DE4207043A1 - Gas flow transducer for measuring pressure, flow speed or volume - has rod perpendicular to flow with inlet and outlet apertures one after other in flow direction - Google Patents

Abstract

The transducer has at least metal profile rod (1) perpendicular to the gas flow direction with inlet (2) and outlet (3) flow apertures arranged one after the other in the flow direction. The flow apertures are slots transverse to the length of the rod and longitudinal channels arranged at the ends of the slots opposite the rod surface. A pressure sensor (7) is included on the front of the rod for converting the pressure to electrical signals for display and evaluation. USE/ADVANTAGE - E.g. for controlling ventilation systems. Enables reliable measurement of representative local parameters at low manufacturing, maintenance and operating costs.

Description

The invention relates to a transducer for Determination of pressure, flow velocity or of the flow volume of flowing gases.

Flow to determine pressure, speed and quantity the gases is the use of pitot tubes, in particular so-called Prandtl's pitot tubes, in connection with Differential pressure meters known. Since pitot tubes according to Prandtl no moving parts subject to wear have, they are insensitive to handling and Ge use and are therefore also suitable for use under rough conditions Operating conditions without the need for re-calibration are.  

The well-known pitot tubes consist of a smooth-walled front open hollow cylinder, which has a suitable bore in the pipe or channel wall or an annular slot having. If a gas flows against the pitot tube, so is the total pressure or at the top of the pitot tube Difference in pressure compared to the free atmosphere, while at the hole in the pipe or duct wall or on the annular slot the static pressure or internal Pressure of the gas or the pressure that is parallel to the pipe wall flowing gas exerts on this, is measured.

The dynamic pressure or back pressure or speed pressure is the difference between the two pressure values and represents the greatest pressure increase that occurs in a flowing gas the center of an obstacle occurs. He can by the height of a column of liquid to be measured, the he maintains the balance so that the dynamic pressure is equal the difference between total pressure and static pressure is equal to the height of the liquid column. Therefore he can can be measured directly by looking at the two on Prandtl's pitot tube occurring pressures on the legs a differential pressure meter, for example a U-tube Ma nometers, transmits.

For measuring and controlling the flow velocity or of the flow volume in air ducts are Wilson accumulation grids known as a pressure transducer based on the fundamental Principle of the Prandtl pitot tube based. The traffic jam ter consists of tubes arranged in parallel, which over Manifolds are connected to each other. The pipes point Openings that alternate in one and the other Show flow direction, so that from the parallel arranged  pipes over the header pipes of the dynamic pressure or total pressure and the reference pressure combined into one value will. The perforation of the tubes is such that a average value of dynamic pressure proportional to Cross-section of the air flow at the connecting piece removed men can be, by connecting suitable devices directly read the mean flow velocity or a signal for control or registration forwarded can be.

Disadvantageous when using the Wilson storage grid as Pressure transducer for measuring and controlling the flow rate speed or the flow volume in air channels the relatively large effort in the manufacture and Arrangement of the pipes arranged in parallel, the collecting pipes and the connecting parts for connecting the pipes and collectors tube.

Because the back pressure (total pressure) and the reference pressure different places through mutual use of pipes for taking up the total pressure and pipes for If the reference pressure is measured, it happens Measurement errors. Another disadvantage is that the The cross-sectional area recorded during the measurement is proportional is low and the mean value formed is therefore not inconsiderable is representative of the flow conditions at the measuring location is. This is especially true when turbulence occurs at the measuring point, so that one for the real pressure or Flow conditions recorded non-representative measured value becomes.

The object of the present invention is to provide a measured value to create subscribers of the type mentioned at the outset low manufacturing, maintenance and application effort universal applicability the dynamic part of the Pressure, the flow and / or the flow volume flow emitting gases over a wide range reliably and with represent for the actual conditions at the place of measurement tative measured values recorded.

This task is characterized by the characteristic of Claim 1 solved.

The solution according to the invention allows the dynamic Share of pressure, flow and / or flow flowing gases over a wide range reliably and with representative (mean) measured values, because the total pressure or dynamic pressure as well as the reference pressure according to the principle of the Prandtl pitot tube to immediate bar successive geometric locations and over a continuous total area can be measured.

The rod-shaped or rail-shaped sensor is included can be produced with little effort, its application is in particular very easy in air ducts and the maintenance effort minimal. Especially at measuring points with turbulence representative measured values recorded, the pressure and flow conditions at the measuring point and the flow volume represent representative of the flowing gases.  

An advantageous embodiment of the invention Solution is characterized in that the inflow and outflow openings from across the length of the rod are blue slits and run in the longitudinal direction of the rod the channels exist that abge on that of the rod surface turned end of the slots are arranged.

