NO148348B - DEVICE FOR SAMPLING A FLUIDUM. - Google Patents

Description

This invention relates to an apparatus for sampling a fluid, e.g. to determine a parameter or parameters thereof, such as mass flow, density, temperature, pH or conductivity, or to carry out a chemical and/or physical

cal analysis, for example, to determine the presntwise in-

keep the bullpen. The invention can also be used for the simultaneous determination of a plurality of parameters, e.g. at the same time determine

measurement of density and temperature.

Examination of a fluid to determine a parameter

for this, such as the density, is usually carried out by passing a main flow of the fluid through a line, in

ning inserts a probe with an inlet opening that faces upstream in the line and which communicates with an outlet opening

which faces downstream in this, and by using an instru-

intended for measuring density etc. to examine the sample current passing through the probe, so that the desired parameter can be determined. The inlet opening can have a dirt protection so that the sample flow is made to make two sharp deflections before it enters the measuring instrument, whereby the amount of dirt or unevenness that enters the instrument is reduced. Despite this, there is still a fairly significant amount of dirt that can enter the instrument.

It is therefore an object of this invention to provide an apparatus for sampling a fluid, where the amount of dirt or unevenness carried with the sample flow is substantially reduced.

The known technique can be considered represented by Russian patent document 568 024. However, the device shown there has an inlet nozzle and an outlet nozzle, both of which are located at the "inner" end of the device. If the inlet opening, as shown in the Russian patent document, is not located at a distance from the end surface, this will result in a very small pressure difference between the pressures at the inlet and outlet openings. Consequently, a noisy signal and a non-linear relationship between the main flow and the sample flow will make the arrangement unsuitable for use in a flow meter, because in a flow meter it is important that the sample flow is in a simple direct relation to the main flow. Furthermore, it should be noted that the inlet opening according to the Russian patent document

enters the main part of the wire.

More specifically, this invention therefore takes as its starting point an apparatus for sampling a fluid, which includes a line through which a main flow of a fluid can be led, a probe inserted in the line or in a chamber that communicates with it, which probe has an inlet opening facing downstream of the line and communicating with an outlet opening located in an end surface of the probe, which end surface is located within and at a distance from the wall of the line, which main flow, passing through the line during operation, causes a sample flow of the fluid is drawn from the line and passed through the probe and then back to the line. The new and distinctive feature of the apparatus according to the invention consists primarily in the fact that the probe has a cylindrical shape and is provided with an inlet opening located at a distance from the end surface.

Said main flow of fluid may be impure or otherwise contaminated, or it may consist of more than one phase. Preferably, in practice, an examination device is mounted

in the probe. The examination device can e.g. be a flow meter. Optionally, the examination device may comprise a density meter with a sensor tube through which the sample flow is arranged to pass, and a device for oscillation of the sensor tube and for determining the density of the sample flow on the basis of these oscillations.

The outlet opening can advantageously be located in an end surface with a reduced diameter of the probe.

The inlet opening can communicate with a passage which preferably leads to a recess in the probe, which recess has a diameter that is substantially larger than the diameter of the passage, which recess has an open end which forms the said outlet opening.

A screen can suitably be mounted on the probe to shield the outlet opening.

The invention is illustrated in the drawing solely as an example, as the drawing figures show the following: Figure 1 a flow diagram illustrating the principle of this invention, Figure 2 schematically shows a first embodiment of the device according to the invention, Figure 3 schematically shows part of another embodiment of the device according to the invention, Figure 4 is a partial section through a third embodiment, Figure 5 schematically shows part of the third embodiment, and Figures 6 to 10 schematically show different probes that can be used in the device according to the invention. Figure 1 schematically shows a flow 10 of a fluid containing heavy particles 11 and light particles 12. A cylinder 13 is shown which is located in the direct flow path of the flow 10 and, as can be seen from Figure 1, the current 10 will cause a streamline movement in an area 14 around the cylinder 13, and a backwater area 15 immediately downstream of the cylinder 13.

