DE102016009644A1 - Device for changing the aerodynamic resistance of a vehicle - Google Patents

Abstract

The present invention relates to an improved device for changing the aerodynamic resistance of a vehicle, wherein the device comprises at least one air deflector, an adjusting device for adjusting the air guide blade and a control unit, which is connected to the adjusting control means, wherein the air deflector, the adjusting device and the Control unit are attached to the vehicle and is characterized in that the control unit comprises a receiver which is designed adapted for wireless data communication and for receiving data for adjusting the adjusting device.

Description

The present invention relates to a device for changing the aerodynamic resistance of a vehicle, in particular a truck.

A device for changing the aerodynamic resistance is, for example, from the date of the present applicant WO 2014/121937 known. This flow guiding device indicates at the rear of a truck provided Luftleitflügel, with two multi-part spoiler wings are provided in extension of the side surfaces of the truck and a top spoiler in extension of the roof of the truck, which improve the air resistance of the truck in the extended state and thus the driving reduce required fuel consumption. Furthermore, especially in lorries above the driver's cab provided baffles are known, which provide as a roof spoiler a transition between the roof surface of the cab and one of the opposite roof surface of the load part of the truck. In the case of a trailer, this distance may vary, thereby necessitating the adaptation of the roof spoiler so as to provide the most efficient air deflector which reduces air resistance due to the air flowing past the truck during travel.

This is from the DE 10 2012 023 577 A1 a device for adjusting the angle of attack of the roof spoiler described. The angle of attack of the roof spoiler is adjusted via sensors mounted on the vehicle, such as optical sensors, distance sensors and / or flow sensors. According to an alternative proposal according to DE 10 2008 056 357 A1 the angle of attack of the roof spoiler is dependent on the horizontal distance between the rear wall of the cab and the front wall of the trailer and the distance between the rear upper edge of the cab and the upper edge of the front wall of the trailer or the relative height between the roof containing the cab roof and the upper edge the front wall of the trailer or changed depending on the edge angle at the rear upper edge of the vehicle body.

The previously known devices are either difficult to handle or expensive to manufacture and expensive. In particular, on the vehicle entrained sensors are expensive and prone to failure, since they are not sufficiently adapted to the sometimes robust conditions of use of the truck. The same applies to any wiring between sensors and a sensor processing the signals of the sensors, which is connected in terms of control with an adjustment and fixed to the vehicle.

The present invention seeks to provide an improved device for varying the aerodynamic resistance of a vehicle.

For this purpose, the present invention proposes a device with the features of claim 1. The device has, in a manner known per se, various components fastened to the vehicle, namely at least one air deflector, an adjusting device associated with the air deflector for adjusting the air deflector and a control unit which is connected in terms of control with the adjusting unit.

According to the invention, the control unit comprises a receiver adapted for wireless data communication and for receiving data for adjusting the adjusting device.

In the device according to the invention, the input variables required for adjusting the adjusting device are not generated on the vehicle, but externally, d. H. not vehicle-bound. The transmission of the data for adjusting the adjusting device are transmitted wirelessly and received via the receiver, which forwards these data as input variables for the control unit. The received data is processed in order to determine setpoint values for the adjustment of the adjusting device, wherein the setpoint data predetermines, for example, the adjustment path of the adjusting device and thus determines the actuating travel of actuators of the adjusting device.

In this case, the control unit can act on a single air deflector, for example, the spoiler wing of the roof spoiler. But it can also provide all provided on the vehicle spoiler so that the vehicle is operated at reduced by the spoiler air resistance and thus increased efficiency. This operation will be described below as "efficiency mode".

Thus, the device according to the invention offers the possibility of an optimized adaptation of the air deflector while avoiding manual intervention and while avoiding a Einstell-measurement which is mounted on the vehicle, in the aforementioned prior art is associated with each of the roof spoiler. Studies on more than 1,200 trucks in 2016 have led to the finding that about 64% of all roof spoilers of long-distance trucks are not correctly matched to the trailer vehicle. The reason lies in the operational procedure with the forwarding agencies. Because here is neither time nor know-how nor possibility, the spoiler by hand if necessary, readjust several times a day, but this is necessary because the position of the roof spoiler must not only be adapted to the respective trailer vehicle, but also to the payload, the deflection of the trailer, the dome height and the like.