The separation of the inflow and outflow openings into slots and Channels enables exact measurement and averaging as well as simple connection options for pressure sensors or Connection lines for pressure sensors.

The rod preferably consists of a flat rail with im Cross section of rounded inflow and outflow side, so that low turbulence from the transducer itself hen and the flow resistance is minimal.

The channels are slotted in particular Cylinder formed, preferably the slots continuously from the upstream and downstream side to the channels expand.

By rounding the transition of the slots to the An and / or downstream sides of the rod are turbulence in the Area of detection of the total pressure or reference pressure avoided, so that a representative output signal for the pressure difference is guaranteed.

Another advantageous embodiment of the invention essen solution is characterized in that between the Channels of the rod extend in the longitudinal direction of the rod extending recess on the top and bottom of the  Bar is arranged, the easy attachment of the Bar enables without the risk that one of the two channels, for example when drilling into the rod is damaged.

By forming the rod from a drawn metal profile, preferably a drawn aluminum profile a cheap manufacture with high dimensional accuracy continuous

The connection of the upstream and downstream channels to Acquisition of an average of the total pressure or reference pressure with a suitable differential pressure sensor either done in such a way that the differential pressure sor directly with one open end of the rod is connected or hose connections to a spatially differential pressure sensor separate from the rod manufactured the.

For the acquisition of representative measured values of the pressure, the Flow velocity and / or the flow volume in Gas channels can preferably have several sensors be arranged distributed over the channel cross-section, wherein an arrangement offset in the longitudinal direction of the gas channel the stacked rods have special advantages offers the acquisition of representative measured values.

Based on an exemplary embodiment shown in the drawing game the idea underlying the invention are explained in more detail.  

Show it:

Figure 1 is a schematic perspective view of a rail-shaped transducer.

Fig. 2 shows a cross section through the sensor according to FIG. 1 with a U-tube manometer as a differential pressure meter and

Fig. 3 is a schematic perspective view of several transducers in an air duct.

The sensor, shown in perspective in FIG. 1, for determining the pressure, flow velocity and / or flow volume of flowing gases consists of a flat rail 1 , which is arranged in the position shown in a gas flow indicated by arrows. The longitudinal extent of the flat rail 1 is arranged essentially perpendicular to the flow direction of the gas, while the flat top and bottom of the flat rail 1 are in the flow direction.

On the end faces of the flat rail 1 , slots are arranged centrally, which open into cylindrical channels and form the inflow and outflow opening 2 , 3 of the measuring sensor.

With dashed lines, a U-tube Manome ter 7 is shown schematically as a differential pressure meter, the free legs with the cylindrical channels of the inflow and outflow side 2 , 3 of the flat rail 1 are connected. Due to the direction of flow of the gas and depending on the flow speed and the density of the gas, a differential pressure Delta p results, which indicates the dynamic pressure of the flowing gas and is kept in balance by the height of the liquid column of the U-tube manometer 7 , so that the different height of the liquid column in the legs of the U-tube manometer indicates the dynamic pressure, ie the difference between the total and the static pressure.

The flat rail 1, in contrast to known, working on the principle of Prandtl'schen Pitot tube transducers, the speed or the dynamic pressure of the flowing gas over the entire surface of the flat rail, from which an average of the speed can be determined instead of a selective speed detection .

Because in many applications there is no constant flow rate speed of the gas is present, which at a point Measurement leads to inaccuracies, for example pressure to regulate quantities means the measuring method according to the invention a significant improvement in accuracy to the to determine the dynamic pressure component over an area.

The flat rail preferably consists of a drawn one Metal profile, preferably a drawn aluminum profile, on the one hand, this ensures high dimensional accuracy and another inexpensive manufacture of the transducer allowed.

Fig. 2 shows more details of the flat rail according to FIG. 1 in an enlarged cross section through the flat rail 1st

As the display is shown in FIG. 2, the flat rail 1 is formed symmetrically in both axial directions and has two openings 2, 3 which form depending on Anord 1 voltage of the flat rail, the upstream-side or abström side opening of the flat rail 1. The openings 2 , 3 consist of narrow slots 21 , 31 which extend from the end face of the flat rail 1 into the interior of the flat rail 1 and expand linearly to a cylindrical channel 22 , 32 which is constructed in the manner of a slotted cylinder.

The front opening 23 , 33 of the slots 21 , 31 is rounded, as is the surface of the flat rail in the region of the front sides 6 .

The flat rail 1 shown here has on its upper side 4 and underside 5 notches 41 , 51 which interrupt the flat upper and lower sides 4 , 5 . These Einker exercises 41 , 51 are only used for better assembly of the flat rail 1 , since they form a mark that allow drilling through the flat rail 1 or drilling into the flat rail 1 without the channels 22 , 32 being damaged. Of course, these notches 41 , 51 can also be omitted, so that flat surfaces 4 , 5 of the flat rail 1 are formed, which can optionally also have a raised profile.

