DE202020102087U1 - Measuring probe - Google Patents

Abstract

Measuring probe with a probe body (2) having a measuring section (3) and extending at least in this in an axial direction (x), the measuring section (3) of which has an inflow side (9) and one of these extending transversely to the axial direction (x) Inflow direction (y) has opposite outflow side (10) and two lateral directions (z) running transversely to the axial direction (x) and transversely to the inflow direction (y), opposite outer sides (11, 12), with the inflow side (9) a trough-shaped recess (13) elongated in the axial direction (x) and in the bottom (14) of which at least one inflow-side measuring opening (15) is introduced, which leads to a first fluid line (16) provided in the probe body (2), and in the outflow side (10) has at least one outflow-side measuring opening (17) which leads to a second fluid line (18) provided in the probe body (2), characterized in that on the outer sides (11, 12) each because a laterally protruding, linear outer edge (33) running in the axial direction (x) is provided.

Description

The invention relates to a measuring probe with a probe body having a measuring section and extending at least in this in an axial direction, the measuring section of which has one inflow side, one outflow side opposite this in an inflow direction running transversely to the axial direction and two in one transverse to the axial direction and transversely to the In the inflow direction extending lateral direction has mutually opposite outer sides, wherein in the inflow side a trough-shaped, in the axial direction elongated recess and in the bottom at least one inflow side measuring opening are introduced, which leads to a first fluid line provided in the probe body, and in the outflow side at least one outflow side Measurement opening is introduced, which leads to a second fluid line provided in the probe body.

Such a measuring probe is, for example, from DE 10 2004 020 284 A1 known and is used in particular for differential pressure measurement. The length of the probe body in the direction of flow is designed to be several times the width of the probe body in the lateral direction. The disadvantage here is that fluid flowing past the measuring probe in the flow direction can lead to undefined pressure conditions on the outflow side and thus to an impairment of the measurement accuracy.

Proceeding from this, the invention is based in particular on the object of being able to avoid the aforementioned disadvantage.

According to the invention, this object is achieved by a measuring probe according to claim 1. Preferred developments of the invention are given in the subclaims and in the following description.

A measuring probe with a probe body having a measuring section and extending at least in this in an axial direction, the measuring section of which has one inflow side, one outflow side opposite this in an inflow direction running transversely to the axial direction, and two lateral sides extending transversely to the axial direction and transversely to the inflow direction Direction of mutually opposite outer sides, wherein in the inflow side a trough-shaped, in the axial direction elongated recess and in the bottom of at least one inflow-side measuring opening are made, which leads to a first fluid line provided in the probe body, and in the outflow side at least one outflow-side measuring opening is made , which leads to a second fluid line provided in the probe body, is further developed according to the invention, in particular, in that a laterally protruding line extending in the axial direction is provided on the outer sides ige outer edge is provided.

The laterally protruding, linear outer edges running in the axial direction lead to a defined flow break-off and thus to defined pressure conditions on the outflow side, in particular in the case of a fluid flowing past the probe body in the flow direction. The outer edges are or form, in particular, flow separation edges.

According to one embodiment, the measuring section and / or the probe body is exposed or can be exposed to the or a fluid in or at least in the measuring section, which fluid flows in particular in the direction of flow. Each outer edge is preferably or forms a flow separation edge, in particular for the or a preferably flowing fluid. The fluid is, for example, a gas. For example, the fluid is air or compressed air.

A central plane extending in the axial direction and in the direction of flow and running in the lateral direction centrally between the outer sides is preferably assigned to the measuring section. The probe body is preferably designed to be mirror-symmetrical in or at least in the measuring section with respect to the center plane. Thus, in the case of the or a fluid flowing past the measuring probe in the flow direction z .B. Set the same flow conditions on both sides of the measuring section. A lateral plane extending in the axial direction and in the lateral direction as well as running in the inflow direction centrally between the inflow side and the outflow side is advantageously assigned to the measuring section. A, preferably free, end of the measuring section preferably forms an, in particular a first, axial end of the probe body.

According to a further development, a laterally protruding projection is provided on each of the outer sides and has one of the outer edges. Each projection preferably tapers in the lateral direction and / or to the side and / or to the side and / or to the side outward to the respective outer edge, in particular in a wedge shape. Each projection preferably has an upstream front side and a downstream rear side, which at its outer edge converges with its front side. Preferably, the front of each protrusion extends in the axial direction. The front side of each projection is advantageously designed to be flat. Preferably, the back of each protrusion extends in the axial direction. The rear side of each projection is advantageously designed to be flat.