In this case, an incorrectly adjusted roof spoiler deteriorates not only the flow conditions at the transition between the cab and the trailer, but also the performance of a rear-provided air deflector, as well as this is not correctly flowed.

Since the present device automatically makes the adjustment of the air guide wing, eliminating the need for a manual adjustment, so that it can be ensured that the provided on the vehicle air vanes are optimally set in each case in the efficiency mode.

The subject matter of claim 1 can be realized solely on a vehicle which carries the adapted according to the invention control unit.

The subsequent developments sometimes indicate components of the device that are not carried along with the vehicle but are provided at a separate location. The following description is constructive and so individual components of the device according to the invention will be described. However, it follows from the corresponding design specifications also a procedural doctrine, which is also taught with the present invention and to be made under protection and is already reflected in the device claims.

Thus, the control unit is preferably designed for wireless reception of characteristic map control data, the map data being sent by a localized processor. This local processor receives image data of a contour of a vehicle and is accordingly wired or wirelessly connected to a camera, which usually receives a side view of the vehicle and thus is particularly suitable to detect the position and position of the roof spoiler. The thus obtained image data for the current contour of the vehicle are compared in the processor with map data to aerodynamically improved contours. From this, the map control data are generated and transmitted wirelessly to the vehicle. This development offers above all the opportunity to optimize the basic aerodynamic shape of the vehicle before driving, for example, by the roof spoiler is brought to the correct height. As previously mentioned, an adaptation may already be necessary if a truck has partially unloaded it. It has been found that the best measured variable is given by a contour line of the vehicle in the side view in any case when it comes to optimizing the roof spoiler of a truck. With the aid of a stationary, preferably bottom-side camera, the vehicle is displayed before exit, for example, from a cargo area at a breakpoint and scanned the geometry of the vehicle in the roof spoiler. In this case, an optical marker, for example a QR code, or an identifier of the vehicle is preferably detected at the same time in order to provide the processor with aerodynamic characteristics of the vehicle and to enable it to communicate directly with the control unit of the vehicle in wireless communication. From the acquired image data of the scan by means of geometry detection of the components of the vehicle, in the example tractor, trailer and roof spoiler, the relative position of the components recognized each other. By means of the vehicle-related aerodynamic characteristics, a map stored on the processor is selected and an optimum contour is calculated, whereupon a manipulated variable, i. H. the map control data are output. This manipulated variable is transmitted wirelessly from the processor to the vehicle, whereby the spoiler unit sets the spoiler to the desired position to the adjusting device. The corresponding actuator of the adjusting device replaces in this embodiment, a manual adjusting catch, which is at least currently not uncommon in the prior art to adjust the roof spoiler in the desired position.

According to an alternative embodiment, the spoiler device is designed for the wireless reception of wind control data and GPS-related signals. The wind control data is usually obtained from weather information about the corresponding location. The wind control data varies with the magnitude and / or direction of the prevailing wind at the location of the vehicle. Alternatively or additionally, the wind control data can also be such data which, taking into account the location and the driving speed as well as the direction of travel, indicate the wind conditions at a location which the vehicle will still reach on its journey. The control device according to the invention is also designed to receive GPS-related signals. These GPS-related signals can be added to the wind control data, as far as these wind control data indicate the weather conditions, especially the wind conditions at the current location of the vehicle or a future still to be reached location. The wind control data can be forwarded directly to the position of the adjustment or processed in the control unit for calculating control commands for the adjustment. So offers the Training the ability to provide the wing or the wing of the vehicle depending on the location and the prevailing weather conditions. In this case, the position of the air guide wing to increase efficiency in the efficiency mode can be done. Alternatively, a safety mode can be arranged to best stabilize the vehicle in critical wind conditions, which will be discussed later.

