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US3255575A - Apparatus for obtaining bubble-free sample, and method for obtaining same - Google Patents

Apparatus for obtaining bubble-free sample, and method for obtaining same Download PDF

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US3255575A
US3255575A US199040A US19904062A US3255575A US 3255575 A US3255575 A US 3255575A US 199040 A US199040 A US 199040A US 19904062 A US19904062 A US 19904062A US 3255575 A US3255575 A US 3255575A
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liquid
sample
degassing
gas
stream
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Otis R H Roberts
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Texaco Inc
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N1/00Sampling; Preparing specimens for investigation
    • G01N1/28Preparing specimens for investigation including physical details of (bio-)chemical methods covered elsewhere, e.g. G01N33/50, C12Q
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N1/00Sampling; Preparing specimens for investigation
    • G01N1/02Devices for withdrawing samples
    • G01N1/10Devices for withdrawing samples in the liquid or fluent state
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T436/00Chemistry: analytical and immunological testing
    • Y10T436/25Chemistry: analytical and immunological testing including sample preparation

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  • This invention relates to the apparatus and method for obtaining a substantially bubble-free sample of liquid for analysis. In another of its more .specific aspects, this invention relates to the apparatus and method for obtaining a substantially bubble-free sample of volatile hydrocarbon liquid for analysis on a spectrometer.
  • the present invention for obtaining a substantially bubble-free liquid sample comprises first divid" ing a sample stream of the liquid into a major portion and a minor portion.
  • the minor portion is admitted to a degassing zone which ,also is provided withan outlet for Withdrawing liquid therefrom.
  • the level of liquid in the degassing zone is controlled to apredetermined depth providing a gas space in the degassing zone above the liquid.
  • the major portion is admitted to an aspirator.
  • Conduit means establishes communication between the aspirator and the gas space of the degassing zone, and desirably a valve means, preferably power-actuated in response to the level of liquid in said degassing zone, is interposed in the conduit means for controlling flow between the aforesaid parts.
  • the minor portion of the liquid sample stream is passed to the degassing zone at a substantially constant rate to maintain the liquid at a substantially predetermined level.
  • the major portion of the liquid sample stream is passed to the aspirator drawing gases from the degassing zone, As a consequence, there is a substantial reduction in pressure in the degassing zone which causes the gases in the liquid to escape. This reduces substantially the volume of gases in the liquid present in the degassing zone.
  • the liquid withdrawn from the degassing zone can then be passed through the samplecell of an automatic analyzer for analysis at substantially the same pressure and temperature as that in the degassing z'one without the formation of gas bubbles in the liquid sample.
  • the invention is shown for use in the catalytic reforming of petroleum naphtha to obtain gasolines and gasoline stocks with high octane ratings which are obtained primarily by reason of conversion of parafiins and naphthenic hydrocarbons to monocyclic aromatic hydrocarbons.
  • the effluent sample stream is passed to an automatic analyzer such as a spectrometer. Particularly suitable for this purpose are an infrared or ultraviolet spectrophotometer. With these analyzers, a beam of infrared or ultraviolet radiation is passed through a liquid sample of the hydrocarbon efiluent. The amount of radiation absorbed at a selected Wave length indicates the amount present of the selected constituent under question. From this analysis, the quality of the effiuent stream can be determined and the operating conditions can be controlled or adjusted.
  • the total efliuent from the operation is usually treated in a high pressure separator to remove most of the hydrogen and light gaseous hydrocarbons.
  • the resulting efliuent is then passed to a stabilizer to recover the normally liquid reaction products substantially free from light hydrocarbons.
  • analysis of the effluent is required, and at the conditions of the hydrocarbon conversion operation, gases are present in the liquid which may form bubbles at the pressure at which the analysis is carried out and therefore interfere with the analysis.
  • hydrocarbon efiluent from a high pressure separator hydrocarbon efiluent from a high pressure separator
  • solenoid valve 4 in line 6 is opened by electric sequence control means 7, and a sample stream of high pressure separator effiuent is passed through line 6.
  • the stream is passed through a filter 8 to remove foreign solids, such as carbon particles, catalyst particles, etc., and through a microfilter 10 to remove fine particles of foreign solids down to about 1 micron size.
  • a filter 8 to remove foreign solids, such as carbon particles, catalyst particles, etc.
  • a microfilter 10 to remove fine particles of foreign solids down to about 1 micron size.
  • the sample streams taken for analysis are likely to be at somewhat higher temperatures and pressures than the analyzer is equipped to handle or might handle under the most favorable conditions.
  • the part of the sample stream passed to the analyzer may be desirably at a temperature of 100 F. and a pressure of 400p.s.i.g. Therefore, the sample stream is passed first through a differential pressure regulator 12 in line 6 which maintains the pressure immediately downstream of the valve higher than a reference pressure by a fixed amount.