According to one embodiment, the projections and / or each projection is wedge-shaped. In particular, each projection has, preferably two, wedge surfaces which preferably converge at its outer edge. The wedge surfaces of each projection are advantageously formed by its front side and its rear side. For example, each projection is designed in the form of a prism with a triangular base. Such a prism is also referred to as a triangular prism, for example. Preferably, the projections each enclose an obtuse, an acute or a right angle on their outer edges. In particular, the wedge surfaces and / or the front side and the rear side of each projection enclose an obtuse, an acute or a right angle with one another at its outer edge.

The outer sides preferably extend in the inflow direction from the inflow side to the outflow side. In particular, each outer side has a flat area which preferably runs in the axial direction. The flat area of each outer side is preferably located in the direction of flow between the flow side and the respective protrusion or the respective outer edge. According to a first alternative, for example, the outer sides and / or the planar or planar areas of the outer sides run, preferably in the direction of flow, preferably from the flow side to the projections or outer edges and / or between the flow side and the projections or outer edges, in particular at least in some areas, parallel or approximately parallel to each other. According to a second alternative, for example, the outer sides and / or the planar or planar areas of the outer sides, preferably in the direction of flow, preferably from the flow side to the protrusions or outer edges and / or between the flow side and the protrusions or outer edges, in particular at least in some areas, wedge-shaped . The outsides and / or the planar or planar areas of the outsides are advantageous, preferably in the flow direction, preferably from the flow side to the projections or outer edges and / or between the flow side and the projections or outer edges, in particular at least in some areas, in the direction of the flow side towards one another too inclined and / or inclined away from one another in the direction of the downstream side or the projections or outer edges.

In the measuring section, the probe body has, in particular, a greater spatial extent in the direction of flow than in the lateral direction. In the measuring section, especially if the outer edges and / or projections are ignored or left out or neglected, the length of the probe body in the direction of flow is preferably several times or at least one and a half times the width of the probe body in the lateral direction. This can be due, for example, to the fact that the fluid lines are arranged one behind the other in the direction of flow. Furthermore, this can be due, for example, to making the upstream side as narrow as possible in the lateral direction in order to achieve a low flow resistance.

The outer edges or each outer edge are or is arranged in the direction of flow, e.g. in the middle between the flow side and the flow side. If the distance between the outer edges and the outflow side in the inflow direction is too great, however, undefined pressure conditions can arise in spite of the outer edges on the outflow side. According to a further development, the outer edges or each outer edge is arranged closer to the outflow side in the inflow direction than on the inflow side. In this way, for example, defined pressure conditions can be ensured or achieved on the downstream side, for example even if the probe body has a relatively large spatial expansion in the direction of flow. The outer edges and / or each outer edge, in particular in the inflow direction, are preferably arranged offset relative to the lateral plane in the direction of the outflow side. Thus, the outer edges and / or each outer edge is arranged in the inflow direction, in particular closer to the outflow side than to the inflow side. The projections and / or each projection is preferably arranged closer to the outflow side than to the inflow side in the inflow direction. The projections and / or each projection is preferably arranged offset, in particular in the direction of flow, with respect to the lateral plane in the direction of the side of the flow. The outer edges and / or the projections are advantageously arranged on the outflow side or in the inflow direction between the lateral plane and the outflow side.

According to one embodiment, the fluid lines, in particular in the probe body and / or in or at least in the measuring section, preferably in each case, run in the axial direction. The fluid lines, in particular in the probe body and / or in or at least in the measuring section, are preferably arranged one behind the other in the direction of flow. The first fluid line is preferably arranged closer to the inflow side in the inflow direction than on the outflow side. The first fluid line is advantageously arranged closer to the upstream side in the flow direction than the second fluid line. The second fluid line is preferably arranged closer to the outflow side in the inflow direction than on the inflow side. The second fluid line is advantageously arranged closer to the outflow side in the inflow direction than the first fluid line. The first fluid line is preferably offset, in particular in the flow direction, in relation to the lateral plane in the direction of the flow side arranged. The second fluid line is advantageously arranged offset in relation to the lateral plane in the direction of the outflow side, in particular in the direction of flow. The second fluid line is preferably arranged in the lateral direction between the projections and / or the outer edges. The fluid lines are preferably each designed as a bore and / or as a particularly cylindrical hole.

