Microwave heating system and method for removing volatiles from adsorbent materials
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H05B-006/72
F26B-003/34
F26B-003/32
출원번호
US-0742945
(2007-05-01)
등록번호
US-7498548
(2009-03-03)
발명자
/ 주소
Opperman,Stephen H.
출원인 / 주소
Ranger Research, Inc.
대리인 / 주소
Harness, Dickey & Pierce, P.L.C.
인용정보
피인용 횟수 :
4인용 특허 :
27
초록▼
A heating apparatus for removing volatiles from a saturated adsorbent is provided. The heating apparatus can include a vessel including a first end and a second end. The vessel can be adapted to receive the saturated adsorbent. The heating apparatus can also include a channel in communication with t
A heating apparatus for removing volatiles from a saturated adsorbent is provided. The heating apparatus can include a vessel including a first end and a second end. The vessel can be adapted to receive the saturated adsorbent. The heating apparatus can also include a channel in communication with the first end of the vessel and a radiation source that provides energy to heat the vessel. The heating apparatus can further comprise a lateral waveguide coupled to the radiation source and disposed within the channel to transmit the energy from the radiation source to the vessel to heat the saturated adsorbent disposed within the vessel.
대표청구항▼
What is claimed is: 1. A heating apparatus for removing volatiles from a saturated adsorbent comprising: a vessel including a first end and a second end, the vessel adapted to receive the saturated adsorbent; an internal vessel disposed within the vessel that defines a channel between the vessel an
What is claimed is: 1. A heating apparatus for removing volatiles from a saturated adsorbent comprising: a vessel including a first end and a second end, the vessel adapted to receive the saturated adsorbent; an internal vessel disposed within the vessel that defines a channel between the vessel and the internal vessel to enable the saturated adsorbent to pass between the vessel and the internal vessel; a second channel in communication with the first end of the vessel; a radiation source that provides energy to heat the vessel; and a lateral waveguide coupled to the radiation source and disposed within the second channel to transmit the energy from the radiation source to the vessel to heat the saturated adsorbent disposed within the vessel. 2. The heating apparatus of claim 1, wherein the internal vessel comprises a dome disposed within the vessel adjacent to the second end of the vessel that protects the radiation source from contact by the saturated adsorbent, and the vessel further comprises: a port coupled to the first end that enables cleaned adsorbent to exit the vessel. 3. The heating apparatus of claim 2, wherein the dome extends from the second end to the first end of the vessel, and the dome is composed of a material that has a low dielectric loss factor. 4. The heating apparatus of claim 3, wherein the vessel includes an interior surface and an exterior surface, the dome disposed adjacent to the interior surface, and with a dielectric material disposed between the dome and the interior surface of the vessel, the dielectric material selected from the group comprising at least one of graphite, silicon carbide powder, alkaline silicate salts, ceramic, and combinations thereof. 5. The heating apparatus of claim 4, wherein the dielectric material comprises an annulus disposed within the vessel between the interior surface of the vessel and the dome. 6. The heating apparatus of claim 2, wherein the port defines at least one passage that enables at least one of a purge gas to enter the vessel and the cleaned adsorbent to exit the vessel. 7. The heating apparatus of claim 6, further comprising a lid coupled to at least one of the dome and the vessel, wherein the lid further comprises: a first member that mates with the dome to enclose a second end of the dome; a second member that mates with the vessel to enclose the second end of the vessel; a port received through the first member and the second member to enable at least one of the saturated adsorbent to enter the vessel and the purge gas to exit the vessel; and wherein the first member includes a dielectric material that absorbs the energy from the radiation source. 8. The heating apparatus of claim 2, further comprising: a mode converter disposed in the second channel and in communication with the waveguide to transmit the energy from the lateral waveguide to the saturated adsorbent; and wherein the mode converter is coupled to the dome to prevent adsorbent from contacting the mode converter. 9. A heating apparatus for removing volatiles from a saturated adsorbent comprising: a vessel including a first end adapted to receive the saturated adsorbent and a second end; a dome disposed within the vessel adjacent to the second end of the vessel that protects the radiation system from contact by the saturated adsorbent and defines a channel between the vessel and the dome to enable the saturated adsorbent to pass between the vessel and the dome; a port coupled to the first end that enables cleaned adsorbent to exit the vessel; a radiation system in communication with the second end of the vessel that generates energy to heat the saturated adsorbent; and wherein the vessel includes a dielectric material that absorbs the energy from the radiation system. 10. The heating apparatus of claim 9, wherein the dome extends from the second end to the first end of the vessel, and the dome is composed of a material with a low dielectric loss factor. 11. The heating apparatus of claim 10, wherein the vessel includes an interior surface and an exterior surface, the dome disposed adjacent to the interior surface and the dielectric material is disposed between the dome and the interior surface of the vessel, with the dielectric material selected from the group comprising at least one of graphite, silicon carbide powder, alkaline silicate salts, ceramic, and combinations thereof. 