  • Suitable differential pressure regulators are known and are commercially available.
  • a fixed metering orifice 16 is provided downstream of differential pressure regulator 12.
  • the differential pressure regulator is adjusted to give a flow of 1 gallon per minute (3785 cc. per min.) through the metering orifice.
  • a pressure regulator 18 controls the pressure in line 6 downstream of metering orifice 16 at a constant predetermined value.
  • a minor portion of the stream flows through line 20 and then through cooler 22 to reduce the temperature of the stream.
  • the remainder of the stream, constituting the major portion thereof, passes through pressure regulator 18 and through line 24 to aspirator 26.
  • the liquid and gases leaving the aspirator are cycled to a refinery stream via lines 27 and 28 for further handling.
  • Hydrocarbon sample enters the degassing zone (indicated generally at 29) through line 30 into upper chamber 32, which is of larger cross-section than line 30.
  • the hydrocarbon liquid is collected in chamber 34 which is of relatively large volume and serves as a liquid receiver section of the degassing zone.
  • Chamber 34 is provided with an orifice 36 at the bottom of the chamber which regulates the flow of sample to the analyzer.
  • a No. 60 drill size orifice (0.001256 square inch opening) will provide a rate of flow of about 100 ccs. per minute.
  • the liquid sample flows through line 38 to the spectrophotometer indicated generally at 40 for analysis.
  • Analysis of .the liquid sample may be conducted on a continuous basis, and the liquid sample is directed from the analyzer through line 42.
  • a second differential pressure regulator valve 44, and metering orifice 45 suitably with a No. 60 drill size sharp edge orifice, controls the rate of flow of the sample through the sample cell of the analyzer.
  • the volume of sample passing through metering orifice 45 can be determined by a suitable flow meter 46.
  • the sample stream is discharged through line 28, usually back into a refinery stream.
  • a pressure equalizing line 48 extends from line 38 to vapor space in the degassing zone to assure a smooth, uniform fiow of liquid to the analyzer 40.
  • Valve 49 is interposed in pressure equalizing line 48 to prevent pres sure surges which could be damaging to some of the more fragile parts of the analyzer.
  • Conduit 52 having valve 54 interposed therein, provides fluid communication between the aspirator 26 and the gas space of the degassing zone 28.
  • Chamber 34 is provided with a suitable float or displacer 56, or other liquid level responsive device which operates liquid level controller 58 which serves to actuate valve 54 controlling the rate of withdrawal of gas from the degasser and the level of the liquid in the chamber at a predetermined level.
  • valve 4 in line 6 is opened, and hydrocarbon sample may be passed from the high pressure separator at the rate of about 1 gallon per minute. This rate is representative only of a typical operation, and it should be understood that the .rate may be suitably adjuted as determined by the various conditions of operation.
  • the stream in line 6 is then divided by valves 18 and 44, as explained above, and a minor portion at the rate of about 100 cc. per minute is passed to the degassing zone, the remainder of the stream being directed to the aspirator.
  • Gas is drawn from chamber 34 allowing the chamber to fill to a predetermined level with degassed liquid sample.
  • the liquid in chamber 34 is maintained at a predetermined level thereby providing a space in the chamber above the liquid.
  • the major portion of liquid is passed .to the aspirator 26 via line 24, and, with valve 54 open, suction in line 52 occurs and the gases from the degassing zone are drawn therefrom. This creates a substantial reduction in pressure in the degassing zone which causes the gases in the liquid to escape readily.
  • the liquid withdrawn from the degassing zone via line 38 is then substantially bubble-free, and is passed to the automatic analyzer 40 for analysis.
  • valve 54 A rise in liquid beyond the predetermined level will tend to close valve 54, reducing the rate of gas withdrawal from chamber 34 and permitting the pressure in the space occupied by gases above the liquid to increase. As a result, the rate of flow of sample to the degassing zone from line 6 is decreased. If the liquid level in chamber 34 decreases, the float or displacer in chamber 34 actuates valve 54 to open the valve more and permit gas to flow at a faster rate through line 52, further reducing pressure in chamber 34 and drawing in sample from line 6 at a faster rate to re-establish the liquid level in chamber 34.
  • hydrocarbon eflluent may be taken for analysis from several points in the over-all hydrocarbon conversion operation.
  • a side stream taken from the reactor in a reforming operation would be typically at about 900 to 975 F. and a pressure of about 600 to 650 p.s.i.g., which is substantially greater than the temperature and pressure for a side stream from a stabilizer.
  • electric sequence control means 7 opens solenoid valve 60 in line 62 leading from the reactor indicated generally at 63. The sequence control means 7 thus closes valve 4 in line 6 so that streams from different units are not mixed.
