IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0194164
(2002-07-12)
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발명자
/ 주소 |
|
출원인 / 주소 |
- Illinois Institute of Technology
|
대리인 / 주소 |
Pauley Petersen & Erickson
|
인용정보 |
피인용 횟수 :
17 인용 특허 :
16 |
초록
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A monitoring system for chemical shipments having an apparatus for detection of a leak from a shipment vessel having a shroud. A first chemical sensor is in communication with a chamber of the shroud for detecting the presence of a substance leaking from the vessel. A second sensor is in communicati
A monitoring system for chemical shipments having an apparatus for detection of a leak from a shipment vessel having a shroud. A first chemical sensor is in communication with a chamber of the shroud for detecting the presence of a substance leaking from the vessel. A second sensor is in communication with the ambient environment surrounding the shroud. A monitoring circuit in communication with the first chemical sensor and the second chemical sensor monitors a first chemical sensor output and a second chemical sensor output and signals an information unit dependant on the increase of at least one of the first and second chemical sensors. The information unit emits a signal to an alarm or output device in response to an increase of the magnitude and/or rate of increase of at least one of the first chemical sensor output and the second chemical sensor output. A physical sensor can be in combination with the monitoring circuit. The information unit can be a remote information unit to which the monitoring circuit signals by wireless communication means.
대표청구항
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A monitoring system for chemical shipments having an apparatus for detection of a leak from a shipment vessel having a shroud. A first chemical sensor is in communication with a chamber of the shroud for detecting the presence of a substance leaking from the vessel. A second sensor is in communicati
A monitoring system for chemical shipments having an apparatus for detection of a leak from a shipment vessel having a shroud. A first chemical sensor is in communication with a chamber of the shroud for detecting the presence of a substance leaking from the vessel. A second sensor is in communication with the ambient environment surrounding the shroud. A monitoring circuit in communication with the first chemical sensor and the second chemical sensor monitors a first chemical sensor output and a second chemical sensor output and signals an information unit dependant on the increase of at least one of the first and second chemical sensors. The information unit emits a signal to an alarm or output device in response to an increase of the magnitude and/or rate of increase of at least one of the first chemical sensor output and the second chemical sensor output. A physical sensor can be in combination with the monitoring circuit. The information unit can be a remote information unit to which the monitoring circuit signals by wireless communication means. riction sleeves is configured with a surface texture, where said surface texture has a corresponding surface roughness value; each of said surface textures for select friction sleeves is configured to induce internal shearing of the soil as the attachment module is penetrated into the soil; and each of said surface textures is further configured to be self-cleaning, such that soil particles do not clog the texture and change the surface roughness value during a sounding. 10. The apparatus of claim 9, wherein each of said friction sleeves has a corresponding value at a measurement depth in a single sounding, and said values correspond to individual in situ measurements of interface strength at said measurement depth. 11. An apparatus for determining interface strength in situ at a particular subsurface location, comprising: a penetrating tip member, said penetrating tip member configured to penetrate into soil of said subsurface location; an attachment module coupled to said penetrating tip member, wherein said attachment module includes a plurality of individual load cells; a data acquisition system coupled to at least one of said penetrating tip member and said attachment module; wherein said penetrating tip member further comprises a conventional CPT module instrumented to measure qc,u2,and fs,and having a CPT digital housing, CPT digital board, dual axis inclinometer and CPT friction sleeve; wherein each of the plurality of said load cells is comprised of a mandrel and a friction sleeve; said each of said friction sleeves is configured with a surface texture, where said surface texture has a corresponding surface roughness value; each of said surface textures for select friction sleeves is configured to induce internal shearing of the soil as the attachment module is penetrated into the soil; and each of said surface textures is further configured to be self-cleaning, such that soil particles do not clog the texture and change the surface roughness value during a sounding; and a vertical arrangement of said friction sleeves in ascending order according to increasing roughness of said surface texture, such that the least rough friction sleeve is placed closest to the penetrating tip member and the roughest friction sleeve is placed furthest away from said penetrating tip member. 