Instead of a U-tube manometer 7 according to FIG. 1, a pressure sensor 70 is provided in this exemplary embodiment, which has two connecting parts 75 , 76 , the spacing of which is equal to the spacing of the channels 22 , 32 . This Drucksen sensor 70 is inserted into one end of the flat rail 1 , while the other end of the flat rail 1 is closed.

The pressure sensor 70 converts the differential pressure in the upstream and downstream channels into an electrical measured value, which is optionally displayed or output to a control unit. Such pressure sensors are known per se, so that a detailed description can be dispensed with.

The rail-shaped transducers shown in FIGS . 1 and 2 and described above for determining the pressure, the flow velocity and / or the flow volume of flowing gases can be used in any manner as a transducer. However, a special area of application is the arrangement in gas channels, where the special property, the dynamic pressure component over a surface instead of being recorded at certain points, comes into its own. Fig. 3 shows such an application, which will be explained in more detail below.

In the gas channel 8 , several rail-shaped transducers 11 , 12 , 13 over the cross section 80 of the gas channel 8 are arranged distributed. The rail-shaped transducers 11 , 12 , 13 are connected in this embodiment with pressure sensors 71 , 72 , 73 as shown in FIG. 2, which convert the detected dynamic pressure components into electrical signals and via lines 91 , 92 and 93 to a control - Deliver and display device 10 . This control and display device 10 can be used, for example, to control the amount of gas and regulate the output of a fan as a function of the detected dynamic pressure values or flow rates.

The rail-shaped transducers 11 , 12 , 13 can either be arranged in a plane perpendicular to the longitudinal extent of the gas channel 8 or can be arranged in a row in different heights at different heights of the gas channel 8 . In this way, the pressure conditions at different locations in the gas channel 8 can be detected in a distributed manner and converted into representative measured values that take account of the turbulence that is present in the gas channel 8 .

The measurement described above can be particularly advantageous procedure in air ducts for air volume measurement in air conditioning systems conditions can be used to determine the air performance or to control and regulate. By the distributed arrangement voltage of the rail-shaped sensor is not only a representative mean over the length of the rail determined in the air duct, but also perpendicular to it at un different geometric locations of the air duct.

Claims (10)

1. Transducer for determining the pressure, the flow velocity and / or the flow volume of flowing gases, characterized by at least one rod ( 1 ) arranged essentially perpendicular to the flow direction of the gas with one behind the other in the flow direction of the gas, in the longitudinal direction of the rod ( 1 ) running inflow and outflow openings ( 2 , 3 ). 2. Sensor according to claim 1, characterized in that the inflow and outflow openings ( 2 , 3 ) from transverse to the longitudinal extension of the rod ( 1 ) extending slots ( 21 , 31 ) and in the longitudinal direction of the rod ( 1 ) channels ( 22 , 32 ), which are arranged on the surface of the rod surface ( 4 ) facing away from the end of the slots ( 21 , 31 ). 3. Sensor according to claim 1 or 2, characterized in that the rod ( 1 ) consists of a flat rail with an inflow and outflow side ( 20 , 30 ) rounded in cross section. 4. Sensor according to claim 2, characterized in that the channels ( 22 , 32 ) are designed in the manner of a slotted cylinder. 5. Sensor according to one of the preceding claims, characterized in that the Schlit ze ( 21 , 31 ) from the upstream and downstream sides ( 20 , 30 ) to the channels ( 22 , 32 ) continuously expand. 6. A sensor according to one of the preceding claims, characterized in that the transition of the slots (21, 31) have a radius of curvature (23, 33) for the presence or outflow side (23, 33) of the rod (1). 7. Sensor according to one of the preceding claims, characterized in that between the channels ( 22 , 32 ) of the rod ( 1 ) in the longitudinal direction of the rod ( 1 ) extending recess ( 41 , 51 ) on the top and bottom ( 4 , 5 ) of the rod ( 1 ) is arranged. 8. Sensor according to one of the preceding claims, characterized in that the rod ( 1 ) consists of a drawn metal profile, preferably a drawn aluminum profile. 9. Sensor according to one of the preceding claims, characterized in that one end of the rod ( 1 ) is closed and the other end is connected to a pressure sensor ( 7 ) which converts the detected pressure values into electrical signals, which are sent to a display or control unit ( 10 ) are submitted. 10. Transducer according to one of the preceding claims for gas channels, characterized in that several re rods ( 11 , 12 , 13 ) over the channel cross-section ( 80 ) ver arranged and arranged with a display or Steuerge advises ( 10 ).