According to a preferred embodiment of the present invention, a server is provided, which is usually stationary and particularly preferably designed as a central server for a plurality of vehicles. The server prepares wind conditions data and, based on a GPS signal from the vehicle, determines the wind manipulation data to the vehicle, which is then wirelessly sent to the vehicle and received by the control unit. Due to this wind control data can be done immediately the locations of the airfoils. The wind control data can be used to adapt the roof spoiler and / or a rear spoiler. It should be noted that present rear wing must be flowed substantially frontal to develop their full effectiveness. It has been shown that the flow can deviate from this flow by approximately 1 ° exactly parallel to the vehicle's longitudinal axis, without any fear of loss of performance in the rear wings. This deviation corresponds to a lateral wind of 1.4 km / h with an assumed driving speed of 80 km / h. Statistically, however, prevails near the ground in Europe, a mean wind of 12 km / h. Effectively, the vehicle is then always flown between 0 and 8.5 ° relative to the vehicle's longitudinal axis, most often with an effective average angle of attack of 5.8 °. In such flow conditions, rear wings usually lose 50% of their capacity.

This is where the present invention begins and teaches adjustability of the air deflectors depending on the actual wind data at the location of the vehicle. The wind control data received by the control unit can be used to effect a height adjustment of the roof spoiler. Above all, however, it is expected that the total resistance of the vehicle, in particular a truck-trailer combination can be significantly lowered when the rear wing, d. H. the airfoils provided at the rear end of the vehicle assume an asymmetric position due to the obliquely flowing air with respect to the vehicle's longitudinal axis. This position is realized mainly in the lateral spoiler elements of the rear wing, whose effect is to be enhanced by tracking the roof-side wing elements. By tracking the position of the individual spoiler wings of the rear spoiler, the turbulent flow lag is not only further reduced, but also stabilized behind the vehicle. At the same time a leeward vortex element of a ring vortex is led further from the vehicle rear side and the pressure on the rear surface increases, whereby the air resistance decreases.

In the inventive correction of the position of the air guide wing wind control data are calculated by the server and sent to the control device of the vehicle. This calculation is usually performed clocked, for example, every minute, so that the position of the air guide wing is adjusted continuously optimized based on the given wind information at each location of the vehicle. Due to the determined speed and direction of the vehicle and the wind, the local mean flow state is known. Thus, when determining the position of the vane, not only the wind acting on-site, but also the current speed of the vehicle due to GPS signals is included. This speed can be either in the control unit on the vehicle in the calculation of the manipulated variable to the air deflector received or sent as a GPS signal initially from the vehicle in the direction of the server and used there to determine the wind control data. For this purpose too, the server can refer to a characteristic field stored there, which indicates an optimum position of the respective air-guiding element as a function of the actual flow conditions relative to the moving vehicle. In this case, the server usually sends the resulting resulting wind control data to the vehicle due to an agreed coding, so that each vehicle individually assigned the necessary wind control data and several vehicles can trim their spoiler even with directly adjacent vehicles via the server.

In this case, the server can also receive actual data for setting the air guide wing and, on the basis of the local wind conditions, determine desired positioning data on the vehicle and transmit it to the vehicle. These local wind conditions can either be due to local weather information or due to weather maps.

According to a preferred development of the present invention, the device has a safety mode which can be stored in the control unit or the server and in which, in the event of critical wind conditions, the air deflector is set to stabilize the vehicle. Thereafter, a paradigm change of the control unit can be arranged with the development of the invention, which is usually operated in the efficiency mode to the air resistance of the vehicle and thus to keep its consumption low while driving. In critical wind conditions, when a high side wind or gust threatens to destabilize the vehicle, the baffles are placed to stabilize the vehicle. In this safety mode, the roof spoiler is usually shut down as much as possible. As a result, in the case of a truck between the roof of the cab and the trailer created a stage at which the flow separates and turbulence bales are generated. These mix downstream into the roof vortices responsible for the lateral flow and for the lateral suction and weaken them. The tail air vanes are asymmetrically set as previously described with reference to the efficiency mode. In this case, the leeward-side wing is greatly reduced in angle, ie adjusted closer to the rear wall of the trailer. This causes a similar stabilization of the air flow as in the efficiency mode and reduces side forces. In addition, results from the profile flow around the windward side wing aerodynamic lateral force, which generates a restoring and stabilizing moment about a kingpin, so a node around.

