DE4242215C1 - Road surface condition measuring system - uses gas and gas/liquid jets operated sequentially during measuring cycle of electrical, optical or radiometric sensor - Google Patents

Abstract

The road surface measuring system uses a gas/liquid mixture directed onto the road surface for at least 0.001 secs. via one or more pairs of jets (3) before a gas is supplied to the measuring side of at least one sensor (1) enclosed by a screening (2), via at least one further jet (4) for a similar duration. The sensor provides electrical, optical, or radiometric measurement of defined substances, e.g. road salt. At least one further gas jet (5) and gas/fluid mixture jet (6) are then used to provide a turbulent gas and/or gas/liquid stream within the screening before the full measuring cycle is repeated. USE - For determining road salt concn. to control salt dispersing device.

Description

The invention relates to the field of mechanical engineering and the mechanics and relates to a method and an apparatus for Measurement of road conditions with contactless recording of Substances such as B. in determining the on the road the amount of salt present.

Various methods and devices are in the art known to take measurements on liquid, dust or atomize Perform substances.

Generally this can be done e.g. B. optically or electrically carry out.

Methods and devices are known for all measuring methods.

According to DE 40 29 615 A1 is a device for detecting Road condition data is known by means of sensors in which a Block that contains the necessary sensors, so in the driving is embedded that the upper surface of the block in the level with the surface of the road. This is the block exposed to atmospheric precipitation. To this The degree of coverage of the roadway can be covered by moisture speed or ice, the water level or the thickness of the ice, the temperature  and / or measure the presence or concentration of salt.

The block is designed so that it consists of two concentric Hollow cylinders exist, the upper one being put over the lower one and that between the walls of the hollow cylinder one or more O-rings are provided for sealing.

DE 38 24 840 A1 describes a method and an apparatus for Determination of the concentration of a taumite dissolved in water tel described.

Then the de-icing agent dissolved in water is removed using a device with at least one wheel rolling on a road as Solution added. One against the tread of the wheel Measuring wheel of a measuring device takes over with it as the measuring surface serving surface that previously by repellant to a Pressed moisture solution in a moisture layer. In electrodes A of the measuring device are arranged at a distance A. in sliding contact with the measuring surface. With the help of a a computing unit applied to the electrodes low-frequency AC voltage becomes the electrical conductivity of the moisture layer between the electrodes. With a temperature measuring medium is the temperature of the moisture layer on the measuring surface che measured and the arithmetic unit as a value for temperature compensation sation of the average de-icing concentration calculated from the conductance fed. The method and the device are for control a salt spreader.  

Another solution is known from DE 38 29 008 A1.

Then a procedure for measuring the de-icing salt content of water layers on traffic areas and with a device for performing this method a high frequency radiation, the frequency of which is between 100 and 10,000 MHz lies on the one covered with the water layer to be examined Area of the traffic area in question, and it will the intensity of the water layer to be examined ref radiation component and / or the phase shift of the radiation reflected from the water layer to be examined portion of the incident with respect to the water layer Radiation measured. The measured values obtained form individually or together a measure of the salinity of the water layer. The device has a first directional antenna which is provided by a High-frequency generator is fed and the radiation portion of which Traffic area at an acute angle with respect to the plumb line right hits, and a second directional antenna that also at an acute angle with respect to the perpendicular to the Traffic area meets. The second directional antenna is with a Phase meter connected. Both directional antennas are above the Traffic area, preferably arranged laterally.

DE 31 20 362 A1 also describes a method and a device for measuring the quantity of soluble substances such as de-icing salts on a Road surface described.

The device consists of a sampling belt according to DE 30 19 341 A1, the absorbent inner layer with the cover to the Edges of the calibrated, the suction of the roads to be tested  liquid serving window is glued and around this window around with starch paste fixed on the surface e.g. B. Silver contains chromate points of different concentrations, each decolorized by a chloride solution according to the concentration ratio or not to be decolorized and thus the barking of the chloride allow content of the aspirated solution. The application of the Sampling tape serves the equipment that the street surface with solvent in a path-dependent amount in one side limited track and the resulting solution a brush roller from the road surface to the Sampling belt, which rolls off a storage drum, transfers.

