AT403559B - SPREADER - Google Patents

Description

ΑΤ 403 559 Β

The invention relates to a spreader according to the preamble of claim 1.

Such spreaders are for spreading or atomizing spreading material, in particular dry sand or other anti-slip materials directly in front of the wheels of vehicles, such as Rail vehicles or trucks determined.

In previous solutions, behind a sand container to prevent the sand from flowing out unintentionally, a " sand staircase " (in the manner of a siphon for liquids). Compressed air is blown into the sand container for discharge. The container must therefore be made pressure-tight in a complex manner. In addition, sand remaining in the delivery line increases the flow resistance and makes it more difficult to remove additional amounts of sand. Furthermore, there has been no spatial separation between the sand container and the conveying line for the sand so that moisture can also penetrate into the sand container via the conveying line and cause the sand to clump there. Moisture in the delivery line leads to the sand sticking and possibly to the line becoming blocked.

SU 935 356 A describes a device for delivering sand under railway wheels with an injector for delivering a sand-air mixture under a pair of wheels. By activating an electropneumatic valve, compressed air is introduced into a so-called injector connected to a sand container and a sand-air mixture is directed to the wheels. For greater effectiveness and lower sand consumption, the duration of the compressed air pulse corresponds to the duration of a full wheel revolution. This device makes it impossible to meter the sand separately from the conveyance of the sand.

AT 251 431 B describes a sand spreader for motor vehicles with a sand container, the outlet opening of which opens into a compressed air pipe connected to a blower, a shut-off device being provided between the container and the compressed air pipe. This patent is based on the task of preventing the pipeline from becoming blocked by the sand in the simplest possible design. To solve the problem, the closure is designed as a solenoid valve and the switch for the magnet and the blower is a multi-stage switch which first actuates the blower and then the slide for opening the sand container. With this device there is no possibility for exact dosing of the sand. With the valve open, the sand enters the pipe section under the influence of gravity. Therefore, the amount of sand exiting depends on the filling level of the funnel or the sand container above it. Furthermore, the known sand spreader does not have an injector as a discharge device, the sand being conveyed directly by the blower.

DE 31 07 219 A1 relates to a method and a device for increasing the grip of frosted vehicle wheels on smooth roads using a granular anti-slip agent. In order to improve the adhesive effect, the tread of a tire is at least partially provided with an adhesive which binds both the granular anti-slip agent and a firm connection with the tire tread, and at the same time or subsequently the anti-slip agent is applied to the tire tread. A gun-type applicator fitting has an outlet nozzle on one shaft and two connections for one container each, which contain the anti-slip agent or the adhesive. By actuating a handle, the adhesive in spray form first enters a cavity, and after opening a slide, the anti-slip agent also enters the cavity under the action of gravity and then through the outlet nozzle onto the tire tread. This document is a method for preparing the wheels of a motor vehicle by manually applying an anti-slip agent to the wheels before starting the journey and not while driving.

The object of the invention is to provide measures for separating the metering of the sand from the conveyance while avoiding the disadvantages of the known devices, so that no moisture can penetrate into the sand container and into the subsequent delivery line and the sand container no longer has to be made pressure-tight.

This object is achieved by the measures according to the characterizing part of claim 1.

An advantageous design of the injector space to optimize the funding is achieved by the measure according to claim 2.

Another advantage is achieved by the measure according to claim 3. The measures according to claims 4 to 6 have also proven to be advantageous for the optimal conveyance of the spreading material.

The invention is explained in more detail with reference to the drawing, in which an embodiment of the subject of the invention is shown. 1 shows a vertical section of the spreading device, FIG. 2 shows a section of the metering device on a larger scale, FIG. 3 shows a top view of the injector housing, and FIG. 4 shows a section of the same along the line III-III of FIG. 3.

The spreading device according to the invention essentially consists of a storage container (not shown) for the spreading material, a metering device 1 and a discharge device 2. 2 connected thereto

AT 403 559 B

The metering device 1 can be of any design, e.g. according to AT 394 169 B. In the present case, the metering device 1 has a metering chamber 3, the outlet opening 4 of which is closed by a metering piston 5 which is held in the closed position shown under the influence of a spring 6. To open the outlet opening 4, a lifting magnet 7 is provided, through which the metering piston 5 can be retracted against the force of the spring 6.

The discharge device 2, which works according to the injector principle similar to a jet pump, has an injector housing 8 with an injector nozzle 9, which in the present case extends in the longitudinal center of the injector housing 8 and is inserted through a lateral opening 10 thereof. The injector housing 8 has an inlet funnel 11, to which a channel 12 which runs obliquely towards the injector nozzle 9 is connected.

The filling funnel 11 forms with the upper edge of the channel 12 an edge 14 which, as seen in the flow direction of the spreading material, is located in front of the outlet opening 16 of the nozzle 9. The outlet opening 16 of the nozzle 9 is located at a distance A in front of the inlet opening 17 in a funnel-shaped channel 13 or an injector funnel 13. The distance A is equal to the diameter of the inlet opening 17 in the channel 13.

