SE441371B - DEVICE FOR THE DISTRIBUTION OF BITUMINOST BINDING AGENT - Google Patents

Description

8406598-6 shaped so that it can spread the binder with all or part of its length with even distribution.

Adjustment of kg of binder per m2 of road surface, also called a donor, takes place by keeping the flow through each nozzle at any determined and constant level and the speed of the binder spreader is adjusted so that the desired donor is obtained. The speed of the binder spreader can also be fed back to the drive motor of the asphalt pump so that the preset amount of binder, kg / m2, is spread even if the speed of the binder spreader varies.

The regulation can be done by controlling the motor of the asphalt pump either according to the pressure in or after the flow to the ramp.

The spreading ramp is provided with nozzles distributed at regular intervals over its entire length. The spreading pattern from each of the nozzles can be flat, homogeneously conical, hollow conical, etc. An accuracy of the spreading, which falls within desired margins, is achieved by a combination of design and manufacturing accuracy of the ramp and the individual nozzle and an often multiple overlap of the rays.

The nozzles in the ramp are usually placed at approximately 100 mm intervals. Flat jet nozzles are often used where the jet is angled approx. 30 ° towards the ramp. In order to achieve an optimal spreading accuracy in the transverse direction of the road, a specific overlap is often desired three times. Other types of nozzle configurations also occur.

What is common, however, is that you always want the spread binder for each type of nozzle configuration to hit the road in a specific way, ie in a specific pattern, which leads to specific requirements regarding the height of the ramp above the ground.

Ramp height adjustments on known machines mean that for each nozzle configuration always keep the ramp at a constant height above the ground. However, this means that errors in the spreading accuracy in the transverse direction are obtained due to the following reasons: 8406598-6 W 1 When the viscosity of the binder varies, the spreading angle of the nozzle also varies and thus also the setpoint for the ramp height which gives optimal spreading accuracy in the transverse direction. 2 When the flow through a nozzle varies, the spreading angle of the nozzle also varies, and thus also the setpoint for the ramp height which provides optimal spreading accuracy in the transverse direction.

The present invention aims to obviate these disadvantages by automatically adjusting the optimal ramp height with regard to both the flow through each individual nozzle and the viscosity of the dispersed binder.

The invention will be described in more detail in the following in connection with the accompanying drawings, in which Fig. 1 shows a ramp spreader mounted on a truck and Fig. 2 the scattering image of a flat jet nozzle with the jet angled approximately 30 ° relative to the ramp. Fig. 3 shows the radiation image from a plurality of nozzles with a triple overlap and Fig. 4 how the scattering image with a single overlap this image varies with varying ramp height above ground. The ratio will in principle be the same even with, for example, a triple overlap. Fig. 5 shows the jet from a single nozzle and how the width of the jet at the ground varies with varying viscosity and / or flow and Fig. 6 finally shows a block diagram of sensor and microprocessor for automatic control of ramp height in accordance with the invention.

Fig. 1 shows a ramp spreader 1 with tank 2 mounted on a truck. The ramp 3 belonging to the ramp spreader is provided with a plurality of nozzles 4 through which the bituminous adhesive is spread on, for example, a roadway from the tank via a pipe and hose system included in the ramp spreader.

The nozzles 4 can be of different design and thus give different shape to the binder squeezed out by the same. Usually a flat jet nozzle is used which gives a scattering image of the binder jet when it hits the ground as shown in Fig. 2. In order for the jets from the adjacent nozzles not to hit each other, the nozzles are angled about 300 relative to the ramp. 840659846 In order to achieve optimal spreading accuracy in the transverse direction of the road, a specific overlap is desired, Fig. 3. Fig. 4 shows the scattering image at a simple overlap at different ramp heights above ground, a giving an optimal scattering image, i.e. the scattering images of the individual beams are adjacent. In height position b, complete coverage of the substrate is not obtained and in position c, strips with a double overlap are obtained.

Fig. 5 shows how the width of the scattering image at the ground from the individual nozzle varies with different viscosity of the binder and / or different flow through the nozzle. The width has been indicated in the figure as an angle of spread v <at the outlet of the jet from the nozzle. The angle ø (1 is obtained at high viscosity and / or low flow and 0 (2 at low viscosity and / or high flow).

The block diagram shown in Fig. 6 schematically shows a number of sensors and a microprocessor which together act on a hydraulic system for automatic control of the height of the spreading ramp above ground so that the desired optimal spreading accuracy of the binder spread on the roadway is obtained.

Sensor A is arranged to transmit signals indicating the height of the ramp above ground. It can be of the ultrasound type. The magnitude of the binder flow to the ramp is measured by the sensor B, which may, for example, be of the displacement meter type. Sensor C senses the temperature of the binder, which is a measure of its viscosity.

Fig. 1 shows a ramp of constant length. In many cases, however, it is desired to be able to vary the spreading width, which is done with the aid of telescopically adjustable ramps. Sensor D informs about how many nozzles are in operation.

Sensors A - D send their signals to microprocessor M. The processor is programmed in: The temperature - viscosity relationship for the current binder The relationship between the viscosity of the binder - the spreading angle of the nozzle ° <for the current nozzle type.

The connection flow through the nozzle - the nozzle spreading angle0 (for the actual nozzle type. -, 8406598-6 d In which pattern the binder for the current nozzle configuration must hit the ground for optimal spreading accuracy in the transverse direction.

Based on the signals from sensors A - D, the microprocessor can continuously calculate and adjust the ramp height which gives optimal spreading accuracy 1 transverse and the value which gives the optimal ramp height. Adjustment of the ramp height takes place by means of the hydraulic valves 5, which control the hydraulic cylinders 6 by means of which the spreading ramp 3 can be raised and lowered.

Claims (1)

8406598-6 CLAIM 1 Device for spreading bituminous adhesive, which device comprises a ramp equipped with a plurality of nozzles and can be raised and lowered vertically and a pump and pipe system which connects the ramp to a tank for the bituminous adhesive, characterized of in combination: - a first sensor (A) intended to sense the height of the ramp (3) above ground, - a second sensor (B) which senses the magnitude of the binder flow fed into the ramp (3), - a third sensor (C ) which senses the temperature of the binder - a fourth sensor (D) for sensing the number of operating nozzles on the ramp (3) and '- a microprocessor (M) connected to the sensors which is programmed to be processed from the sensors (A, B,' C ) incoming signals for setting the optimal ramp height above ground. Device according to claim 1, characterized in that the equipment for the height displacement of the ramp (3) is hydraulic and consists of hydraulic valves (5) connected to the microprocessor (M) and connected to a hydraulic system and hydraulic cylinders connected to the ramp (3). (6) for raising or lowering the ramp (3) to the optimum height above ground. Device according to one of Claims 1 to 2, characterized in that the first sensor (A) is arranged to sense the ground level by means of ultrasound. Device according to one of Claims 1 to 3, characterized in that the second sensor (B) consists of a rotating displacement meter. Device according to one of Claims 1 to 4, characterized in that the third sensor (C) is of the thermocouple type. Device according to one of the claims 1. - 5, characterized in that the fourth sensor (D) is connected to each of the nozzle valves included in the ramp (3).