DE2430730A1 - DEVICE FOR MEASURING GAS FLOW - Google Patents

Description

Priority: July 2, 1973, France, 73 24 135

Provision for gas flow measurement

The invention relates to a device for measuring the flow of gas, in particular air, which through the ventilation openings ■ a ventilation system is sucked.

In the known devices of this type, the entire is too measuring air flow passed through a duct in which it reacts against a responding to the flow velocity of the air Feeler works; the sensor emits a signal, the size of which increases with the throughput of the relevant flow. Because of this The signal amplitude can increase as a function of the throughput such devices have good sensitivity only within a limited flow range defined by the Measuring range of the responsive to the air flow velocity Sensor is determined; in addition, these devices generally present a resistance that controls the air flow to be measured changes, which makes a variable correction depending on the measured throughput necessary.

The invention is based on the general object, disadvantages, as they occur in devices according to the state of the art "Eliminate or at least mitigate. A more specific object of the invention can be seen in the abovementioned problems.

to fix parts and in particular a device for gas flow measurement to create that works for larger throughput ranges with good sensitivity and one on the gas flow produces a weak pressure drop that is practically independent of the throughput.

The device according to the invention for measuring the flow of gas, in particular of air, which comprises a sensor responsive to the flow velocity of the gas, is characterized by at least one main bushing, the passage cross-section of which can be controlled by means of a movable closing element, as well as an auxiliary bushing, which is arranged parallel to the main bushing (s) and in which the sensor is arranged, wherein devices are provided, on the one hand, by means of the sensor, a certain throughput through the auxiliary bushing to determine and, on the other hand, to determine the corresponding position of the movable closing member or members in order to obtain the Derive the value of the throughput to be measured.

Thus, the pressure drop in the auxiliary bushing is in time the measurement always the same size. It is just as large in the main bushing or bushings that are parallel to the auxiliary bushing are arranged. As a result, the pressure drop in the device is independent of the throughput.

According to an advantageous embodiment of the invention, the sensor is formed by a flexible plate that is located below the action of the air passing through the auxiliary duct bends, with devices being provided to prevent a certain To determine throughput in the auxiliary feed-through corresponding position of this plate. The movable closing element is formed by a sliding flap provided with a scale, which can be moved in guide rails and an inlet slide for the corresponding main implementation.

According to a first variant of this embodiment, the sensor is formed by an electrical resistance wire, the is heated by electric current and converted into a resistance

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bridge is switched on. The change in electrical resistance this wire due to its cooling by the predetermined throughput through the auxiliary feedthrough causes a Detuning of the bridge, which allows this throughput to be determined.

According to a further variant, the sensor is an impeller formed, which is set in rotation by the air flowing through the auxiliary duct and illuminated by a light source whose amplitude changes periodically, the frequency of the light source being the speed of the impeller at the predetermined Throughput in the auxiliary feed-through. If this throughput exists, the impeller appears to be immobile.

The invention becomes a preferred one in the following description Embodiment explained in more detail with reference to the drawing. Show in the drawing.

1 shows a perspective illustration of an embodiment of the device according to the invention; FIG. 2 shows a schematic representation in a longitudinal section along the line II-II in FIG. 1, the device for measuring the air throughput being installed on a ventilation grille; FIG. Fig. 3 is a scheraatic representation in section longitudinally

the line HI-III of Figure 2; and FIG. 4 shows an end view in the direction of that shown in FIG arrow shown f.

According to the drawing, the device comprises a transverse one cylindrical, transparent housing 2, the entrance surface of which is closed by a wall 9, while that of the wall 9 is opposite Exit surface is open.

In the interior of the housing 2 there is an auxiliary bushing 5 rectangular cross-section, which is delimited by transparent walls 8 and on the wall 9 closing the entry surface in an opening 10 opens. The one hand of the housing 2 and

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on the other hand, space bounded by the walls 8 forms a main duct 7th

The wall 9 has two further openings 11 and 12 with the main implementation 7 are in connection. A movable closing element is arranged in front of each of these openings 11, 12 is each formed by a sliding flap 13; the sliding flaps 13 are guided in rails 14 attached to the wall 9. The opening 11 has a triangular cross-section, while, the opening 12 has a rectangular cross-section. Scales 16 on the wall 9 (Fig. 4) allow a determination of the position of the Sliding flaps 13.

A flow sensor is arranged in the auxiliary feed-through 5. In the illustrated embodiment, this sensor is formed by a thin and elastically deformable plate 6, which is arranged transversely to the inlet opening 10 of the auxiliary feed-through 5 and is attached to the walls 8 with one of its edges. The plate 6 is made of elastic material such as Spring steel.

The auxiliary bushing ends on the side opposite the inlet wall 9 5 and the main bushing 7 in a calming chamber 1 (Figs. 2 and 3).

In Fig. 2 and 3, the device for flow measurement is the "sucked through a ventilation grille 3 of a ventilation system" Air built in. The exit surface of the device is on the wall to which the grid is attached, via an in between joined pipe seal 4 attached.