According to a first alternative, the trough-shaped depression has a flat bottom. For example, the trough-shaped recess has a U-shaped cross section, in particular in a sectional plane running transversely to the axial direction. The legs of the U-shaped cross-section can enclose, for example, a right or an obtuse angle with the back of the U-shaped cross-section.

According to a second alternative, the trough-shaped depression has, for example, a curved or at least partially curved base.

For example, the trough-shaped depression has a partially circular or semicircular cross section, in particular in the or a section plane running transversely to the axial direction. The base is preferably curved into the probe body.

A plurality of, for example two or three, measuring openings on the inflow side are preferably made in the bottom of the elongated depression, which lead to the first fluid line and are in particular spaced apart from one another in the axial direction. Preferably, several, for example two or three, measuring openings on the outflow side are introduced into the outflow side, which lead to the second fluid line and are in particular spaced apart from one another in the axial direction. The multiple measuring openings open up the possibility, for example, that any condensate that may occur can drain off better.

According to a further development, the probe body has a connection area, in particular at a, preferably axial, distance from the measuring section. The fluid lines preferably run, preferably from the measuring section, to the connection area. The fluid lines advantageously run in the axial direction and / or straight, preferably from the measuring section, in particular up to the connection area. The probe body advantageously runs in the axial direction and / or straight, preferably from the measuring section to the connection area. Two measurement connections are preferably provided in the connection area, of which a first measurement connection leads to the first fluid line and a second measurement connection leads to the second fluid line. A sensor unit and / or a differential pressure sensor or differential pressure transducer and / or at least one or more pressure sensors or pressure transducers is or are preferably connected and / or connectable to the measuring connections and / or to the fluid lines, in particular in the connection area. The sensor unit is or comprises, in particular, a pressure sensor unit. The sensor unit preferably comprises the or one or at least one pressure sensor or differential pressure sensor or the or more pressure sensors. The connection area advantageously forms an, in particular a second, axial end of the probe body.

Two test connections are preferably provided in the connection area, of which a first test connection leads to the first fluid line and / or to the first measurement connection and a second test connection leads to the second fluid line and / or to the second measurement connection. The test connections are in particular closed by, preferably releasable, closure elements, in particular tightly. The closure elements are or include, for example, plugs or screw plugs or screws.

According to one embodiment, the probe body has a stem section axially adjoining the measuring section and preferably extending in the axial direction, in particular up to the connection area. The fluid lines, in particular also, are advantageously provided in the trunk section and / or the fluid lines run, in particular also, in and / or through the trunk section. At least one channel is preferably provided in the trunk section, in particular in addition to the fluid lines, which preferably extends from an end region of the trunk section facing the measuring section to the connection region. Advantageously, two or more channels are provided in the trunk section, in particular in addition to the fluid lines, which preferably extend from the or one end area of the trunk section facing the measuring section to the connection area. The or each channel preferably runs in the axial direction. In particular, the or each channel runs straight. The or each channel is advantageously open or closed at its end facing the end region. The or each channel is preferably closed or closable at its end facing the end region, in particular by a preferably releasable closure element, in particular tightly. The or each channel can advantageously be closed or opened at its end facing the end region, in particular by the or a preferably releasable closure element. The or each closure element is or comprises, for example, a plug or screw plug or a screw. The channels are preferably arranged next to one another in the lateral direction. For example, especially in the trunk section, the channels together with the fluid lines have a cruciform arrangement. The or each channel is advantageously designed as a bore and / or as a particularly cylindrical hole.

The or each channel is preferably open and / or accessible in the connection area and / or at its end facing the connection area. For example, at least one sensor or measured value recorder or several sensors or measured value recorders are provided and / or connected on or in the duct or on or in the ducts. The sensor or measured value recorder or the sensors or measured value recorders comprises or include, in particular, one or at least one temperature sensor or temperature recorder, by means of which, for example, the temperature, in particular the temperature of the fluid, can be measured and / or recorded in the area of the measuring section. Additionally or alternatively, the sensor or measured value recorder or the sensors or measured value recorders comprises, for example, one or at least one oil sensor, by means of which, in particular, the or an oil content or residual oil content in the fluid can be measured. In addition or as an alternative, the sensor or measured value recorder or the sensors or measured value recorders comprises, for example, one or at least one particle sensor, by means of which particles in the fluid in particular can be detected and / or counted.

