The present invention relates to an arrangement for measuring flow velocities and volume flows in a flow channel with the help of a Pitot tube.
Pitot tubes, also known as dynamic pressure gauges, are widely used sensors in flow meter technology for determining flow velocities. A special form of a Pitot tube is the Prandtl tube, for example, which is used for speed measurement in aviation. However, dynamic pressure gauges are used in ventilation technology in measuring flow velocities, volume flows, or mass flows in ventilation ducts because they are characterized by the possibility of simple assembly and by a low pressure drop in the installed state.
A known design of such dynamic pressure gauges is illustrated in
Symbol ρ here denotes the density of the flowing medium. The relationship above follows directly from the Bernoulli equation.
Flow velocity vS is normally not constant over the cross section of the flow channel. An average dynamic pressure pS and from this an average flow velocity vS in flow channel 10 are ascertained because probe tube 10 has multiple openings 11 along its longitudinal axis. Such a measurement of the average flow velocity is too inaccurate, however, and the particular flow profile must be included in the measurement result. In the past, this problem has been solved by adjusting and calibrating Pitot tubes individually for each possible channel cross section. This is only a minor problem with permanently installed Pitot tubes, but for mobile measurements using portable operational control meters, a probe tube adapted to each possible channel cross section would be necessary, which is not practical for mobile applications. An enormous number of different probes, namely one for each possible channel cross section, would be necessary.
The object of the present invention is therefore to provide a measuring arrangement for determining the flow velocity in a flow channel which is suitable for performing sufficiently accurate measurements of flow velocity in tubes of any diameter.
This object is achieved by a measuring arrangement as recited in claim 1. Various embodiments and refinements and a method for use of the measuring arrangement are the subject matter of the dependent claims.
Unlike the related art, in the present invention the problem of the influence of the flow profile over the cross section of the flow channel on the measurement result for the average flow velocity is solved not by adapting and calibrating a Pitot tube specifically for a certain channel cross section but instead by improving upon the Pitot tube to the extent that a measurement of the flow profile is possible and thus the measurement result for the flow profile may also influence the calculation of the average flow velocity.
The measuring arrangement according to the present invention for determining flow velocities in a flow channel includes, in addition to the flow channel, a probe tube having multiple openings situated along a line parallel to a longitudinal axis of the probe tube and a differential pressure sensor. The probe tube is inserted through a first opening into the interior of the flow channel in such a way that the openings in the probe tube are facing the flow in the flow channel. All the openings facing the flow lead into the interior of the probe tube, where a total pressure (static pressure+dynamic pressure) prevails as a function of the oncoming flow velocity.
The differential pressure sensor has a first connection, which is connected to the interior of the probe tube. A second connection of the differential pressure sensor is connected to the flow channel via an opening in such a way that the static pressure in the interior of the flow channel is applied to that second connection. Therefore, this opening must not be exposed to the oncoming flow in the channel and must be situated with its cross section parallel to the flow lines. The differential pressure measured by the differential pressure sensor corresponds exactly to the dynamic pressure in the interior of the probe.
The probe tube is also at least partially surrounded by a displaceable and/or length-variable shield that is designed to close or cover one or more openings or none at all, depending on the position and/or length of the shield along the probe tube.
After insertion of the probe into the flow channel, it is possible to measure not only an average dynamic pressure value but also an entire measurement series with as many individual pressure measurements as there are openings in the probe tube. Each measurement of the measurement series is performed with a different number of openings exposed to oncoming flow. The openings that should not be exposed to oncoming flow must be covered by the shield. The probe may be inserted only partially into the flow channel during a measurement. The shield is positioned in such a way that the openings that are not in the flow channel are covered by the shield and the openings that are in the channel are exposed to oncoming flow. In this case, the shield is thus only outside of the channel. However, the probe may also be inserted completely into the channel. In this case, the shield must of course be positioned at least partially in the channel to cover a different number of openings there, depending on the length and position of the shield.