Furthermore, a method is known from US Pat. No. 4,615,225 which a liquid conductive material is analyzed by by means of an electrical spark, a small amount of the liquid is evaporated against conductive material and with the help of a Carrier gas is brought via lines to an analyzer.

There is also a device according to DE-GM 19 95 735 known which is the substance to be examined in a closed Space is there, is whirled up and over pipes is brought to the place where the investigation takes place.

The disadvantage of the known methods and devices is in that either direct contact with the surface  on which the substances are located, on which measurements should be made, or that only the amount of water dissolved de-icing agent can be determined, or that the sampling takes place in a closed room.

The invention is based, a method and a task To provide a device for measuring road conditions, through the without direct contact with the Surface on which the substances to be measured are located an electrical, optical or radiometric measurement to the Substances can be taken, taking measurements on other solutions than can be done on de-icing water solutions and where the Sampling is not restricted to an enclosed space.

The task is by a method having the features of claim 1 and solved by a device with the features of claim 3.

Advantageous further developments are in the Subclaims marked.  

The operation of the device and the The procedure is as follows:

A gas or a gas-liquid is passed through at least two nozzles blown mixture on the surface on which the measuring substances. This causes these substances whirled up and part of it settles on the measuring side of the or the sensors. The liability on the measuring side of the sensor is achieved by adhesion.

Through this first cycle step, a larger amount of salt is released the measurement side of the sensor or sensors deposited as the or Need sensors for measurement. To this unneeded part  to remove the fluid medium and always have the same size To ensure ßes measuring volume, a gas is then over the Blown measuring side of the sensor or sensors.

The electrical, optical or radiometric measurement is now carried out on the substances on the measuring side of the sensor. The The type of measurement depends on the type of substance to be measured and the type of sensor used.

After that, a gas stream is passed over the inside of the shield blown to clean the inside of the shield.

A gas-liquid mixture is then passed over the measuring side blown of the sensor or sensors. This rinses the measuring side and freed from the fluid medium on it.

As a last step, a gas flow is over the measuring side of the or the sensors are blown to dry the measuring side.

This cycle can be repeated as often as required be performed.

The use of the is particularly advantageous Method and the device against one surface moved relative to the device.

The invention is illustrated below using an exemplary embodiment explained in more detail with the help of the drawing. This shows in a schematic Representation of a device for measuring the concentration of up de-icing salts on a road surface.

The device contains a sensor 1 for measuring the electrical conductivity of salt solutions. This sensor 1 is surrounded by a 5 cm high shield 2 . At the lower end in the shield, four nozzles 3 are arranged opposite one another. The nozzles 3 are arranged at an angle of 45 ° with respect to the Mittelach se of the device. Above the four nozzles 3 , a further nozzle 4 is arranged at an angle of 120 ° with respect to the central axis of the device and on the measuring side of the sensor 1 .

Also above the four nozzles 3 , four further nozzles 5 are arranged at an angle of 90 ° with respect to the central axis of the device.

Furthermore, above the four nozzles 3 , a further nozzle 6 , at an angle of 135 ° with respect to the central axis of the device and directed towards the measuring side of the sensor 1 , is arranged. Separate feed lines 7 lead to the perforated disk 9 to the nozzles 3 to 6 . A container 8 for water and air is installed in the feed lines 7 above the perforated disk 9 . The rotatably mounted perforated disk 9 opens and closes the feed lines 7 to the nozzles 3 to 6 . In the perforated disc 9 holes and cutouts are attached, which control the water and air flow to the nozzles 3 to 6 . This is done as follows:

As a first cycle step, a water-air mixture with a pressure of 0.5 MPa is blown onto the road surface within 0.01 s. The water-air mixture is created by simultaneously emptying the water and air containers 8 through the nozzles 3 through a hole in the perforated disk 9 . The perforated disk 9 continues to rotate and thus closes the feed line 7 to the nozzles 3 . During this time, the salt swirled up in water is deposited on the measuring side of sensor 1 . Since more is deposited than is required for the measurement, the supply line 7 for air is now opened through a hole in the perforated disk 9 to the nozzle 4 and the air with a pressure of 0.5 MPa within 0.01 s on the measuring side of the sensor 1 blown. The excess fluid medium is thereby removed from the sensor 1 . The perforated disk 9 continues to rotate and closes the feed line 7 to the nozzle 4 .

