DE1523158C - Compensated anemometer - Google Patents

Description

The invention relates to a compensated anemometer for measuring the airspeed V of an aircraft with respect to the air or the wind with respect to a fixed point, each with a sensor for the static pressure P _s , for the difference Δ Ρ between the total pressure and the static pressure as well as for the absolute temperature T , also a device for determining the size

AP. P,

IO

and a device for the approximate determination of the speed according to the formula of St. Venant according to the sizes mentioned.

Known arrangements of this type have the disadvantage that only very imprecise results are obtained at speeds of KO or at speeds close to zero, so that these arrangements are unsuitable for measuring very low speeds. ^!

Based on this, the invention is based on the object of creating a device which with the Speed starting at zero while maintaining high accuracy up to speeds is fully and reliably operational on the order of about 300 knots.

To solve this problem, the compensated anemometer according to the invention is characterized in that that the parts of the device controlled by the quantity Λ ' the size

■ _ Ax

^y "" 1 + Bx

as a homographic function of χ , where A and B are chosen so that y is the value

1 +

AP

3.Γ.

40

assumes for two arbitrarily chosen values of the quantity χ and that the device for representing V is controlled by the quantities T and y , where V results from V ² = - y · T.

For the measurement of small speeds, A and B are determined by the condition that the two curves have the same tangent to the origin and a common point which corresponds to a given speed, e.g. B. 300 knots.

In a preferred embodiment, the device determining the size a consists in a manner known per se of a rigid arm which can be pivoted in a fixed plane about a fixed point, the angular coefficient of the direction of this arm being precisely with respect to a fixed axis of this plane represents a quantity proportional to χ , while the device representing the quantity y as a hoinographic function of a consists of an organ which is translationally movable in the relevant plane on a straight line perpendicular to the fixed axis and whose displacement is controlled by a second arm, which is rigidly connected to the first and is offset with respect to it by an angle e in such a way that tgß is B , so that the translational displacement of this organ reproduces exactly the quantity j>.

Calculation and experience show that when ε = 4 ° 10 'the relative error for the

V ²
Value of - =, - as determined by the device of the

Invention there is provided, remains in respect to the value from the formula of St. Venant under V1000 ^f fo speeds between 0 and 300 nodes.

The control of the pivotable arm can be effected, for example, by means of two anemometer capsules, of which both outside the static pressure P _s and inside one subject to the vacuum and the other subject to the total pressure, and the connection of the capsules to the arm can be done by a system of pivotable levers and be made of sliders with two degrees of freedom.

In the control circuit of the pivotable arm, an adjustment system consisting of two relative to one another is advantageous movable organs inserted whose distance changes by any, z. B. inductive, capacitive, photoelectric or mechanical effects cause the swivel arm to be adjusted.

Tn the drawing shows an embodiment of the device according to the invention, and although shows

Fig. 1 is a schematic diagram of the essential parts of the invention,

F i g. 2 shows an embodiment diagram of the device for

V ²
the measurement of -ψ- and

F i g. 3 is a schematic of the electronic device for calculating V from F ² .
In the illustrated embodiment

Δ Ρ
the value of the quantity χ = “- represented by

the angular coefficient tgß for the direction taken by an arm 1 which is pivotable in a plane around the point 0 with respect to a fixed direction Oy in this plane, ie through the distance O'B taken by this lever on the solid axis that goes through 0 perpendicular to Oy. A second arm 2 is attached in a rigid connection to the arm 1 in a direction which forms an angle ε with the extension of the arm 1. Under these conditions, when the arm 1 sweeps the distance O'B, the arm 2 sweeps a distance AD proportional to on a fixed axis passing through 0 " perpendicular to Oy

ig (ß-e) + tge =

tgj8 (l + tg ² ε)
1 + tgetg /?

d. H. to the size

ν -

■ _Ax. · ..
1 + Bx

where A - 1 -f- tg ² e and B - tge.