In the safety mode, a control module installed in the vehicle preferably generates control data in real time and transmits them to the adjustment device, either directly or indirectly by delivery to the control unit. This causes a short reaction time in safety mode. In addition, it is ensured that the safety mode is reliably set and adapted even if, for whatever reason, radio contact with the server is lost during critical wind conditions. Preferably, in the control module and during the safety mode, vehicle response data is received and processed to detect critical wind conditions, the vehicle response data indicating the vehicle's response to environmental conditions of the vehicle. Such reactions may be the yaw rate or the lateral acceleration. Also, for example, in the case of a truck to the trailer, a rear camera may be provided which detects the roll angle of the vehicle or its track deviation and passes as an input to the control module.

Further details and advantages of the present invention will become apparent from the following description of three embodiments in conjunction with the schematic drawing. In this show:

1 a schematic representation of an embodiment of a device for changing the aerodynamic resistance of a vehicle using external image data;

2 a schematic representation of an embodiment of a device for changing the aerodynamic resistance of a vehicle using wind data;

3 a schematic representation of an embodiment of a device for changing the aerodynamic resistance of a vehicle in safety mode

The 1 shows a first embodiment of the present invention. In a scan of a QR code on the vehicle and a picture of a camera outside the vehicle input data for the processor of a server are generated and then transmitted to this. The transmission to the processor can be wired or wireless. The processor calculates, based on the input data and a stored map, the positioning data for adjusting an air wing of the vehicle. Via a wireless data connection, the processor transmits this control data to the control unit, which are used by the control unit to give control commands to the adjustment of the air guide wing. In this case, the control unit is connected in terms of control with the adjustment of the air guide wing. The first embodiment is particularly suitable for adjusting the air guide wing before leaving a company premises.

The 2 shows a second embodiment of the present invention. The input data of the processor of a server is the location of the vehicle, which is determined by a GPS module on the vehicle and transmitted wirelessly to the server, and external wind data. Based on the input data and a stored map, the processor calculates the control data for adjusting the air deflector of the vehicle. The further course until the actual adjustment of the air guide wing is then carried out analogously to that described in the first embodiment.

The 3 shows a third embodiment. The embodiment differs from the second embodiment in that the control unit is designed to receive and process vehicle reaction data. Based on the vehicle reaction data critical wind conditions and a threat of destabilization of the vehicle are detected. The control unit, preferably a control module, which may be integrated in the control unit, then performs a paradigm shift. In the case of such a paradigm shift, the control unit is in one Safety mode in which the control commands serve primarily to stabilize the vehicle.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2014/121937 [0002]
• DE 102012023577 A1 [0003]
• DE 102008056357 A1 [0003]

Claims (9)

Device for changing the aerodynamic resistance of a vehicle, in particular a truck, which comprises at least one air deflector, an adjusting device for adjusting the air guide blade and a control unit, which is connected in terms of control with the adjusting device, wherein the air deflector, the adjusting device and the control unit on the vehicle are fastened, characterized in that the control unit comprises a receiver which is designed adapted for wireless data communication and for receiving data for adjusting the adjusting device. Device according to claim 1, characterized in that the control device is designed for the wireless reception of characteristic map control data and that a localized processor is provided which receives image data of a contour of the vehicle and compares with map data aerodynamically improved contours and generates the map control data and sends to the controller. Device according to claim 1 or 2, characterized in that the control device is designed for the wireless reception of wind control data and GPS-related signals. Device according to claim 3, characterized by a server which processes data on weather conditions and, based on a GPS signal of the vehicle, determines wind-control data for the vehicle and sends it to the vehicle. Device according to claim 4, characterized in that the server receives actual data for adjusting the air guide wing and determined based on the local wind conditions on the vehicle setpoint control data and transmitted to the vehicle. Device according to one of the preceding claims characterized by a security mode, which is stored in the control unit or the server and is provided in the case of critical wind conditions, the air deflector for stabilizing the vehicle. Device according to Claim 6, characterized by a control module installed in the vehicle, which in the safety mode generates actuating data in real time and outputs it to the adjusting device. Device according to claim 6 or 7, characterized in that set in the safety mode provided above a truck cab roof spoiler at the lowest level and / or provided asymmetrically at the end of the vehicle, vertically extending and provided in extension of the side surfaces of a trailer wings. Device according to one of claims 6 to 8, characterized in that the control module receives vehicle reaction data indicating the reaction of the vehicle to environmental conditions of the vehicle, and processes to detect critical windstorms.

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