The heavy particles 11 in the flow 10 collide with the cylinder 13, while the light particles 12 are only deflected radially by the cylinder 13. Consequently, the backwater area 15 is relatively free of both light particles 12 and heavy particles 11.

If therefore the cylinder 13 is provided with a passage

16 which passes through this and has an inlet opening 17 facing downstream in relation to the current 10 and located in the backwater area 15

and an outlet opening 18 which is placed in an end surface 19 of the cylinder 13, then fluid from the backwater area 15 will flow into passage: 16 and out through the outlet opening 18. This flow through the passage 16 occurs due to the difference in the pressures that exist at the inlet opening 17 and the outlet opening 18. This fluid flow through the passage 16 will be relatively free of both heavy particles 11 and light particles 12 and is therefore very suitable for use as a test flow which is passed through a measuring instrument for determining a parameter of the fluid, e.g. mass flow or density.

Figure 2 therefore shows schematically a first embodiment of an apparatus according to the invention.

Figure 2 shows a line 20 with a main flow 21 which is carried through it, and this main flow 21 can be formed by a dirty or otherwise contaminated fluid flow or it can be a fluid consisting of two or more phases. An essentially cylindrical probe 22 is inserted into the line 20, which probe 22 has a test passage 23 which passes through it. This test passage 23 has an inlet opening 24 which faces downstream in the line 20 and an outlet opening 25 which is placed on an end surface 26 of the probe 22. This end surface 26 is located within and at a distance from the wall of the line 20. The inlet opening 24 is located at a smaller distance from the wall of the line 20 than from the end surface 26. As explained above below

reference to Figure 1, the main flow when moving through the line 20 will consequently cause a sample flow of fluid to be drawn from the line 20 and passed through the sample passage 23 in the probe from the inlet opening 24 to the outlet opening 25 and then back to the line 20. As this sample flow consists of fluid which is extracted from the backwater area on the downstream side of probe 22, it contains very little dirt or other contaminants.

Furthermore, if the fluid in the line 20 consists of two phases, the sample flow will be formed by the pure base fluid. In contrast to what is previously known, the inlet opening 24 will therefore not quickly become clogged by dirt or contamination.

The test passage 23, which during operation has a continuous flow of continuous fluid, communicates with a chamber 27 which is closed except for the end which communicates with the test passage 23. Consequently, the fluid in the chamber 27 will be relatively stagnant.

A "flow" thermistor 28 is mounted in the sample passage 23, while a "reference" thermistor 29 is mounted in the chamber 27. The thermistors 28, 29 form part of a flow meter of the type described in British patent 1,463,507.

It will therefore be realized that the construction shown in Figure 2 is such that it prevents the introduction of significant amounts of dirt or other contaminants from entering the flow meter.

The construction shown in Figure 3 can be arranged in a generally similar manner to that in Figure 2, and for this reason it will not be described in detail, since like reference numbers indicate corresponding parts. In Figure 3, however, a test passage 23a is used which passes outside the line 20 to and from a flow meter or other instrument (not shown).

Figure 4 shows yet another embodiment according to this invention, where a main line 30 has a main flow 31 which is horizontal and which carries a soiled or otherwise? way contaminated fluid. The line 30 has a flange part 32 whose interior 33 communicates with the interior of the main line 30. The outer end of the flange part 32 is closed with an end plate 34. Through this end plate 34 a cylindrical probe 35 is passed which sticks in in the horizontal flow 31. The probe 35 is sealed against the end plate 34 by means of a seal 36. The probe 35 has a continuous test passage 40 which is provided with an inlet opening 41 which faces downstream in the main line 30 and with an outlet opening 42 which is placed in an end surface 43 of the probe 35. When the horizontal stream 31 passes through the main line 30, it causes a sample flow of fluid to be drawn through the sample passage 40 from the inlet opening 41 to the outlet opening 42 and then back to the main line 30.

A density measuring instrument 44 is arranged in the test passage 40, e.g. of the type shown in British Patent 1,175,586.

A density meter of the type shown at 44 is extremely sensitive to fouling because any such fouling can affect the oscillations of a sensor tube (not shown) therein or can even prevent that tube from oscillating at all. However, the construction shown in Figure 4 ensures that the sample stream passing through the density meter 44 contains absolutely no impurity, no matter how dirty the fluid that is passed through the main line 30 is.