Now the electrical conductivity of the saline solution is measured. Since the electrical conductivity over a wide concentrate range is almost proportional to the salt concentration Via a calibration curve, statements about the salt concentration immediately feasible on the road.

Then the space below the sensor 1 and the inside of the shield ( 2 ) is cleaned of possibly adhering dirt by the perforated disc 9 by means of a hole, the supply lines 7 for air to the nozzles 5 and thus blown air onto the inner walls of the shield 2 becomes.

Thereafter, the measuring side of the sensor 1 is rinsed and cleaned by the perforated disk 9 releasing the feed lines 7 from the containers 8 for water and air to the nozzles 6 by means of a hole and thus a water-air mixture via the measuring side of the sensor 1 with a Pressure of 0.5 MPa is blown within 0.05 s. The measuring side of sensor 1 is rinsed and cleaned by this water-air mixture.

For the next measuring cycle, the measuring side of sensor 1 has to be dried. This is done by rotating the perforated disk 9 and releasing the supply line 7 for air to the nozzle 6 . The air is blown onto the measuring side of sensor 1 with a pressure of 0.05 MPa within 0.05 s.

This measuring cycle is repeated every 2 s.

The result of measuring the electrical conductivity of the Saline solution can be used directly to control the Spreader can be used.

Claims (7)

1. A method of measuring road conditions under touch-less uptake of substances, in which via feed lines (7) for gas and liquid first, a gas-liquid mixture through minde least two pairs of opposite nozzles arranged (3) at least 0.001 s is blown onto the road surface on of the substances to be measured, that a gas is then blown for at least 0.001 s via one or two further nozzles ( 4 ) onto the measuring side of one or more sensors ( 1 ), which are surrounded by a shield ( 2 ), that subsequently an electrical, optical or radiometric measurement at the Substan zen who siege to abgela on the measuring side of the sensor or sensors (1), is carried out by means of the sensor or sensors (1), that thereafter a gas via at least two nozzles (5 ) at least 0.001 s is blown onto the inside of the shield ( 2 ), that then via one or two further nozzles ( 6 ) first a gas-liquid mixture and then a gas is blown for at least 0.001 s on the measuring side of the sensor or sensors ( 1 ), turbulent, directed and / or impulsive gas and / or liquid flows being used and the entire measuring cycle being carried out one or more times in succession is performed. 2. The method according to claim 1, in which the feed lines ( 7 ) are guided via containers ( 8 ) for gas and liquids, wherein in each case the amount of gas and / or liquid is stored in the containers ( 8 ) which is required for a method step in one cycle is needed. 3. Device for measuring road conditions with contactless absorption of substances consisting of at least one sensor ( 1 ), which is surrounded by a shield ( 2 ), and a device for receiving the substances through a fluid medium, which has a central axis, wherein in addition to the sensor or sensors ( 1 ) there are at least two pairs of oppositely arranged nozzles ( 3 ), the nozzle openings being arranged at an angle of 30 to 60 ° to the central axis of the device, directed towards the road surface, with further one to two nozzles ( 4 ) are arranged at an angle of 95 to 135 ° to the central axis of the device, on the measuring side of the sensor or sensors ( 1 ), with at least two further nozzles ( 5 ) at an angle of 80 to 120 ° are arranged to the central axis of the device, with another one to two nozzles ( 6 ) at an angle of 120 to 150 ° to the central axis of the device, on the measuring side of the sensor or sensors ( 1 ) are arranged, the gas and / or liquid pressure at which the gas and / or the liquid emerge from the nozzles ( 3 to 6 ) being between 0.05 and 5 MPa and the throughputs through the nozzles ( 3 to 6 ) per measuring cycle for the liquid 1 to 10 cm ³ and for the gas 1 to 20 l, and being arranged in or on the on-line devices ( 7 ) for the gas and the liquid are. 4. The device according to claim 3, wherein the height of the shield ( 2 ) corresponds to at least the width of a sensor ( 1 ). 5. The device according to claim 3, wherein the feed lines ( 7 ) are guided via containers ( 8 ) for gas and liquid. 6. The device according to claim 3, wherein the gas and / or rivers liquid pressure is 0.5 MPa. 7. The device according to claim 3, in which a perforated disc ( 9 ) is provided for controlling the nozzles in the measuring cycle.