12. The apparatus of claim 11, wherein the friction sleeves are spaced from the penetrating tip member such the friction sleeves are located outside of a high shear zone occurring around the penetrating tip member. 13. The apparatus of claim 12, wherein the friction sleeves have an average surface roughness of approximately 0.05 to approximately 250 um. 14. The apparatus of claim 13, wherein each of said friction sleeves is further configured with a diamond surface texture; and said diamond surface texture having geometric parameters, including diamond height, diagonal diamond spacing, penetration angle, and diamond width, that are variable to impart different characteristics to the textured surfaces of said friction sleeves. 15. The apparatus of claim 14, wherein said geometric parameters of each of the diamond surface textures is further configured by diamond height variations from approximately 0.25 to approximately 2.0 mm, diagonal spacing from approximately 4.6 to approximately 12.5 mm, and penetration angles from approximately 30 to approximately 120 degrees. 16. A method of determining interface strength in situ comprising the steps of: positioning a penetrating tip member so as to penetrate into soil at a particular subsurface area; positioning an attachment module in a predetermined relationship to the penetrating tip member so as to form a penetrometer comprised of at least said penetrating tip member and said attachment module; forcing the penetrating tip member end of the penetrometer into the soil; collecting penetrating tip member measurements; and collecting attachment modu le measurements from a plurality of individual electrically isolated load cells, wherein each of the load cells measures the soil response separately; wherein each load cells obtains an in situ measurement of interface strength at each measurement depth that corresponds to the location of each load cell on the attachment module; wherein each load cell obtains the in situ measurement of interface strength without using the measurement data of the penetrating tip member. 17. The method of claim 16, further comprising transmitting said data corresponding to said penetrating tip member measurements and said attachment module measurements to a data acquisition system. 18. The method of claim 16, wherein the penetrating tip member is a conventional CPT module. 19. The method of claim 16, wherein each of said load cells of said attachment module is comprised of a corresponding plurality of mandrels and friction sleeves; and further comprising a method for measuring the interface resistance for each of said friction sleeves, where said interface resistance data is used to determine corresponding interface strength. 20. The method of claim 16, further including the steps of: measuring penetration depth of said penetrometer; measuring penetration tip member values; and measuring verticality of said penetrating tip member; where the penetration depth, penetration tip member values, and verticality measurements comprise the drive tip measurements; and measuring frictional forces at each measurement increment on each of a plurality of friction sleeves located in the corresponding plurality of individual load cells, where the frictional force data comprises the attachment module measurements. 21. The method of claim 20, further comprising the steps of converting the analog measurement data from each of said measurements to digital signals, multiplexing, and then relaying the multiplexed data to the data acquisition system. 22. A method of determining interface strength in situ comprising the steps of: positioning a penetrating tip member so as to penetrate into soil at a particular subsurface area; positioning an attachment module in a predetermined relationship to the penetrating tip member so as to form a penetrometer comprised of at least said penetrating tip member and said attachment module; forcing the penetrating tip member end of the penetrometer into the soil; collecting penetrating tip member measurements; collecting attachment module measurements from a plurality of load cells, each of said load cells of said attachment module is comprised of a corresponding plurality of mandrels and friction sleeves, said plurality of friction sleeves are configured to be removable, such that the arrangement of the friction sleeves along the attachment module portion of the penetrometer may be reconfigured into different order arrangements for measuring corresponding interface resistances of said friction sleeves; transmitting said data corresponding to said penetrating tip member measurements and said attachment module measurements to a data acquisition system; and measuring the interface resistance for each of said friction sleeves, where said interface resistance data is used to determine corresponding interface strength. 23. The method of claim 22, wherein said friction sleeves are spaced from the penetrating tip member such that the friction sleeves are located outside of a high shear zone occurring around the penetrating tip. 24. The method of claim 22, wherein the friction sleeves are configured with a surface texture; and said surface texture of select friction sleeves is configured with a diamond-shaped pattern so as to induce internal shearing of the soil around the penetrometer as the penetrometer is penetrated into the soil. 25. The method of claim 24, wherein the friction sleeves are arranged in ascending order of vertically according to increasing roughness of the surface texture, such that the lea
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