  • Efiluent from the reactor is filtered at 64 to remove foreign solids, and is then passed through cooler 66 and pressure regulator valve 68, having pressure controller 70, to reduce the temperature and pressure of the stream.
  • the stream from line 62 is then conducted to line 6 for further processing in accordance with the invention as described above.
  • Apparatus for obtaining a substantially bubble-free liquid sample from a liquid process stream comprising in combination,
  • means including a first conduit for withdrawing a sample from a liquid process stream
  • aspirating means having a first inlet means for admiting a first portion of said liquid process stream to create suction therein, a second inlet means for as pirating gas thereto, and an outlet means for discharging a mixture of liquid and gas therefrom;
  • degassing means for degassing a second portion of said process stream, said degassing means having a liquid inlet means, a degassing zone, liquid outlet means for withdrawing therefrom a liquid sample substantially free of gas, and gas outlet means;
  • valve means controlling the volume of liquid entering said second and third conduits
  • Apparatus in accordance with claim 1 also comprising means responsive to the level of liquid in said degassing zone to control the level of said liquid therein to a predetermined depth, and
  • a method for obtaining a substantially bubblefree liquid sample which comprises:
  • a method for obtaining a substantially bubblefree liquid sample which comprises:
  • analytical means connecting with said liquid outlet means of said degassing means
  • valve means interposed between said liquid outlet means and said analytical means for controlling the rate of flow of bubble-free liquid to said analytical means
  • Apparatus for obtaining a substantially bubble-free liquid sample from a liquid process stream comprising in combination,
  • degassing means including a first conduit for withdrawing a sample from a liquid process stream and for introducing said sample of said process stream into a degassing means, said degassing means having a liquid inlet connected to said first conduit, a degassing zone, liquid outlet means for withdrawing therefrom .a liquid sample substantially free of gas, and a gas outlet means;
  • aspirating means having a first inlet means for admit-' ting a first portion of said liquid process stream to create suction therein, a second inlet means for aspirating gas thereto, and an outlet means for discharging a mixture of liquid and gas therefrom;
  • valve means controlling the volume of liquid entering said second and third conduits
  • said degassing means including a constricted zone of relatively smaller cross-section than said degassing zone, and pressure equalizing means connecting said liquid inlet means and said liquid outlet means;
  • analyzing means connected to said liquid outlet from said degassing zone for analyzing said liquid 'substantially free of gas

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  • Life Sciences & Earth Sciences (AREA)
  • Physics & Mathematics (AREA)
  • Health & Medical Sciences (AREA)
  • Chemical & Material Sciences (AREA)
  • Analytical Chemistry (AREA)
  • Biochemistry (AREA)
  • General Health & Medical Sciences (AREA)
  • General Physics & Mathematics (AREA)
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Description

June 14, 1966 o. R. H. ROBERTS 3,255,575
APPARATUS FOR OBTAINING BUBBLE-FREE SAMPLE, AND METHOD FOR OBTAINING SAME Filed May 51, 1962 o n: CI L o no I o t Lu & -1 a l- CD} I on E w 21 co 0: u co m .J R, E y 9 F6 (\J United States Patent 3,255,575 APPARATUS FOR OBTAINHQG BUBBLE-FREE SfiELE, AND METHOD FOR OBTAINING Otis R. H. Roberts, Rolling Hills Estates, Calif, assignor to Texaco Inc., New York, N.Y., a corporation of Delaware Filed May 31, 1962, Ser. No. 199,040 8 Claims. (CI. 55-46) This invention relates to the apparatus and method for obtaining a substantially bubble-free sample of liquid for analysis. In another of its more .specific aspects, this invention relates to the apparatus and method for obtaining a substantially bubble-free sample of volatile hydrocarbon liquid for analysis on a spectrometer.
In the chemical and petroleum fields, for example, analysis is required of the several streams at various stages of the operation. Various automatic analyzers are commonly employed which provide accurate and rapid analysis. Suitable analyzers in wide use include, for example, infrared and ultraviolet spectrophotometers.
In petroleum refinery operations involving the conversion of hydrocarbons, effluent is analyzed to monitor the operation and to determine the quality of the product, for example. It is conventional practice to take a sample stream of hydrocarbon eflluent which may be preliminarily treated, such as by filtering to remove foreign solids or by adjusting the temperature, and passing the sample of the efiluent to a suitable analyzer. However, refinery operations are conducted at elevated temperatures and pressures, and gaseous products are usually admixed with the liquids. As a consequence, when a liquid sample of hydrocarbon effluent is passed to an automatic analyzer at lower pressure than the process pressure, gas in the liquid may form bubbles which interfere with the accuracy of the analysis. This is particularly true with spectrophotometers where bubbles in the liquid sample will cause an inaccurate reading.