In the case of the FIG. 2, the components of the device are housed in a tight housing 3 in which the static pressure P ₈ prevails. A vacuum capsule 4 actuates a lever 6 via the rod 5, which is pivotable about the axis 7 and carries a pin 8 at its end. The pin 8 can slide in a slot 9 which is formed perpendicular to the axis yj in the movable slide 10. The runner 10 carries a second pin or projection 11 which engages in a link that is attached to the end of an arm 1 of a two-armed lever 1, 2

is provided. The fixed pivot point 0 of this lever lies on the axis y'-y, which is perpendicular to the middle position of the lever 6.

In the interior of the housing 3, a capsule 13 is also attached, which is accessible on the inside to the total pressure P _t and on the outside is exposed to the pressure P ₃ that prevails in the housing 3. The capsule 3 actuates a lever 15 via the rod 14, which is pivotable about the axis 16, about which a second lever 17 can also be rotated. The lever 15 is balanced at one end by the mass 33 and at its other end carries a magnetic core 18 which is movable in a coil 19 of a differential transformer held on the lever 17. The lever 17 also has a pin 20 at its end which engages in an elongated hole 21 in the slide 22. The slide 22 is slidably disposed in the fixed frame of the device perpendicular to the y'-y axis, and the slider 10 can slide in the slide 22 parallel to the y'-y axis.

The arm 2 of the double-armed lever 1, 2 forms an angle ε with the extension of the arm 1 and has a link 23 at its end. A pin 24, which sits on a slide 25, which can be moved translationally to the axis y'-y, engages in the gate 23 . The movement of the slide 25 is controlled via the gear mechanism 26 and the screw 27 by a servomotor 28, which in turn is fed by the differential transformer 19 via the amplifier 29. The screw 27 controls a potentiometer 32 via the gear mechanism 30 and the axis 31.

The device works as follows: The capsule 4 actuates under the action of the static pressure P _s via the lever 6 and the slot 9 the adjustment of the rotor 10 parallel to the axis y' - y and thus changes the ordinate of the pin 11 with respect to the Axis Ox perpendicular to y'-y. The whole thing is regulated in such a way that y = K ₂ - P _s .

The capsule 13 experiences a deformation proportional to Pt-P _s = AP and controls the position of the magnetic core 18 in the coil 19 via the lever 15 28 dines. The motor 28 sets the screw 27 in rotation and thus controls the abscissa of the pin 24. Each adjustment of the pin 24 controls the abscissa of the pin 11 via the link 23 and the lever arms 2 and 1 and the link 12 and thus via the elongated hole 21 The abscissa of the pin 20 and thus ultimately determines the angular position of the pivot lever 17 with the coil 19.

The controlled device remains in equilibrium at standstill when the core 18 and the coil 19 are in such a relative position that the voltage at the terminals of the coil 19 is zero. The regulation takes place in such a way that under these conditions the pin 11 has the abscissa χ = Κ _Λ Δ Ρ with respect to the axis y'-y . The lever 1 then forms an angle β with Oy such that

60

K ₂ ■ Ps Ps

If the angle β is zero, the pin 24 has the position A, and each adjustment K of the slide 22

(72

corresponds to an adjustment K -ψ- of the slide 25 and consequently a rotation of the screw 27

V ²
proportional to - = -.

The potentiometer 32 controlled by the screw 27, which is fed by a voltage - U , supplies a voltage

V ²

V ² The calculation or determination of V from K - = -

can be done by a device as shown in FIG. 3 is reproduced.

A potentiometer 35 driven by an axle 36 is effected by its output voltage via the amplifier 37 the supply of the potentiometer 32, which is shown above in FIG. 2 is mentioned

and its rotation is proportional to - = - .

The output voltage of the potentiometer 32 is via the line 38 to the control amplifier 39, the by the motor 40 for the rotation of the shaft 41, which the two potentiometers 42 and 43 is common.

The voltage output by the potentiometer 43 is used to control the potentiometer via the amplifier 44 42 to dine. The voltage output by the latter is fed to the control amplifier 39.

The device described above is used as follows: the temperature is measured, for example, by a platinum resistance probe of known type which, by virtue of a known control, produces a rotation of the axis 36 proportional to T.