In order to measure the air flow D sucked through the grille 3, the sliding flaps 13 are actuated in such a way that the openings 11 and 12, starting with the triangular opening 11, are gradually opened .. Under the action of the flow velocity of the air passing through the auxiliary duct 5, the plate 6 bends. When the plate 6 reaches the position shown in FIGS. 2 and 3 Position 6a shown in phantom, in which its free end is a

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Marking attached to the walls of the auxiliary feed-through 5 is opposite, the positions of the sliding flaps 13 determined by means of the scales 16. These scales can be represented by a prior calibration of the device directly in terms of the values to be measured Total throughput must be calibrated.

At the moment the scales 16 are read, the throughput q is through the auxiliary lead-through 5 always the same, since it is a predetermined Bending of the plate ice 6. The pressure drop in the auxiliary feed-through 5 is therefore also always the same. Since auxiliary bushing 5 and main bushing 7 are parallel to each other are arranged, the pressure drop in both feedthroughs is the same. Thus, the pressure drop across the device is regardless of the throughput to be measured D.

Since the plate 6 is also made of the lightest possible material, the pressure drop caused by the device is low and does not noticeably change the throughput to be measured.

The plate 6 is then determined that it has a mean inclination of exactly 45 ° with respect to a certain throughput q occupies its rest position. Therefore, the device can be used on horizontal ceilings or floors just as well as on vertical ones Walls.

In the vicinity of the grid 3, the flow lines are not parallel to each other. Due to the presence of 4 calming chambers 1 is avoided that the currents through the respective auxiliary and Main feedthroughs through this disturbed zone will be affected. The triangular shape of the opening 11 allows enlargement the reading accuracy with small throughputs. Actually corresponds to a relatively small change in cross-section at this opening, a relatively large displacement of the corresponding Flap 13. The measurement of small throughputs is thereby carried out with the opening 12 fully closed. On the other hand, the opening 11 becomes whole for the measurement of large throughputs opened.

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The middle longitudinal plane of the auxiliary bushing 5 preferably falls with the center plane of the housing 2, as shown in FIG the drawing is shown. Such an arrangement reduces the influence of the arrangement of the grid 3 to be monitored with respect to the axis of the device.

It should be noted that the deformable plate 6 by other types of responsive to the flow velocity of the gas Flow sensors can be replaced.

For example, across the auxiliary bushing 5, an electrical Resistance wire can be arranged by electrical Electricity is heated. This wire is going to be used in a circuit Determination of its electrical resistance, for example in a bridge, switched on. The cooling of the wire through the Air flow causes the bridge to be detuned, with a predetermined throughput q also being detuned is equivalent to. The circuit can therefore be set in such a way that the throughput q corresponds to the bridge adjustment.

In another embodiment, the flow rate sensor comprises a measuring vane, which is formed by an impeller set in rotation by the air flow through the auxiliary feed-through. This impeller is illuminated by a light source, the amplitude of which changes periodically. The frequency of that light source is equal to the speed of the impeller, which in turn corresponds to the throughput, so that this throughput by the apparent Motionlessness of the impeller is displayed.

Instead of using a single main leadthrough 7, for example, two parallel openings 11 and 12 can also be used Bushings can be provided.

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Claims (8)

Patent a ns ρ r ü ehe fi.Λ device for flow measurement of gas, in particular of Air, with a responsive to the flow velocity of the gas Sensor identified by at least a main leadthrough (7), the passage cross section of which can be controlled by a movable closing element (13), one parallel auxiliary bushing arranged for the main bushing or bushings (7). (5), in which the sensor (6) is arranged, as well as one Means (15, 16) for determining a predetermined through ■ flow rate through the auxiliary bushing (5) by means of the sensor (6) and to determine the corresponding position of the movable closing members (13) and therefrom for deriving the value of the flow rate to be measured. 2. Apparatus according to claim 1, characterized through a collecting chamber (1), which is an opening through which the entire flow rate to be measured flows and into which the auxiliary bushing (5) and the main bushing or main bushings (7) open. 3. Apparatus according to claim 1 or 2, characterized in that g e k e η η - ζ e = I η e t that the movable closing member or members (13) each comprise a sliding flap (13), each associated with an opening (11, 12) with a fixed passage cross-section . Rails (14) slides. 4 0 9 8 8 5/0 3 8 5 4. Device according to one of claims 1 to 3, characterized in that the sensor is an elastically deformable one Plate (6) comprises and that means (15) is provided for a predetermined flow rate through the Auxiliary lead-through (5) to determine the corresponding position of this plate (6). 5. Apparatus according to claim 3, characterized by a main bushing (7) with a triangular inlet opening (11) for measuring small flow rates. 6. Apparatus according to claim 4, characterized in that that the said predetermined flow rate corresponding Position of the plate (6) corresponds to an average inclination of the plate of exactly 45 ° with respect to its rest position. 7. Device according to one of claims 1 to 3, characterized in that the sensor comprises an electrically heated electrical resistance wire and a device for determining the resistance of the wire. 8. Device according to one of claims 1 to 3, characterized in that the sensor has an impeller and a Includes means for determining its speed. AU 9885/0385