DE3715460C1 - Wind tunnel balance and method for operating it - Google Patents

Abstract

Wind tunnel balance which is used to measure the forces acting in a flow on an object, in particular a vehicle, and to calculate torques (moments), acting on the vehicle, by means of a processor. Provision is made of a device for applying defined forces from 0 to full load to the vehicle in a horizontal direction, in particular the longitudinal direction of the vehicle, and for determining the displacement (SM) of the centre of gravity of the vehicle which results from the respective force. The force/displacement function thereby determined is taken into account when determining torque.

Description

The invention relates to a wind tunnel balance and a method their operation according to the preamble of claim 1 or 10th

Wind tunnel scales are used to measure the aerodynamic influences, i.e. H. Forces and moments related to the three orthogonal to each other Determine axes with high precision; the desired measurement accuracy is on average with an approved error of + 0.25 ‰.

It is known that real vehicles shift due to their elastic wheels and suspension under wind load during the measurement. On the basis of measurements carried out, it was found that at wind speeds in the wind tunnel up to, for example, 200 km / h, the shift in the center of gravity of the vehicle can be 2 cm in the X direction.

If one now considers the influence of errors from the vehicle displacement, a supposed aerodynamic moment about the axis MY of approximately 300 m results, for example, with a vehicle displacement of 2 cm and a vehicle mass of 1500 kg. N with a permissible scale error of 0.2 m. N.

This error occurs with both a 6 component and a 7-component wind tunnel balance, whereby this influence with the 7-component scale is lower, because under wind load that Vehicle rolls on the tire to the rear and this one Roll effect through the parallel guidance of the buoyancy measurement of the Generation of moments from the shift of the center of mass of the Counteracts vehicle.

When evaluating measurement results, this error from the displacement of the model can be corrected by measuring the displacement of the body during the test in the X direction and the Y direction and by correcting these parts in the test evaluation, as in DE-Z ATZ (Automobiltechnische Zeitschrift) 87 (1985) 1, pp. 31-36.

Here, the displacement of the body is Wind flow measured, but not the actual one Displacement of the center of gravity of the vehicle as Suspension, engine, transmission and body of the vehicle uneven during the aerodynamic test shift and a relative shift of the center of gravity in Vehicle to bodywork done. The relocation of the The center of gravity is in the known device alternatively assumed linear in the first approximation. This estimate the actual center of gravity shift can only be rough reproduce generalized and the required measurement accuracy is not adhered to.

The invention has for its object a wind tunnel balance and a method for operating such a wind tunnel balance specify, with the shift in the center of gravity of the investigating object determined with increased accuracy can be.

This object is achieved according to the invention by Wind tunnel scale or a method for operating a Wind tunnel scale with the characteristics of the license plate Claims 1 and 10 respectively.

With the device used in connection with the wind tunnel scale, the relationship between forces acting in the X or Y direction on the vehicle and the displacement of the center of gravity of the vehicle in the X or Y direction can be determined very precisely before the actual measurements with air supply and take into account in the subsequent measurement.

Preferred developments of the wind tunnel balance according to the invention and the method for operating the same are in the rest Subclaims marked.

Further advantages of the invention result from the following description of exemplary embodiments based on the drawing. It shows

Fig. 1 is a schematic diagram of a 7-component wind channel scale in side view and

Fig. 2 is an illustration similar to Fig. 1, but for a 6-component wind tunnel balance.

6- or 7-component wind tunnel scales are known per se. As an example, reference is made to DE-OS 34 42 005. A detailed description of the structure and function of the Wind tunnel scales as such are therefore unnecessary the following description focuses on the invention appropriate characteristics.

Fig. 1 thus shows a schematic representation of a 7-component wind tunnel balance according to the first embodiment, for example with a fixed base 12 on which a horizontally extending base plate 14 is supported, preferably via hydrostatic bearings 26 , which laterally, the hot in X- and Y direction, against one or more load cells 28 for measuring the horizontal forces exerted on a vehicle 22 from.

The vehicle 22 , which can also be an aircraft or another object to be examined in the wind tunnel, stands with its four wheels 24 on a force introduction element 20 , which sits on a force transmission element 18 , preferably with a cylindrical hydrostatic bearing for vertical movement. Each force transmission element is in turn supported by a load cell 16 (measuring or weighing device) on the base plate 14 .

In a known manner, the buoyancy forces in the Z direction, the horizontal forces in the X and Y direction and the various moments, such as tilting moment and rolling moment, can be measured by means of the load cells 16 and 28 , taking into account the track width and the wheel spacings for the formation of moment result when a corresponding flow in the direction of arrow 40 is exerted on the vehicle 22 .

As mentioned at the beginning, the force in the X direction causes a shift in the center of gravity of the vehicle, which is denoted by S _M in the figures. The figures also show a displacement of the body S _K. This shift in the center of mass results in considerable torque errors.

The invention now brings an extremely simple method and a device used by which a heavy weight point shift practically perfect and physically correct can be corrected.

The method according to the invention is characterized in that a defined changing force is applied to the vehicle in the X direction (and Y direction) before the actual measuring process, ie before the air flow is applied, with the result that the vehicle is displaced becomes. This shift causes a change in the lift measurement of the wind tunnel balance by the moment portion of the center of gravity shift. In Fig. 1, the device used in this method is shown in principle. In particular, on the vehicle 22 in the X direction, a rope or wire 32 engages, which is loaded via a force measuring device 34 with different forces, which are shown in the drawing as weights 38, which are attached to a rope which is arranged in a stationary manner Deflection roller 36 is guided and connected to the side of the load cell 34 opposite the vehicle 22 .