The potentiometer 35 fed by the voltage - U ₀ supplies a voltage -U = -U ₀ T.

The potentiometer then supplies a voltage

V ² T

U _n -T-

V ²

- U ₀ ■ v ² .

The motor 40 causes a rotation χ of the axis 41. When the potentiometer 43 is _{fed by a voltage -f CZ 0} , it supplies a voltage + U ₀ -X, and the potentiometer 42 then supplies a voltage + U ₀ - χ ■ χ = + U ₀ -X ² .

The amplifier 39 thus receives on the one hand a voltage - U ₀ - V ² from the potentiometer 32 via the line 38 and on the other hand a voltage + U ₀ -X ² from the potentiometer 42.

So if U ₀ -V ² = U ₀ · x ² , ie V = χ , the amplifier 39 receives the voltage zero, the readjustment of the potentiometers 42 and 43 is stopped, and these are adjusted by an angle χ = V.

The following modifications in the implementation of the inventive idea are possible:

The system with pivoting double-armed lever can be used by any other system for the calculation replaced by a homographic function. The two runners or slides 10 and 22 can be rigidly connected to each other and have two degrees of freedom compared to the fixed frame. The differential transformer 18, 19 can be through a system of contacts on the levers 15 and 17 can be replaced to the motor 28 in one sense or another depending on which becomes effective

Rotate contacts. The differential transformer can also be powered by a light source system and photodiodes on the lever 15 or 17 are replaced, depending on the illuminated diode, the motor to let go in one sense or another. The system of inductive pick-up can also be carried out by a any capacitive system can be replaced.

Claims (6)

Patent claims: 1. Compensated anemometer for measuring the airspeed V of an aircraft in relation to the air or the wind in relation to a fixed point, each with a sensor for the static pressure P _s , for the difference Δ Ρ between the total pressure and the static pressure as well as for the absolute temperature T , also a device for determining the size Δ P χ = —β— and a device for approximate wise determination of the speed according to the formula of St. Venant from the variables mentioned, characterized in that the parts of the input controlled by the variable χ Ax
direction the size y = as homographic see the function of χ , where A and B are chosen so that y is the value ΔΡ assumes for two arbitrarily chosen values of the quantity x, and that the device for representing V is controlled by the quantities T and y , where V results from V ² = y · T. 2. Anemometer according to claim 1, characterized in that the size χ determining device in a known manner consists of a rigid arm (1) which is pivotable in a fixed plane about a fixed point (0), the angle coefficient of Direction of this arm (1) with respect to a fixed axis of this plane represents exactly a variable proportional to χ , while the device representing the variable y as a homographic function of χ consists of an organ (25) which is located in the relevant plane on a to fixed axis vertical straight line is translationally movable and its displacement is controlled by a second arm (2) which is rigidly connected to the first and is offset with respect to this by an angle ε, such that tg ε = B , so that the translational displacement of this organ (25) reproduces exactly the size y. 3. Anemometer according to claim 2, characterized in that the control of the pivotable Arms (1) is effected by means of two anemometer capsules (4, 13), both of which are static on the outside Pressure Ps and of which one (4) the vacuum and the other (13) the total pressure subject. 4. Anemometer according to claim 3, characterized in that the connection of the capsules (4 or 13) with the arm (1) through a system of pivoting levers (6 or 17) and from Sliders or slides (10 and 22) is made with two degrees of freedom. 5. Anemometer according to claim 2, 3 or 4, characterized in that in the control circuit of the pivotable arm (1) an adjustment system consisting of two mutually movable organs (18, 19) is inserted whose distance changes by any, z. B. inductive, capacitive, photoelectric or mechanical action cause the pivoting arm (1) to be adjusted. 6. Anemometer according to one of claims 1 to 5, characterized in that the determination V ²
the speed from - = - by one with the Control potentiometers (32, 35, 42, 43) and amplifiers (37, 39, 44) are provided electronic device takes place. 1 sheet of drawings