The injector funnel 13 runs coaxially with the injector nozzle 9 in the horizontal direction.

The arrangement of the edge 14 in the flow direction of the material to be spread and the air seen in front of the outlet opening 16 of the nozzle 9, the defined distance A between the outlet opening 16 of the nozzle 9 and the inlet opening 17 into the injector funnel 13, results in a delimited injector chamber 18, the geometric one Training requires the optimization of the discharge of the grit.

The spreading device according to the invention works according to the jet pump principle, according to which the spreading material is sucked into the injector chamber 18 from the storage container (not shown) and by means of the air blown into the injector chamber 18 through the injector funnel 13 and a hose, not shown, connected to the outlet opening 20 of the same, a delivery line or the like. is carried out. The blown-in air thus ensures both the transport of the grit from the storage container for the grit into the injector space 18 and the conveyance of the grit from it via the hose line or the like connected to the injector funnel 13, for example to the wheel, by the suction effect in the injector space 18 of a vehicle.

The air supply to the injector nozzle 9 can take place either radially in the direction of arrow B through the channel 19 or in the axial direction of arrow C.

Advantageously, the cone angle alpha of the inlet funnel 11 can be 120 * and the cone angle beta of the injector funnel 13 can be 15 °, the generatrix of the wall 21 of the inlet funnel 11 facing the axial inlet side of the injector nozzle 9 being parallel to the axis XX of the channel 12 and with the horizontal central axis VY of the nozzle 9 encloses an angle gamma of 30 *. The cone angle alpha results as a compromise between good pouring of the sand and a low overall height of the inlet funnel 11.

The air speed at the nozzle outlet can preferably be approximately 560 m / sec. at the inlet opening 17 of the injector funnel 13 approx. 100 to 120 m / sec. and in the delivery line, not shown, where the final sand speed also occurs, about 18 m / sec. be.

The advantage of the design of the spreader according to the invention is that the air does not press the sand against the wall, but sucks it in its flow. This reduces the wear of the components to a minimum and the device can be built from light, cheap material.

With the aid of the invention, sand with a grain size of 0.5 to 3 mm can be discharged in quantities of 300 to 2000 g / min through conveying lines of up to 8 m long and 14 to 15 mm in diameter with air quantities of 8 to 10 m3 / h. The sand container does not have to be pressure-tight, since the sand is sucked in by suppressing the injector. This suppression acts as far as behind a connecting flange (not shown) of the sand container to the metering device or into the sand container and prevents a so-called " bridge formation " so that the undisturbed sand wake is guaranteed.

The delivery line is preferably flexible and can be designed as a plastic or rubber hose.

All transitions in the injector housing can also be designed with transition radii or rounded - with somewhat more complex production, but more favorable in terms of flow technology.

Finally, a precaution is taken, by means of which the compressed air supply continues for a certain period of time after the sand metering device has been switched off or closed, so that remaining sand is still discharged from the delivery line and the latter is completely emptied.

The bore 10, the channels 12, 13 and 19 and the inlet funnel 11 in the injector housing 8 can be drilled out or milled out. The arrangement 3 is unnecessary due to the construction according to the invention

Claims (6)

AT 403 559 B of its own discharge device, e.g. a brush roller in the area of the wheel. Within the scope of the invention, the angles mentioned can vary up or down by a small amount. Instead of the air, another gaseous medium can also be provided. 1. Scattering device with a storage container, a metering device and a discharge device, characterized in that after the metering device (1) a compressed air-actuated conveying or discharge device (2) is provided for discharging the spreading material, the discharge device (2 ) has an injector housing (8) with an inlet funnel (11) and an adjoining channel (12), the axis of which extends obliquely to the longitudinal axis of an injector nozzle (9) opening into the latter, to which an injector funnel (13 ) connects, an injector chamber (18) being formed between the nozzle (9) and the injector funnel (13). 2. Spreading device according to claim 1, characterized in that between the inlet funnel (11) and the adjoining channel (12) formed edge (14), seen in the conveying direction of the spreading material or in the flow direction of the air, in front of the outlet opening (16) of the injector nozzle (9) is arranged in the injector chamber (18). 3. Scattering device according to claim 2, characterized in that the distance (A) between the outlet opening (16) of the injector nozzle (9) and the outlet opening from the injector chamber (18) or the inlet opening (17) in the injector funnel (13) is the same the diameter of the same. 4. Spreading device according to at least one of claims 1 to 3, characterized in that the funnel angle (alpha) of the feed funnel (11) is approximately 120 *. 5. Spreading device according to at least one of claims 1 to 4, characterized in that the angle of the axis (X-X) of the feed hopper (11) adjoining the channel (12) to the central axis (Y-Y) of the injector nozzle (9) is substantially 30 *. 6. Scattering device according to one of claims 1 to 5, characterized in that the angle of the injector funnel (13) is substantially 15 *. Including 4 sheets of drawings 4