Figure 5 shows a further embodiment of the device according to the invention, which is largely similar to that in figure 3, and which for this reason shall not be described in detail, as like reference numbers indicate corresponding parts. In the construction on

figure 5, however, the inlet opening 24 is located within and in connection with a chamber 50 which communicates with the line 20 and forms a "pocket" therein. The concentration of contamination in the chamber 50 will generally be less than in the main part of the line 20, as the fluid in the chamber 15 will be relatively stagnant and consequently be both open to the static pressure in the line and less exposed to eddies and noise in the main part of the line 20. The higher pressure in chamber 50 also increases sensitivity.

Figures 6 to 10 schematically illustrate a number of different probes that can be used instead of those in Figures 2

to 5.

Thus, figure 6 shows a cylindrical probe 22a

with an inlet opening (not shown) which communicates with a passage 51. This passage is led through an end portion 52 with a reduced diameter of the probe 22a. The passage 51 leads to an outlet opening 53 which is arranged in an end face 54 with a reduced diameter of the probe 22a. The end portion 52 with a reduced diameter increases the suction effect and provides a greater pressure difference, greater flow and better sensitivity.

Figure 7 shows a cylindrical probe 22b with an inlet opening (not shown) which communicates with a passage 52 leading to a recess 53 in the probe 22b. The recess 53, which has a diameter substantially larger than the diameter of the passage 52, is provided with a thin, curved, peripheral wall 54. The recess 53

has an open end 55 which constitutes the outlet opening from the probe 22b. The design shown in figure 7 helps to improve linearity.

Figure 8 shows a probe 22c which largely corresponds to the one in Figure 2, but which has a screen 56 mounted on the probe to shield its outlet opening 57 from disturbing effects caused by the pipeline wall.

Figure 9 shows a probe 22b with a portion 52 which has a reduced diameter and other features that correspond to those in the probe 22a in Figure 6, and which is further provided with the screen 56 as in Figure 8.

Figure 10 shows a probe 22e with a recess 53

and other features which correspond to those in the probe/22b in figure 7, and in addition to this it is provided with the screen 56 as in figure 8.

All the different designs shown in the figures

5 to 10 helps improve sensitivity at low flow,

increasing immunity to fouling, improving linearity over a wide working range and enabling the use of the device in smaller pipes or conduits than would otherwise be possible.

Claims (6)

1. Apparatus for sampling a fluid, comprising a line through which a main flow of a fluid can be passed, a probe (13, 22) inserted in the line or in a chamber communicating therewith, which probe has an inlet opening (17, 24) facing downstream of the line and which communicates with an outlet opening (18, 25, 53) which is located in an end surface (19, 26) of the probe, which end surface is located within and at a distance from the wall of the conduit, which main current, which during operation passes through the conduit, causes that a sample flow of the fluid is drawn from the line and passed through the probe and then back to the line, characterized in that the probe (13, 22) has a cylindrical shape and is provided with an inlet opening (17, 24) which is located at a distance from the end surface (19, 26). 2. Apparatus according to claim 1, characterized in that the probe is inserted in a chamber (50) which communicates with the line (20), and that the probe (22) has an inlet opening (24) which is placed in the chamber (50) and is open to the static pressure in the line (20). 3. Apparatus according to claim 2, characterized in that the inlet opening (24) is located at a smaller distance from the wall of the line (20) than from the aforementioned end surface (26). 4. Apparatus according to claim 3, characterized in that the outlet opening (53) is located in an end surface (54) with a reduced diameter of the probe. 5. Apparatus according to claim 3, characterized in that the inlet opening communicates with a passage (52) which leads to a recess (53) in the probe (22b), which recess (53) has a diameter that is substantially larger than the diameter of the passage (52) , and that the recess (53) has an open end which forms the aforementioned outlet opening. 6. Apparatus according to one of the preceding claims, characterized in that a screen (56) is mounted on the probe to shield the outlet opening (57).