According to a further development, the probe body is connected to a measuring fitting. The measuring fitting preferably comprises a wall delimiting a measuring space. The probe body, in particular with or at least with its measuring section, is advantageously introduced or can be introduced into the or a measuring chamber of the measuring fitting. The probe body, in particular with or at least with its measuring section, is preferably introduced or can be introduced into a pipeline or into a container, preferably by means of the or a measuring fitting. The or a fluid is preferably provided or can be provided in the measuring space of the measuring fitting and / or in the pipeline or in the container. The or a fluid preferably flows in the measuring space of the measuring fitting and / or in the pipeline or in the container, in particular in the direction of flow.

According to one embodiment, the probe body extends, in particular with its trunk section or with at least one area of its trunk section, through the or a wall of the or a measuring fitting or pipeline or of the or a container. The probe body preferably has a round or non-round outer circumferential contour in the trunk section or in at least one or in the at least one area of the trunk section. For example, the probe body has a circular or an elliptical outer circumferential contour in the trunk section or in at least one or in the at least one area of the trunk section. Due to this non-circular or elliptical outer circumference contour, the probe body can e.g. be oriented and / or non-rotatably mounted on the measuring fitting or pipeline and / or on the container.

• 1 eine perspektivische Ansicht einer Messsonde gemäß einer ersten Ausführungsform,
• 2 einen Längsschnitt durch die Messsonde nach 1,
• 3 eine Seitenansicht der Messsonde nach 1 mit einem geschnitten dargestellten Bereich,
• 4 einen Querschnitt durch einen Messabschnitt der Messsonde entlang einer aus 2 ersichtlichen Schnittlinie A-A,
• 5 einen Querschnitt durch einen Messabschnitt einer Messsonde gemäß einer zweiten Ausführungsform,
• 6 einen Querschnitt durch einen Messabschnitt einer Messsonde gemäß einer dritten Ausführungsform und
• 7 einen Querschnitt durch einen Messabschnitt einer Messsonde gemäß einer vierten Ausführungsform.

The invention is described below on the basis of preferred embodiments with reference to the drawing. In the drawing show:

• 1 a perspective view of a measuring probe according to a first embodiment,
• 2 a longitudinal section through the measuring probe 1 ,
• 3 a side view of the measuring probe according to 1 with a section shown,
• 4th a cross section through a measuring section of the measuring probe along one from 2 visible section line AA,
• 5 a cross section through a measuring section of a measuring probe according to a second embodiment,
• 6th a cross section through a measuring section of a measuring probe according to a third embodiment and
• 7th a cross section through a measuring section of a measuring probe according to a fourth embodiment.

the end 1 Fig. 3 is a perspective view of a measuring probe 1 can be seen according to a first embodiment, wherein the measuring probe 1 one moving in an axial direction x extending probe body 2 with a measuring section 3 and one on this in the axial direction x subsequent trunk section 4th having. The trunk section extends 4th in the axial direction x from the measuring section 3 up to a connection area 5 , which is preferably an axial end of the probe body 2 forms. One in the axial direction x running central longitudinal axis of the measuring probe 1 is with the reference number 6th marked. There is also a coordinate system 7th shown, whose x-axis is the axial direction x , the y-axis of which is a direction of flow y and its z-axis is a lateral direction z represents. The coordinate axes shown x , y and z form in particular an orthogonal legal system in this order.

the end 2 is a longitudinal section through the measuring probe 1 along the central longitudinal axis 6th visible in the xy plane. Also shows 3 a side view of the measuring probe 1 with one along the Central longitudinal axis 6th Area shown cut in the xz plane 8th . Supplementary shows 4th a cross section through the measuring section 3 the measuring probe 1 along the out 2 apparent section line AA and transverse to the axial direction x .

In the measuring section 3 points the probe body 2 an upstream side 9 , one of these in the direction of flow y opposite downstream side 10 and two outer sides opposite one another in the lateral direction 11 and 12th on. In the upstream side 9 is a trough-shaped, in the axial direction x elongated depression 13th introduced into their soil 14th several upstream measurement openings 15th are introduced to one in the probe body 2 provided first fluid line 16 lead in the axial direction x to the connection area 5 extends. Furthermore, are in the downstream side 10 several downstream measurement openings 17th introduced to one in the probe body 2 provided second fluid line 18th lead in the axial direction x to the connection area 5 extends.