It is therefore an object of this invention to provide a method and apparatus for obtaining a sample of liquid for analysis which is substantially bubble-free.
Other objects and advantages of the present invention will best be understood by referring to the following detailed specification and'preferred embodiments thereof, and to the accompanying drawing Which schematically illustrates the invention. I
In general, the present invention for obtaining a substantially bubble-free liquid sample comprises first divid" ing a sample stream of the liquid into a major portion and a minor portion. The minor portion is admitted to a degassing zone which ,also is provided withan outlet for Withdrawing liquid therefrom. As explained more fully hereinbelow, it is preferable that the level of liquid in the degassing zone is controlled to apredetermined depth providing a gas space in the degassing zone above the liquid. Simultaneously with admitting the minor portion to the degassing zone, the major portion is admitted to an aspirator. Conduit means establishes communication between the aspirator and the gas space of the degassing zone, and desirably a valve means, preferably power-actuated in response to the level of liquid in said degassing zone, is interposed in the conduit means for controlling flow between the aforesaid parts.
In operation, the minor portion of the liquid sample stream is passed to the degassing zone at a substantially constant rate to maintain the liquid at a substantially predetermined level. At the same time, the major portion of the liquid sample stream is passed to the aspirator drawing gases from the degassing zone, As a consequence, there is a substantial reduction in pressure in the degassing zone which causes the gases in the liquid to escape. This reduces substantially the volume of gases in the liquid present in the degassing zone. The liquid withdrawn from the degassing zone can then be passed through the samplecell of an automatic analyzer for analysis at substantially the same pressure and temperature as that in the degassing z'one without the formation of gas bubbles in the liquid sample.
In order to describe the invention in greater detail, reference is now made to the accompanying drawing which schematically illustrates the invention for use in a petroleum refinery operation. For purposes of illustration, the invention is shown for use in the catalytic reforming of petroleum naphtha to obtain gasolines and gasoline stocks with high octane ratings which are obtained primarily by reason of conversion of parafiins and naphthenic hydrocarbons to monocyclic aromatic hydrocarbons. The effluent sample stream is passed to an automatic analyzer such as a spectrometer. Particularly suitable for this purpose are an infrared or ultraviolet spectrophotometer. With these analyzers, a beam of infrared or ultraviolet radiation is passed through a liquid sample of the hydrocarbon efiluent. The amount of radiation absorbed at a selected Wave length indicates the amount present of the selected constituent under question. From this analysis, the quality of the effiuent stream can be determined and the operating conditions can be controlled or adjusted.
In the reforming of petroleum naphtha using a platihum-alumina catalyst, for example, the total efliuent from the operation is usually treated in a high pressure separator to remove most of the hydrogen and light gaseous hydrocarbons. The resulting efliuent is then passed to a stabilizer to recover the normally liquid reaction products substantially free from light hydrocarbons. As explained above, analysis of the effluent is required, and at the conditions of the hydrocarbon conversion operation, gases are present in the liquid which may form bubbles at the pressure at which the analysis is carried out and therefore interfere with the analysis. Thus, referring to the drawing, hydrocarbon efiluent from a high pressure separator,
not shown, is delivered through line 2 for processing in a stabilizer, not illustrated in the drawing. As exemplary of a commercial reforming operation, effluent from the high pressure separator would be at a temperature of.
about to F.'and a pressure of about 450 p.s.i.g. When it is desired to take a sample from line 2, solenoid valve 4 in line 6 is opened by electric sequence control means 7, and a sample stream of high pressure separator effiuent is passed through line 6. The stream is passed through a filter 8 to remove foreign solids, such as carbon particles, catalyst particles, etc., and through a microfilter 10 to remove fine particles of foreign solids down to about 1 micron size. Generally, it is desirable or necessary to reduce the temperature and pressure in the sample line, for in commercial operating units, the sample streams taken for analysis are likely to be at somewhat higher temperatures and pressures than the analyzer is equipped to handle or might handle under the most favorable conditions. For example, when an ultraviolet spectrophotometer is employed to analyze the sample stream delivered to the stabilizer of the reforming operation mentioned above, the part of the sample stream passed to the analyzer may be desirably at a temperature of 100 F. and a pressure of 400p.s.i.g. Therefore, the sample stream is passed first through a differential pressure regulator 12 in line 6 which maintains the pressure immediately downstream of the valve higher than a reference pressure by a fixed amount. Suitable differential pressure regulators are known and are commercially available. A fixed metering orifice 16 is provided downstream of differential pressure regulator 12. A sharp edge plate orifice Patented June 14, 1966 g regulator 12 so that a constant pressure difference is maintained across metering orifice 16 whereby a constant volume of liquid is passed through the metering orifice. Suitably the differential pressure regulator is adjusted to give a flow of 1 gallon per minute (3785 cc. per min.) through the metering orifice. A pressure regulator 18 controls the pressure in line 6 downstream of metering orifice 16 at a constant predetermined value. A minor portion of the stream flows through line 20 and then through cooler 22 to reduce the temperature of the stream. The remainder of the stream, constituting the major portion thereof, passes through pressure regulator 18 and through line 24 to aspirator 26. The liquid and gases leaving the aspirator are cycled to a refinery stream via lines 27 and 28 for further handling.
