DE2838023A1 - DEVICE FOR EXAMINATION OF STREAMING MEDIA - Google Patents

Description

Patent attorneys Dipl.-Ing. H. Weiokmann, Ditl-Phys. Dr. K. Fincke

Dipl.-Ing. F. A. Weickmann, Dipl.-Chem. B. Huber

Dr.-Ins.H. Liska

DXIIIH 8 MÜNCHEN 86, DEN 3 J _t / 5 [jg,

POST BOX 860 820 MÖHLSTRASSE 22, CALL NUMBER 98 39 21/22

J. AGAR INSTRUMENTATION LIMITED, Prospect Road, Alresford, Hampshire SO 24 9QG, UK

Device for the investigation of flowing media

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description

The present invention relates to a device for examining flowing media which contaminate can be and / or contain several phases, on one parameter or several parameters simultaneously, with one the main line through which the medium flows, with one in the main line or in one communicating with the main line Chamber inserted probe into which a test flow of the medium from the main line is introduced and into the main line is passed back, and with a measuring arrangement for examining the test flow.

In the device specified above, a flowing medium can, for example, on the mass flow, the Density, temperature, pH, conductivity or to carry out chemical and / or physical Analyzes, such as the percentage of oxygen, can be examined. Furthermore you can also at the same time several parameters, for example density and temperature, can be determined at the same time.

The investigation of a flowing medium to determine one of its parameters, for example its density, is usually carried out in such a way that the medium is passed through a main line into which a probe is inserted * is, the inlet opening of which faces the flowing medium in the direction of flow and which has an outlet opening communicates which is arranged in the flow direction behind her. To study the through the probe A measuring device, such as a density measuring device, is provided for determining a parameter in the flowing test flow. A protection against contamination can be placed over the inlet opening

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be provided so that the test flow before entry into the measuring device in two sharply bent flow arms, is split, reducing the amount of dirt entering the meter. However, this is the Amount of dirt that can enter the measuring device considerably large.

The present invention is therefore based on the object of specifying a device of the type in question, in which the amount of dirt carried in the test flow can be significantly reduced.

To solve this problem is in a device of initially mentioned type provided according to the invention that the probe has an inlet opening which is in the main line seen in the direction of flow on the side facing away from the inflowing medium and with an outlet opening communicates in an end face of the probe, and that the end face within the main line at a distance from it Wall is arranged.

In the device according to the invention defined above, a test flow is sucked out of the main line and through the sample from the inlet port to the outlet port and then returned to the main line »There. the test flow is examined. .. "" ".

In the broadest sense, the term "line" includes any type of flow-guiding elements, such as open ones Channels, tubes and flow beds.

The probe is preferably cylindrical and in particular as Circular cylinder formed. A circular cylindrical probe is suitable especially for line pipes, as in these in simpler

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Way a circular hole can be drilled, in which the probe can be inserted tightly. However, the probe can can also be formed by an angular body, for example a body with sharp edges, which has square, rectangular or triangular end faces.

The measuring arrangement, which can for example be a flow meter, is mounted in the probe.

However, a density measuring device with an oscillating test tube can also be used as the measuring arrangement, with the density of the test flow can be determined from the vibrations of the test tube.

In a further development of the invention, the outlet opening in a reduced diameter end face of the probe may be provided.

According to a further development of the invention, the inlet opening can communicate with a channel which leads to a recess leads in the probe, the recess having a larger diameter compared to the diameter of the channel and has an open end forming the outlet opening.

A shield can in particular be used for the outlet opening be provided.

The invention is illustrated below with reference to “from in the figures the drawing illustrated embodiments explained in more detail. It shows:

1 shows a flow diagram to explain the principle of the invention;

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2 shows a schematic representation of a first embodiment of the device according to the invention;

3 shows a schematic representation of a second embodiment the device according to the invention;

FIG. 4 shows a cross section, partially broken away, of a third embodiment of FIG device according to the invention;

5 shows a schematic representation of part of the third embodiment of the device according to the invention ; and

6 to 10 each show a schematic representation of various probes which are used in an inventive Device are used.