In the connection area 5 are two measuring connections 19th and 20th provided, of which a first measuring connection 19th to the first fluid line 16 and a second measuring connection 20th to the second fluid line 18th leads. In particular, the measuring connections 19th and 22nd a schematically indicated differential pressure sensor 21 connected or connectable. Also in the connection area 5 two test connections 22nd and 23 provided, of which a first test connection 22nd to the first fluid line 16 and a second test connection 23 to the second fluid line 18th leads. The test connections 22nd and 23 are through detachable locking elements 24 , especially in the form of screw plugs, tightly closed.

In the trunk section 4th are in addition to the fluid lines 16 and 18th two channels 25th and 26th provided that extends from one of the measuring section 3 facing end area 27 of the trunk section 4th to the connection area 5 extend.

Each channel is at its end 27 facing end by a releasable closure element 28 , in particular in the form of a screw plug, closed. For example, a measured value sensor is provided in at least one of the channels.

Further is on the trunk section 4th a mounting flange 29 provided by means of which the probe body 2 the measuring probe 1 on a measuring fitting 30th can be fastened, one of which is a measuring room 40 limiting and schematically shown wall 31 has through which the probe body 2 with its trunk section 4th passes so that the measuring section 3 in the measuring room 40 the measuring armature 30th is arranged, in which preferably a fluid 32 , such as compressed air, in the direction of flow y flows.

On the outsides 11 and 12th is one laterally protruding and one laterally protruding in the axial direction x running, linear outer edge 33 having a projection 34 provided that extends in a lateral direction z to the respective outer edge 33 tapered in a wedge shape, the outer edges 33 opposite one in the axial direction x and in a sideways direction z extending as well as in the direction of flow y in the middle between the upstream side 9 and the downstream side 10 running lateral plane 35 towards the downstream side 10 are arranged offset. Thus are the outer edges 33 in the direction of flow y closer to the downstream side 10 than on the upstream side 9 arranged. The central longitudinal axis 6th runs in particular in the lateral plane. Every lead 34 has an upstream front side 38 and a downstream rear 39 on, being the front 38 and the back 39 in particular form wedge surfaces in the respective outer edge 33 converge. Furthermore is in the measuring section 3 the probe body 2 with respect to one in the axial direction x and in the direction of flow y extending as well as in the lateral direction z in the middle between the outsides 11 and 12th running central plane 36 designed mirror-symmetrically.

How out 4th visible, point the outsides 11 and 12th one each in the direction of flow y between the upstream side 9 and the respective lead 34 located, level area 37 on, being the flat areas 37 the outsides 11 and 12th run parallel to each other. Further is the soil 14th the deepening 13th just trained.

the end 5 is a cross section through a measuring section 3 a measuring probe 1 according to a second embodiment, features that are identical or similar to the first embodiment are denoted by the same reference numerals as in the first embodiment. In contrast to the first embodiment, the planes run Areas 37 the outsides 11 and 12th wedge-shaped and are in the direction of the upstream side 9 inclined towards each other. Apart from these differences, the second embodiment is the same as the first embodiment, so that reference is made to the description of the first embodiment for a further description of the second embodiment.

the end 6th is a cross section through a measuring section 3 a measuring probe 1 according to a third embodiment, features that are identical or similar to the first embodiment are denoted by the same reference numerals as in the first embodiment. In contrast to the first embodiment, the flat areas run 37 the outsides 11 and 12th wedge-shaped and are in the direction of the upstream side 9 inclined towards each other. Further is the soil 14th the deepening 13th curved. Apart from these differences, the third embodiment is the same as the first embodiment, so that reference is made to the description of the first embodiment for a further description of the third embodiment.

the end 7th is a cross section through a measuring section 3 a measuring probe 1 according to a fourth embodiment can be seen, features identical or similar to the first embodiment being denoted by the same reference numerals as in the first embodiment. The difference to the first embodiment is the floor 14th the deepening 13th curved in some areas. Apart from these differences, the fourth embodiment is the same as the first embodiment, so that reference is made to the description of the first embodiment for a further description of the fourth embodiment.