Hydrocarbon sample enters the degassing zone (indicated generally at 29) through line 30 into upper chamber 32, which is of larger cross-section than line 30. As a consequence, the flow of fluid is decelerated abruptly thereby facilitating separation of gas from liquid. The hydrocarbon liquid is collected in chamber 34 which is of relatively large volume and serves as a liquid receiver section of the degassing zone. Chamber 34 is provided with an orifice 36 at the bottom of the chamber which regulates the flow of sample to the analyzer. Suitably a No. 60 drill size orifice (0.001256 square inch opening) will provide a rate of flow of about 100 ccs. per minute. The liquid sample flows through line 38 to the spectrophotometer indicated generally at 40 for analysis. Analysis of .the liquid sample may be conducted on a continuous basis, and the liquid sample is directed from the analyzer through line 42. A second differential pressure regulator valve 44, and metering orifice 45, suitably with a No. 60 drill size sharp edge orifice, controls the rate of flow of the sample through the sample cell of the analyzer. The volume of sample passing through metering orifice 45 can be determined by a suitable flow meter 46. The sample stream is discharged through line 28, usually back into a refinery stream.
A pressure equalizing line 48 extends from line 38 to vapor space in the degassing zone to assure a smooth, uniform fiow of liquid to the analyzer 40. Valve 49 is interposed in pressure equalizing line 48 to prevent pres sure surges which could be damaging to some of the more fragile parts of the analyzer.
Conduit 52, having valve 54 interposed therein, provides fluid communication between the aspirator 26 and the gas space of the degassing zone 28. Chamber 34 is provided with a suitable float or displacer 56, or other liquid level responsive device which operates liquid level controller 58 which serves to actuate valve 54 controlling the rate of withdrawal of gas from the degasser and the level of the liquid in the chamber at a predetermined level.
In operation, valve 4 in line 6 is opened, and hydrocarbon sample may be passed from the high pressure separator at the rate of about 1 gallon per minute. This rate is representative only of a typical operation, and it should be understood that the .rate may be suitably adjuted as determined by the various conditions of operation. The stream in line 6 is then divided by valves 18 and 44, as explained above, and a minor portion at the rate of about 100 cc. per minute is passed to the degassing zone, the remainder of the stream being directed to the aspirator. Gas is drawn from chamber 34 allowing the chamber to fill to a predetermined level with degassed liquid sample. The liquid in chamber 34 is maintained at a predetermined level thereby providing a space in the chamber above the liquid. As explained above, the major portion of liquid is passed .to the aspirator 26 via line 24, and, with valve 54 open, suction in line 52 occurs and the gases from the degassing zone are drawn therefrom. This creates a substantial reduction in pressure in the degassing zone which causes the gases in the liquid to escape readily. The liquid withdrawn from the degassing zone via line 38 is then substantially bubble-free, and is passed to the automatic analyzer 40 for analysis.
A rise in liquid beyond the predetermined level will tend to close valve 54, reducing the rate of gas withdrawal from chamber 34 and permitting the pressure in the space occupied by gases above the liquid to increase. As a result, the rate of flow of sample to the degassing zone from line 6 is decreased. If the liquid level in chamber 34 decreases, the float or displacer in chamber 34 actuates valve 54 to open the valve more and permit gas to flow at a faster rate through line 52, further reducing pressure in chamber 34 and drawing in sample from line 6 at a faster rate to re-establish the liquid level in chamber 34.
Where desired, hydrocarbon eflluent may be taken for analysis from several points in the over-all hydrocarbon conversion operation. For example, a side stream taken from the reactor in a reforming operation would be typically at about 900 to 975 F. and a pressure of about 600 to 650 p.s.i.g., which is substantially greater than the temperature and pressure for a side stream from a stabilizer. When it is desired to analyze a side stream from the reactor, electric sequence control means 7 opens solenoid valve 60 in line 62 leading from the reactor indicated generally at 63. The sequence control means 7 thus closes valve 4 in line 6 so that streams from different units are not mixed. Efiluent from the reactor is filtered at 64 to remove foreign solids, and is then passed through cooler 66 and pressure regulator valve 68, having pressure controller 70, to reduce the temperature and pressure of the stream. The stream from line 62 is then conducted to line 6 for further processing in accordance with the invention as described above.