When the weights 38 are changed , a different force in the X direction, measured with the load cell 34 , is applied to the vehicle 22 and causes a corresponding displacement path Δ X.

The device 30 for determining the dependence of the center of gravity shift S _M on the applied force is only shown in principle in FIG. 1. A wide variety of embodiments are possible for this. Thus, instead of the weights 38, a stationary mechanical, electromechanical or hydraulic pulling or pushing device can be used, with which the changing force is applied to the vehicle 22 via the load cell 34 .

The function of shifting the center of gravity of the vehicle during the action of the tractive force can either be written down manually or preferably recorded via a data acquisition and processing system, which in turn takes the correction variables into account when processing the measured values. In particular, when the flow in the direction of arrow 40 is applied to the vehicle 22, on the basis of the force in the X direction now measured by the force measuring cell 28, a very specific, determined displacement S _{M of} the center of gravity is assigned to this force and the torque generated thereby is used for correction .

During the tensioning process, it must be ensured that no vertical and lateral components act on the wind tunnel balance, which means that the tensioning wire must always be kept exactly horizontal and in the desired longitudinal direction. Advantageously, therefore, the clamping device 30 with a manual or automatic height and. Provide side compensation if the model not only moves back and to the side during tensioning, but also changes its height and center position.

For this purpose, FIG. 2 shows a basic embodiment applied to a 6-component wind tunnel balance 50 .

In deviation from the embodiment according to FIG. 1, a single force transmission element in the form of a transmission plate 52 is arranged between the force introduction elements 20 and the load cells 16 .

The clamping device 60 of this exemplary embodiment is designed for automatic height adjustment. In particular, 62 elements 64 and 66 are relief for a weight of a bracket and an automatic height compensation provided, the first of which the load cell 34 holds, while the second member 66 holds a hydrostatic flat bearing 68 through which the tension wire 72, for example by means of a feed shaft 70 excited, guided.

With this tensioning device 60 , the shift in the center of gravity of the vehicle can again be determined depending on the force applied to the tensioning wire 32 and measured by means of the load cell 34 and used in the actual wind tunnel, i.e. when flow is applied to the vehicle 22 .

To frictional resistance of the chassis joints or spring elements to take into account during the measurement, it makes sense either the vehicle during cornering or to excite the tensioning device, for example by vibrators, high-frequency vibrations or others Pulsations that are mechanical, hydraulic or electrical can be initiated. This also corresponds to the situation on the road or in the wind tunnel where the vehicle (or a other model) automatically by the wind during the measurement is excited, causing possible stiction or other frictional resistances reduced or even completely avoided will.

It should be noted that devices for automatic Height compensation in connection with wind tunnel scales or Similar devices are generally known, so that these not described in detail here.

Claims (11)

1. Wind tunnel balance, with which the forces acting on the flow of an object, in particular a vehicle, are measured and the moments acting on the vehicle are calculated by means of a processor, a shift in the center of gravity being taken into account when determining the torque, characterized in that a device ( 30; 60 ) for applying defined forces before the measurement process when the wind flows against the vehicle in a horizontal direction, in particular the longitudinal direction of the vehicle, and for determining the center of gravity shift (SM) of the vehicle ( 22 ) resulting from the respective force as a force-displacement function is. 2. Wind tunnel balance according to claim 1, characterized in that the device ( 30; 60 ) has a variable power source ( 38; 70 ) which acts on the vehicle ( 22 ) via a force measuring device ( 34 ). 3. Wind tunnel balance according to claim 2, characterized in that the power source ( 38; 70 ) via the force measuring cell ( 54 ) by a wire ( 32 ) is connected to the vehicle ( 22 ). 4. Wind tunnel balance according to claim 2 or 3, characterized in that support means (springs 64, 66 , bearing 68 ) for the load cell ( 34 ), the rope ( 32 ) and / or the connection ( 72 ) to the power source ( 70 ) are provided , which ensure an exact application of the force in the horizontal longitudinal direction. 5. Wind tunnel balance according to one of claims 1 to 4, characterized in that the power source are calibration weights ( 38 ) which act on the force measuring cell ( 34 ) via a deflection device ( 36 ). 6. Wind tunnel balance according to one of claims 1 to 4, characterized characterized in that the power source is a mechanical,  hydraulic or electrical manual or automatic actuated pull / push device is. 7. Wind tunnel balance according to claim 6, characterized in that the adjusting device is a traction spindle. 8. Wind tunnel balance according to one of the preceding claims, characterized in that the support means ( 64, 66, 68 ) have a frame ( 62 ) on which the load cell ( 34 ) and a holder ( 68 ) for the connection ( 42 ) to the power source ( 70 ) are suspended adjustable in height. 9. Wind tunnel balance according to claim 8, characterized in that the connection ( 72 ) to the power source ( 70 ) in a hydrostatic bearing ( 68 ) which is displaceable in the vertical and lateral directions along the frame ( 62 ). 10. A method for operating a wind tunnel balance, with which the forces acting on an object, in particular a vehicle, under flow are measured and the moments acting on the vehicle are calculated by means of a processor, taking into account a shift in the center of gravity, characterized in that on the vehicle in front of the Measuring process with inflow of wind in the horizontal direction, in particular in the longitudinal direction of the vehicle, defined changeable forces, in particular tensile forces, and the shifts in the center of gravity of the vehicle caused by the respective forces are ascertained and that the force / displacement function thus resulting in the determination of the Vehicle ( 22 ) acting moments is taken into account. 11. The method according to claim 10, characterized in that the vehicle ( 22 ) or the clamping device ( 30 ) is kept in vibration during the displacement measurement.