FIG. 1 shows a flow 10 of a flowing medium which contains heavy particles 11 and light particles 12. A cylinder lying in the direct flow path of the flow 10 creates a flow area 14 and a suction area 15 directly on its rear side.

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

The cylinder 13 has a channel 16 with an inlet opening 17, which is seen in the direction of the flow 10 is located on the side facing away from the inflowing medium in the suction area 15, and with an outlet opening 18, which in an end surface 19 is arranged, the medium flows out

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the suction area 15 into the channel 16 and out of the outlet opening 18 out. This flow through the channel 16 is due to a pressure difference at the inlet opening 17 and at the outlet opening 18. The flow in the channel 16 is relatively free of both heavy particles 11 and of light particles 12, so that it is suitable as a test flow which can be passed through a measuring device, to measure a parameter of the flowing medium, such as the mass flow or the density.

In the first embodiment of the device according to the invention shown in FIG. 2, a line 20 is provided, which is flowed through by a main flow 21, this flow being formed by a flowing medium that is contaminated and / or contains two or more phases. There is a cylindrical probe in the pipe 22 is used, which has a test flow channel 23. This test flow channel 23 has an inlet opening 24, which, viewed in the direction of flow, lies on the side facing away from the inflowing medium, and one in an end face 26 provided outlet opening 25. The end face 26 lies within the line 20 at a distance from their wall. As was explained with reference to FIG. 1, the main flow flowing in the line 21 causes a Sucking in a test flow into the test flow channel of the probe from the inlet opening 24 to the outlet opening 25 and back into the line 20. Since the test flow is formed by flowing medium that comes from the suction area is sucked off on the side of the probe 22 facing away from the inflowing medium, it contains a very small proportion of pollution. If the flowing medium in the line 20 contains two phases, the test flow is through alone formed the basic clean flowing medium. In contrast to known devices, the Inlet opening 24 no dirt.

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The test flow channel 23, through which the flowing medium passes in a continuous stream, communicates with a chamber 27 which, apart from its end communicating with the test flow channel 23, is closed. The flowing medium in the chamber 27 stagnates to a certain extent.

A flow thermistor 28 is located in the test flow channel 23 mounted, while a reference thermistor 29 is mounted in the chamber 27. These thermistors 28 and 29 form one Part of a flow meter as described in British Patent 1,463,507.

The embodiment according to FIG. 2 described above is designed so that significant amounts of dirt cannot flow through the flow meter.

The embodiment shown in FIG. 3 and provided with corresponding reference numerals corresponds essentially the embodiment of Figure 2 and is therefore here not described in detail. In this embodiment according to Figure 1, however, a test flow channel 23a is provided, which outside the line 20 to a not shown Measuring instrument leads.

In the embodiment shown in Figure 4, a main line 30 leads a horizontal main stream 31 of a contaminated flowing medium. The line 30 is provided with a flange 32, the interior 33 of which with the interior the main line 30 communicates and the outer end of which is closed by an end plate 34. Through this End plate 34 protrudes a cylindrical probe 35 into the horizontal flow 31, this probe through a Seal 36 is sealed to the end plate. The probe has a test flow channel 40 with an inlet port 41,

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which seen in the direction of flow on the facing away from the medium, as well as an outlet opening 42 in an end surface 43. From the horizontal Flow 31 in the main line 30 is a test flow in the test flow channel 40 from the inlet port 41 to Outlet port 42 and pulled back into main line 31.

A density meter 44 is provided in the test flow channel 40, such as that in the British patent 1 175 586 is described.

Such a density measuring device, denoted by 44, is extremely sensitive to dirt, since any soiling Can influence or even prevent vibrations of a (not shown) test tube. The one shown in FIG However, construction ensures that the test tube passing through density meter 44 has virtually no test tube Contains dirt, although the medium flowing through the main line 30 may contain dirt.