Having described my invention, and certain embodiments thereof, I claim:
1. Apparatus for obtaining a substantially bubble-free liquid sample from a liquid process stream comprising in combination,
means including a first conduit for withdrawing a sample from a liquid process stream,
aspirating means having a first inlet means for admiting a first portion of said liquid process stream to create suction therein, a second inlet means for as pirating gas thereto, and an outlet means for discharging a mixture of liquid and gas therefrom;
degassing means for degassing a second portion of said process stream, said degassing means having a liquid inlet means, a degassing zone, liquid outlet means for withdrawing therefrom a liquid sample substantially free of gas, and gas outlet means;
a second conduit connecting said first conduit to said aspirating means for supplying aspirating liquid thereto;
a third conduit connecting said first conduit to said liquid inlet means of said degassing means for supplying a liquid sample thereto;
valve means controlling the volume of liquid entering said second and third conduits;
a fourth conduit connecting together said second inlet of said aspirating device and said gas outlet from said degassing zone;
and means for combining the liquid outlet means of said aspirating means with the liquid outlet means of said degassing means.
2. Apparatus in accordance with claim 1, also comprising means to control the level of liquid in said degassing zone.
3. Apparatus in accordance with claim 1, also comprising means responsive to the level of liquid in said degassing zone to control the level of said liquid therein to a predetermined depth, and
valve means interposed in said fourth conduit means and operated by said .level responsive means, to control flow of said gas from said gas outlet of said degassing means to said gas inlet of said aspirating means, and means for analyzing said liquid substantially free of gas. 4. A method for obtaining a substantially bubblefree liquid sample, which comprises:
separating a stream of a liquid containing gaseous components into a major portion and a minor portion, introducing said minor portion into a degassing zone, separating gaseous components from said minor portion by vaporization of said gaseous components in said degassing zone, simultaneously introducing said major portion into an aspirator, applying suction created in said aspirator to said degassing zone and removing gaseous components therefrom, discharging said major portion including the removed gaseous components from said aspirator, and withdrawing liquid substantially free of gas from said degassing zone. 5. A method for obtaining a substantially bubblefree liquid sample, which comprises:
separating a stream of a liquid containing gaseous components into a major portion and a minor portion, introducing said minor portion into a degassing zone, separating gaseous components from said minor portion by vaporization of said gaseous components in said degassing zone, controlling the level of said liquid in said degasssing zone at a point below the top of said degassing zone, simultaneously introducing said major portion into an aspirator, applying suction created in said aspirator to the upper portion of said degassing zone and removing gaseous components therefrom, discharging said major portion including the removed gaseous components from said aspirator, and Withdrawing liquid substantially free of gas from said degassing zone. 6. Apparatus for analyzing a liquid process stream which comprises, in combination,
means for Withdrawing a sample stream from said process stream, means for removing solid impurities from said sample stream, means for metering the rate of flow of said sample stream, means for dividing said metered sample stream into a major portion and a minor portion, exchanger means for controlling the temperature of said minor portion, degassing means for separating gas from said minor portion, including inlet means connected to said exchanger means for introducing said minor portion into the upper portion of said degassing means, means for collecting said separated gas in the upper portion of said degassing means, gas outlet means connected to said gas collecting means, means for collecting substantially bubble-free liquid in the lower portion of said degassing means, liquid outlet means connected to said liquid collecting means, and pressure equalizing means connecting said liquid outlet means with said upper portion of said degassing means, 7 liquid level control means within said degassing means for controlling the level of said liquid therein to a predetermined depth, flow control means located in said gas outlet means of said gas degassing means and actuated by said liquid control means, aspirating means having a first inlet for admitting I 6 said major portion of said process stream, a second inlet connecting with said gas space in said degassing zone for admitting gas thereto, and an outlet for discharging liquid and gas therefrom,
analytical means connecting with said liquid outlet means of said degassing means,
valve means interposed between said liquid outlet means and said analytical means for controlling the rate of flow of bubble-free liquid to said analytical means, and
means for returning analyzed liquidfrom said analytical means and liquid and gas discharged from 'said outlet of said aspirating means to said liquid process stream.