In the first differential pressure measurement of the measurement series, only a first opening in the probe tube is not closed and may be freely exposed to oncoming flow. Prior to the second differential pressure measurement, a second opening in the probe tube (for example, an opening directly adjacent to the first opening that is already open) is exposed, so that in the second measurement, two openings (for example, adjacent openings) are exposed to oncoming flow and the average dynamic pressure in the interior of the probe tube changes accordingly. Prior to each additional measurement, another opening in the probe tube, which was previously closed by the shield, is exposed (for example, the opening directly adjacent to the opening that was exposed immediately previously). This procedure is continued until all the openings in the probe tube are uncovered and are freely exposed to oncoming flow. This procedure may of course be performed equally well in the opposite order, i.e., all the openings in the probe tube are exposed to oncoming flow in the first measurement and one opening after the other is successively covered by the shield in subsequent measurements until only one opening is freely exposed to oncoming flow and contributes to the average pressure in the probe tube. The order in which the openings are covered or exposed is not relevant for the result. However, for practical reasons, the openings are usually covered or exposed in a given order.
The change in the average dynamic pressure in the interior of the probe tube during the successive opening or closing of the openings in the probe tube provides information about the flow profile over the cross section of the flow channel. The shape of the flow profile is ascertainable from the measured series of dynamic pressure values.
An important aspect of the present invention is the design of the shield. This may be designed as a bellows or as a telescoping tube of variable length that is pulled over the probe tube and covers one or more neighboring openings in the probe tube or covers none at all, depending on its position and/or length, so that they are no longer exposed to oncoming flow. Another option is to use a second tube that is also pulled over the probe tube and which has openings that overlap with the openings in the probe tube, depending on the position of the shield, and these openings may be exposed or closed, depending on the position. In this case, a rail which is situated on the side of the probe tube facing the flow may also be used instead of a tube.
To be usable as a universal parameter probe, moisture and temperature sensors may also be provided on the probe tube in the measuring arrangement according to the present invention.
The present invention is explained in greater detail below on the basis of the exemplary embodiments illustrated in the figures.
a shows a Pitot tube according to the present invention having a telescoping tube as a shield;
a shows a diagram with a measurement series of the dynamic pressures recorded according to the method according to the present invention as a function of the openings freely exposed to oncoming flow in the probe tube;
b shows a diagram with the values that were calculated from the measurement series in
The same reference numbers in the figures denote the same parts.
a and 2b show a part of the measuring arrangement according to the present invention, namely a probe tube 10 having openings 11 positioned along a line parallel to the axis of symmetry on the side facing the flow and having a telescoping tube 12a which is pulled over the probe tube and which is suitable for covering one or more of the successive openings or none at all, depending on the set position and length. Probe tube 11 may be inserted into the channel to different distances, depending on how the length of telescoping tube 12a has been set.
a and 3b correspond essentially to
a shows as an example (not drawn to scale) the sequence of a measurement series such as that ascertained in the measurement operation according to the present invention. Using a probe tube that is initially covered completely by the shield, one opening after the other in the probe tube is exposed step by step by manual displacement of the shield or the probe tube (by which the shield is again displaced and/or compressed or elongated) and the dynamic pressure is ascertained as the pressure difference between the total pressure in the interior of the probe tube and the static pressure after exposing the particular opening. In the case of a probe tube having n openings 11, n individual measured values pn are thus obtained in one measurement operation.
The shape of the flow profile is easily determined from this measurement series. A series of single-point dynamic pressure values Δpn proportional to the flow profile is obtained by subtracting the product from the dynamic pressure measured instantaneously and the number of openings not covered by the instantaneous measurement from the product of the dynamic pressure measured previously and the number of uncovered openings thereby. Thus if n openings are exposed to oncoming flow in the nth measurement of the measurement series, then the single-point dynamic pressure is
Δpn=pn·n−pn−1·(n−1) for i>1. (2)
In the first measurement with only one opening exposed to oncoming flow in the probe tube, single-point dynamic pressure Δp1 is naturally equal to average dynamic pressure p1.
Δp1=p1 (3)
The values being sought for local flow velocity vn, corresponding to single-point dynamic pressure values Δpn, are then obtained according to the following equation by analogy with equation (1):
The local resolution for the flow profile corresponds exactly to the distance between the openings.
An average flow velocity in the flow channel or the volume flow or flow rate is easily calculated from the shape of a flow profile ascertained in this way.
Number | Date | Country | Kind |
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20 2006 011 065.8 | Jul 2006 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/005082 | 6/8/2007 | WO | 00 | 9/21/2009 |