List of reference symbols

1

Measuring probe

2

Probe body

3

Measuring section

4th

Trunk section

5

Connection area

6th

Central longitudinal axis

7th

Coordinate system

8th

section shown area

9

Upstream side

10

Downstream side

11

Outside

12th

Outside

13th

deepening

14th

Bottom of the recess

15th

Upstream measurement opening

16

first fluid line

17th

Measurement opening on the downstream side

18th

second fluid line

19th

Measuring connection

20th

Measuring connection

21

Differential pressure sensor

22nd

Test connection

23

Test connection

24

Closure element

25th

channel

26th

channel

27

End of the trunk section

28

Closure element

29

Mounting flange

30th

Measuring fitting

31

Wall of the measuring fitting

32

Fluid

33

Outer edge

34

head Start

35

Lateral plane

36

Middle plane

37

flat area

38

front

39

back

40

Measuring room of the measuring armature

x

axial direction

y

Direction of flow

z

lateral direction

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102004020284 A1 [0002]

Claims (14)

Measuring probe with a probe body (2) having a measuring section (3) and extending at least in this in an axial direction (x), the measuring section (3) of which has an inflow side (9) and one of these extending transversely to the axial direction (x) Inflow direction (y) has opposite outflow side (10) and two lateral directions (z) running transversely to the axial direction (x) and transversely to the inflow direction (y), opposite outer sides (11, 12), with the inflow side (9) a trough-shaped recess (13) elongated in the axial direction (x) and in the bottom (14) of which at least one inflow-side measuring opening (15) is introduced, which leads to a first fluid line (16) provided in the probe body (2), and in the outflow side (10) has at least one outflow-side measuring opening (17) which leads to a second fluid line (18) provided in the probe body (2), characterized in that on the outer sides (11, 12) j in each case a laterally protruding, linear outer edge (33) extending in the axial direction (x) is provided. Measuring probe after Claim 1 , characterized in that a laterally protruding projection (34) is provided on each of the outer sides (11, 12) and has one of the outer edges (33) and tapers laterally to the respective outer edge (33). Measuring probe after Claim 2 , characterized in that each projection (34) is wedge-shaped. Measuring probe after Claim 3 , characterized in that the wedge surfaces (38, 39) of each projection (34) at its outer edge (33) enclose an obtuse angle with one another. Measuring probe according to one of the Claims 2 until 4th , characterized in that each outer side (11, 12) has a flat area (37) lying between the inflow side (9) and the respective projection (34), the flat areas (37) of the outer sides (11, 12) in Direction of flow (y) run parallel to each other. Measuring probe according to one of the Claims 2 until 4th , characterized in that each outer side (11, 12) has a flat area (37) lying between the inflow side (9) and the respective projection (34), the flat areas (37) of the outer sides (11, 12) in Inflow direction (y) run in a wedge shape and are inclined towards each other in the direction of the inflow side (9). Measuring probe according to one of the preceding claims, characterized in that the outer edges (33) in the inflow direction are arranged closer to the outflow side (10) than to the inflow side (9). Measuring probe according to one of the preceding claims, characterized in that at least in the measuring section (3) the fluid lines (16, 18) run in the axial direction (x) and are arranged one behind the other in the flow direction (y). Measuring probe after the Claims 7 and 8th , characterized in that the second fluid line (18) is arranged in the lateral direction (z) between the outer edges (33). Measuring probe according to one of the preceding claims, characterized in that the trough-shaped depression (13) has a flat or at least regionally curved base (14). Measuring probe according to one of the preceding claims, characterized in that the probe body (2) has a connection area (5) at a distance from the measuring section (3), up to which the fluid lines (16, 18) run. Measuring probe after Claim 11 , characterized in that the probe body (2) has a stem section (4) axially adjoining the measuring section (3) and extending in the axial direction (x) to the connection area (5), in which, in addition to the fluid lines (16, 18) at least one channel (25) is provided which extends from an end area (27) of the trunk section (4) facing the measuring section (3) to the connection area (5). Measuring probe according to one of the preceding claims, characterized in that at least in the measuring section (3) the probe body (2) is centered between the outer sides ( 11, 12) extending center plane (36) is designed mirror-symmetrically. Measuring probe according to one of the preceding claims, characterized in that the probe body (2) is exposed or can be exposed at least in the measuring section (3) to a fluid (32) flowing in the inflow direction (y), for which the outer edges (33) form flow separation edges.

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