7. Apparatus for obtaining a substantially bubble-free liquid sample from a liquid process stream comprising in combination,
means including a first conduit for withdrawing a sample from a liquid process stream and for introducing said sample of said process stream into a degassing means, said degassing means having a liquid inlet connected to said first conduit, a degassing zone, liquid outlet means for withdrawing therefrom .a liquid sample substantially free of gas, and a gas outlet means;
aspirating means having a first inlet means for admit-' ting a first portion of said liquid process stream to create suction therein, a second inlet means for aspirating gas thereto, and an outlet means for discharging a mixture of liquid and gas therefrom;
a second conduit connecting said first conduit to the liquid inlet ofsaid aspirating device for supplying aspirating liquid thereto;
a third conduit connecting said first conduit to the liquid inlet of said degassing means for supplying a liquid sample thereto;
valve means controlling the volume of liquid entering said second and third conduits,
a fourth conduit connecting together said second inlet of said aspirating device and said gas outlet from said degassing zone,
said degassing means including a constricted zone of relatively smaller cross-section than said degassing zone, and pressure equalizing means connecting said liquid inlet means and said liquid outlet means;
means responsive to the level of liquid in said degassing zone to control the level of said liquid therein to a predetermined depth,
flow control valve means interposed in said fourth conduit,
means operated by said liquid level responsive means, for opening said flow control valve means when said liquid level is below said predetermined depth, and for closing said flow control valve means when said liquid level exceeds said predetermined depth, and
means for returning said gas-free liquid from said degassing means and said liquid and gas discharged from said aspirating means to said liquid process stream. I
8. Apparatus in accordance with claim 7, including,
analyzing means connected to said liquid outlet from said degassing zone for analyzing said liquid 'substantially free of gas, and
said means for returning said gas-free liquid from said degassing means, and said liquid and gas discharged from said aspirating means, to said liquid process stream connected to said analyzing means.
References Cited by the Examiner UNITED STATES PATENTS 1,255,018 1/1918 Jones 55-170 2,013,184 9/1925 Marden 55168 2,226,097 12/1940 Happel et a1. 23-253 2,489,893 11/1949 Johnson 55468 (Other references on following page) UNITED STATES PATENTS Whitlock et a1 5541 'Shobe 55-165 X Wadley et a1. 25043.5 X Amir 23230 Gardner 137-604 Stinson 55-55 Zucker 5555 Snipes 55-468 'Bearden et a1. 55270 Roof 5518 Morgan 25043.5 Gates 55167 REUBEN FRIEDMAN, Primary Examiner. B. NOZICK, Assistant Examiner.

Claims (1)

1. APPARATUS FOR OBTAINING A SUBSTANTIALLY BUBBLE-FREE LIQUID SAMPLE FROM A LIQUID PROCESS STREAM COMPRISING IN COMBINATION, MEANS INCLUDING A FIRST CONDUIT FOR WITHDRAWING A SAMPLE FROM A LIQUID PROCESS STREAM, ASPRIATING MEANS HAVING A FIRST INLET MEANS FOR ADMITING A FIRST PORTION OF SAID LIQUID PROCESS STREAM TO CREATE SUCTION THEREIN, A SECOND INLET MEANS FOR ASPIRATING GAS THERETO, AND AN OUTLET MEANS FOR DISCHARGING A MIXTURE OF LIQUID AND GAS THEREFROM; DEGASSING MEANS FOR DEGASSING A SECOND PORTION OF SAID PROCESS STREAM, SAID DEGASSING MEANS HAVING A LIQUID INLET MEANS, A DEGASSING ZONE, LIQUID OUTLET MEANS FOR WITHDRAWING THEREFROM A LIQUID SAMPLE SUBSTANTIALLY FREE OF GAS, AND GAS OUTLET MEANS; A SECOND CONDUIT CONNECTING SAID FIRST CONDUIT TO SAID ASPIRATING MEANS FOR SUPPLYING ASPIRATING LIQUID THERETO;
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Cited By (14)

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US3446077A (en) * 1966-08-15 1969-05-27 Phillips Petroleum Co Sampling system
US3517557A (en) * 1967-11-30 1970-06-30 Naphtachimie Sa Device for sampling hot gaseous mixtures containing condensables
US3977254A (en) * 1974-10-22 1976-08-31 U.S. Philips Corporation Apparatus for sampling for use in a continuous determination of a component in a gas mixture
US4310335A (en) * 1979-03-01 1982-01-12 Institut Francais Du Petrole Method and apparatus for conveying through a pipe a diphasic fluid of high free gas content
US4317379A (en) * 1979-01-08 1982-03-02 Veb Gaskombinat Schwarze Pumpe Process and apparatus for the continuous withdrawal of specimens from a current of a crude gas for purposes of gas analysis
US4670029A (en) * 1986-05-12 1987-06-02 Westinghouse Electric Corp. Water treatment system for ultrasonic inspection of turbine rotors from the bore
FR2616487A1 (en) * 1987-06-12 1988-12-16 Commissariat Energie Atomique DEVICE FOR THE CONTINUOUS CIRCULATION OF A LIQUID FOR THE PURPOSE OF TAKING A SAMPLING OR A CONTROL OF THIS LIQUID
US4799393A (en) * 1985-09-03 1989-01-24 Technicon Instruments Corporation Combined closed and open tube sampling apparatus and method
US4900683A (en) * 1986-12-16 1990-02-13 Ciba-Geigy Corporation Process for preparation of samples for analysis
US5762684A (en) * 1995-11-30 1998-06-09 Dainippon Screen Mfg. Co., Ltd. Treating liquid supplying method and apparatus
US6706094B2 (en) * 2002-05-13 2004-03-16 Wisys Technology Foundation Inc. Collection of dissolved gases from groundwater
US20100212406A1 (en) * 2009-02-25 2010-08-26 Browne Bryant A Collection of dissolved gases from groundwater
US11307138B2 (en) * 2019-03-12 2022-04-19 Paul Hattingh Testing method for residual organic compounds in a liquid sample
US11315776B2 (en) * 2019-10-01 2022-04-26 Elemental Scientific, Inc. Automated inline preparation and degassing of volatile samples for inline analysis

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US1255018A (en) * 1916-03-30 1918-01-29 Philip Jones Process and apparatus for the separation of oils and gases.