12. The heating apparatus of claim 11, wherein the dielectric material comprises an annulus disposed within the vessel between the interior surface of the vessel and the dome. 13. The heating apparatus of claim 12, further comprising a lid coupled to at least one of the dome and the vessel, wherein the lid further comprises: a first member that mates with the dome to enclose a second end of the dome; a second member that mates with the vessel to enclose the second end of the vessel; a port received through the first member and the second member to enable at least one of the saturated adsorbent to enter the vessel and the purge gas to exit the vessel; and wherein the first member includes a dielectric material that absorbs the energy from the radiation source. 14. The heating apparatus of claim 9, wherein the port defines at least one passage that enables at least one of a purge gas to enter the vessel and the cleaned adsorbent to exit the vessel. 15. The heating apparatus of claim 9, wherein the radiation system further comprises: a second channel in communication with the first end of the vessel; a radiation source in communication with the second channel that provides energy to heat the vessel; a lateral waveguide in communication with the radiation source and disposed in the second channel to receive the energy from the radiation source; a mode converter disposed in the channel and in communication with the waveguide to transmit the energy from the lateral waveguide to the vessel to heat the saturated adsorbent disposed within the vessel; and wherein the mode converter is coupled to the dome to prevent adsorbent from contacting the mode converter. 16. A heating apparatus for removing volatiles from a saturated adsorbent comprising: a vessel adapted to receive the saturated adsorbent; a dome disposed within the vessel adjacent to the second end of the vessel that protects the radiation source from contact by the saturated adsorbent and defines a channel between the vessel and the dome to enable the saturated adsorbent to pass between the vessel and the dome; a second channel coupled to the vessel; a radiation source in communication with the second channel to provide energy to heat the vessel; a lateral waveguide coupled to the radiation source and disposed within the second channel to transmit the energy from the radiation source to the vessel to heat the saturated adsorbent disposed within the vessel; and wherein the vessel includes a dielectric material that absorbs the energy from the radiation system. 17. The heating apparatus of claim 16, wherein the vessel has a first end and a second end, and further comprises: a port coupled to the first end that defines at least one passage that enables at least a purge gas to enter the vessel or the cleaned adsorbent to exit the vessel; and wherein the vessel includes an interior surface and an exterior surface, with the dome disposed adjacent to the interior surface so that the saturated adsorbent passes between the dome and the inner surface of the vessel, and the dielectric material is disposed between the dome and the interior surface of the vessel, with the, dielectric material selected from the group comprising at least one of graphite, silicon carbide powder, alkaline silicate salts, ceramic, and combinations thereof. 18. The heating apparatus of claim 17, further comprising a lid coupled to at least one of the dome and the vessel that further comprises: a first member that mates with the dome to enclose a second end of the dome; a second member that mates with the vessel to enclose the second end of the vessel; a port received through the first member and the second member to enable at least one of the saturated adsorbent to enter the vessel and the purge gas to exit the vessel; and wherein the first member includes a dielectric material that absorbs the energy from the radiation source. 19. The heating apparatus of claim 16, further comprising: a mode converter disposed in the second channel and in communication with the waveguide to transmit the energy from the lateral waveguide to the saturated adsorbent; and wherein the mode converter is coupled to the dome to prevent adsorbent from contacting the mode converter.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (27)
Mezey Eugene J. (Columbus OH) Dinovo Salvatore T. (Columbus OH), Adsorbent regeneration and gas separation utilizing microwave heating.
Wear Frederick C. (St. Louis MO) Durant Dick Q. (Manchester MO) McKinney Howard F. (Edwardsville IL), Apparatus and process for drying granular products.
Bazile Jean-Luc (Sur Siange FRX) Billon Paul (Grasse FRX) Mallea Patrick (Nice FRX), Defect detecting device for two-layer parts, in particular for solar cells.
Charm Stanley E. (Boston MA) Landau Steven (Brookline MA) Zarrineghbal Hossein (Winchester MA) Golden Robert F. (Acton MA), High temperature, short time microwave heating system and method of heating heat-sensitive material.
Archambeault Gary L. (Sarnia CAX) Murphy William J. (Brights Grove CAX) Mackert Edmund M. (Baytown TX), Metal fixation in oily waste contaminated soil using microwave radiation acting on in-situ produced coupling agent.
Butwell Robert J. (Redwood City CA) McCune Earl (San Jose CA) Green Michael (Palo Alto CA) Huey Hugo (Cupertino CA) Legarra James R. (Redwood City CA) Wilcox Ross (Palo Alto CA), Method of and apparatus for heating a reaction vessel with microwave energy.
Charm Stanley E. (Boston MA) Landau Steven (Brookline MA) Zarrineghbal Hossein (Winchester MA) Golden Robert F. (Acton MA), Non-invasive infrared temperature sensor, system and method.
Cauquil Grard (Codolet FRX) Sourrouille Michel (Laudun FRX), Process for dissolving plutonium and/or other radioactive elements present in solid or liquid products.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.