The embodiment shown in FIG. 5 and provided with corresponding reference numerals corresponds to the invention essentially the embodiment of Figure 3. In the embodiment of Figure 5 is the inlet port 24, however, arranged within a chamber 50 which communicates with the line 20 and with this a "pocket" forms. The concentration of dirt in the chamber is generally lower than in the main part of the line 20, wherein the flowing medium in the chamber 50 stagnates to some extent, so that compared to the main part of the conduit 20 lower turbulence are present. The higher pressure in chamber 50 also increases sensitivity.

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Figures 6 to 10 show schematically different Versions of probes which can be used instead of the probes according to FIGS. 2 to 5.

Figure 6 shows a cylindrical probe 22a with a (not shown) Inlet opening, which is connected to a channel 51 communicates through an end portion 52 with reduced Diameter of the probe 22a runs. The channel 51 leads to an outlet opening 53 in a reduced diameter end surface 54 of the probe 22a. The end portion 52 with reduced Diameter increases the suction, resulting in a greater differential pressure, a stronger flow and a leads to better sensitivity.

Figure "7 shows a cylindrical probe 22b with a (not shown) Inlet opening which communicates with a channel 52 which leads to a recess 53 in the probe 22b leads. This recess 53, the diameter of which is larger than the diameter of the channel 52, is in a thin one curved peripheral wall 54 is provided. The recess 53 has an open end 55, which the outlet opening of the son * de 22b forms. This embodiment according to FIG. 7 supports the improvement of the linearity. ,

FIG. 8 shows a probe 22c which essentially corresponds to the probe according to FIG. However, this probe has a ■ Screen 56 for an outlet opening 57 in order to eliminate influences from the pipeline wall.

FIG. 9 shows a probe 22d with a part 52 of reduced diameter and other design features accordingly of the probe 22a according to FIG. 6, a shield 56 according to FIG. 8 being additionally provided.

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FIG. 10 shows a probe 22e with a recess 53 and further design features corresponding to the probe 22b according to FIG. 7, a shield according to FIG. 8 also being provided.

The embodiments according to FIGS. 5 to 10 improve the sensitivity to weak currents, the insensitivity against dirt, the linearity in a larger working area and allow use the device in smaller tubes.

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Claims (9)

Claims 1.) Device for the investigation of flowing media, welehe can be dirty and / or contain several phases, on one or several parameters at the same time, with a main line through which the medium flows, with one in the main line or in one with the main line communicating probe inserted into which a test flow of the medium from the Main line is initiated and returned to the main line, and with a measuring arrangement for investigation the test flow, thereby g e k e η η shows that the probe (22) has an inlet opening (24) which in the main line (20, 30) seen in the direction of flow on the side facing away from the inflowing medium and with an outlet opening (25, 53, 57) in an end face (26, 54.) of the probe (22) communicates, and that the end face (26, 54) inside the main line (20, 30) is arranged at a distance from its wall. 2. Apparatus according to claim 1, characterized in that the probe (22) is cylindrical. 3. Apparatus according to claim 1 and 2, characterized marked. net that the probe (22) is designed as a circular cylinder. 4. Device according to one of claims 1 to 3, characterized characterized in that the measuring arrangement (44) is mounted in the probe (22). 5. Device according to one of claims 1 to 4, characterized characterized in that the measuring arrangement (44) is a flow meter. 90981 5/0690 6. Device according to one of claims 1 to 4, characterized in that the measuring arrangement (44) is a density measuring device with an oscillatable test tube,
the density of the test flow can be determined from the vibrations of the test tube. 7. Device according to one of claims 1 to 6, characterized in that the outlet opening (53) in one
Reduced diameter end face (54) of the probe
is provided. 8. Device according to one of claims 1 to 7, characterized in that the inlet opening communicates with a channel (52) which leads to a recess (53) in the probe (22b), and that the recess (53) one in comparison to the diameter of the channel (52) larger diameter as well as an open one forming the outlet opening
End owns. 9. Device according to one of claims 1 to 8, characterized by a shield (56) for the outlet opening (57). 90981 5/0690