US2013184A (en) * 1933-03-31 1935-09-03 Neptune Meter Co Fluid storage and metering system
US2226097A (en) * 1939-08-04 1940-12-24 Socony Vacuum Oil Co Inc Hydrocarbon cracking process
US2489893A (en) * 1940-01-16 1949-11-29 Bailey Meter Co Apparatus for purifying and feeding sample gas
US2522005A (en) * 1946-11-15 1950-09-12 Automatic Pump & Softener Corp Degasifier
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US2688629A (en) * 1949-12-29 1954-09-07 Standard Oil Dev Co Method for controlling a hydrocarbon synthesis reaction
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Cited By (19)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3446077A (en) * 1966-08-15 1969-05-27 Phillips Petroleum Co Sampling system
US3517557A (en) * 1967-11-30 1970-06-30 Naphtachimie Sa Device for sampling hot gaseous mixtures containing condensables
US3977254A (en) * 1974-10-22 1976-08-31 U.S. Philips Corporation Apparatus for sampling for use in a continuous determination of a component in a gas mixture
US4317379A (en) * 1979-01-08 1982-03-02 Veb Gaskombinat Schwarze Pumpe Process and apparatus for the continuous withdrawal of specimens from a current of a crude gas for purposes of gas analysis
US4310335A (en) * 1979-03-01 1982-01-12 Institut Francais Du Petrole Method and apparatus for conveying through a pipe a diphasic fluid of high free gas content
US4799393A (en) * 1985-09-03 1989-01-24 Technicon Instruments Corporation Combined closed and open tube sampling apparatus and method
US4670029A (en) * 1986-05-12 1987-06-02 Westinghouse Electric Corp. Water treatment system for ultrasonic inspection of turbine rotors from the bore
US4900683A (en) * 1986-12-16 1990-02-13 Ciba-Geigy Corporation Process for preparation of samples for analysis
FR2616487A1 (en) * 1987-06-12 1988-12-16 Commissariat Energie Atomique DEVICE FOR THE CONTINUOUS CIRCULATION OF A LIQUID FOR THE PURPOSE OF TAKING A SAMPLING OR A CONTROL OF THIS LIQUID
EP0296917A1 (en) * 1987-06-12 1988-12-28 Commissariat A L'energie Atomique Device for continuously circulating a liquid in order to sample or to check this liquid
US5762684A (en) * 1995-11-30 1998-06-09 Dainippon Screen Mfg. Co., Ltd. Treating liquid supplying method and apparatus
US6706094B2 (en) * 2002-05-13 2004-03-16 Wisys Technology Foundation Inc. Collection of dissolved gases from groundwater
US20100212406A1 (en) * 2009-02-25 2010-08-26 Browne Bryant A Collection of dissolved gases from groundwater
US11307138B2 (en) * 2019-03-12 2022-04-19 Paul Hattingh Testing method for residual organic compounds in a liquid sample
US11315776B2 (en) * 2019-10-01 2022-04-26 Elemental Scientific, Inc. Automated inline preparation and degassing of volatile samples for inline analysis
US20220328297A1 (en) * 2019-10-01 2022-10-13 Elemental Scientific, Inc. Automated inline preparation and degassing of volatile samples for inline analysis
US11615949B2 (en) * 2019-10-01 2023-03-28 Elemental Scientific, Inc. Automated inline preparation and degassing of volatile samples for inline analysis
US20230290626A1 (en) * 2019-10-01 2023-09-14 Elemental Scientific, Inc. Automated inline preparation and degassing of volatile samples for inline analysis
US12100581B2 (en) * 2019-10-01 2024-09-24 Elemental Scientific, Inc. Automated inline preparation and degassing of volatile samples for inline analysis

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