DE1133415B - Snow removal machine - Google Patents

Description

Snow removal machine The invention relates to a snow removal machine with at least one helical at least one arranged transversely to the clearing direction once its rotary shaft, the broaching and conveying screw, its screw surface surrounds the rotating shaft at a distance and is connected to it by a series of webs is.

In the known snow removal machines of this type, the screw surfaces have a flat profile, and the webs connecting the worm surfaces to the rotating shaft lie in the extension of the screw surface and are in the direction of the rotating shaft seen, arranged in alignment. The webs serve exclusively to stiffen the Broaching and conveyor screw. Due to the planar design of the in the direction of the rotating shaft normal arranged auger surface results in inadequate snow clearance, because part of the snow is thrown out of the auger as a result of centrifugal force.

There are also screw surfaces with a profile that is concave in the conveying direction known, which, however, are only connected to the rotating shaft at the ends. Also is the execution of an uninterrupted screw conveyor known in which the Rotary shaft adjacent parts as conveying organs and the outer parts as clearing organs are trained. If the snow conditions are correspondingly unfavorable This can lead to congestion in the shaft area, and the concave screw surface can also be fill in with snow, thereby losing the advantage of the concave shape.

The invention is intended to adhere to the known snow removal machines Defects corrected and an improved, congestion-free evacuation made possible.

This is achieved by the fact that the outer part of the screw surface forming clearing zone opposite the conveying zone closer to the rotating shaft towards the direction the rotating shaft has a smaller angle of inclination in a manner known per se and those connecting the screw surface to the rotating shaft with a cutting edge provided webs to the direction of the rotating shaft differently inclined push-off surfaces form.

The special design of the screw surface results in the Advantage that the speed of the screw can be reduced so that the The inclination of the clearing zone is sufficient to counteract the centrifugal force.

The webs are suitable over the entire length of the screw surfaces Distributed at intervals and have in the area of the snow removal point one opposite the Inclination of the screw surface to the direction of the rotating shaft is less inclined. in the In the area of the snow shedding point, the webs support the snow shedding. the axial conveyance of the snow to the discharge point is improved if after an advantageous applicable, additional feature of the invention of the angle of inclination of the webs to Direction of the rotating shaft away from the snow removal point. Included the angles of inclination of adjacent ones, away from the snow removal point, can be more consecutive Increase the webs to the rotating shaft by the same amount.

With regard to the profile of the screw surface, it is advantageous if the clearing zone occupies at least one fifth of the width of the screw surface.

The invention is particularly useful in practice with such Facilities advantageous in which in the middle behind the in opposite directions The direction of conveyance of screw surfaces comprised at least one rotary shaft transverse to the clearing direction rotating impeller is arranged and the worm surfaces from a rear wall of the housing are tightly enclosed. With such a snow removal machine, after another Characteristics of the invention for the improved throwing of snow into the blower wheel counter-conveying screw surfaces arranged one above the other will. The surfaces of the webs in the area in front of the centrifugal wheel should be at most deviate slightly from the direction of the rotating shaft. Here the clearing capacity essentially due to the formation of pairs of the counter-rotating screw surfaces in the sense of double-thread screws.

In order to achieve a perfect clearing even with higher snow conditions, is further proposed according to the invention, two broaching and screw conveyors, their Rotating shafts are parallel, to be arranged one above the other. This just results from the other features of the invention particular advantages, namely that of the the upper auger moves cleared snow in its conveying zone to the discharge point, while in the case of snails of a well-known type, the snow moves from the upper to the lower Snail falls and overloads it. If in a preferred way the two If the superposed broaching and conveyor screws rotate in the opposite direction, it will also the snow thrown into the blower wheel due to the special arrangement of the worm surfaces and favors the webs which are arranged particularly flat in the end area in front of the centrifugal wheel.

When performing this type, it can also be advantageous if the diameter of the upper screw is smaller than that of the lower screw is. But it is also possible to move the lower screw opposite the upper one in the reaming direction to arrange something in front. This makes the snow removal in the area of the deeper lying, solid snow, as is the case, for example, when clearing airfields necessary is.

Also for types of snow removal machines where the snow removal organs arranged in the middle of the rotating shaft surrounded by counter-rotating screws are, becomes an advantageous by a further embodiment of the invention Improvement created that in the middle of the rotating shaft, between which they encompassing, opposing conveying screw surfaces individual in the direction of rotation of the rotating shaft be arranged hollow and with this rigidly connected throwing blades. In advantageous Execution, the throwing blades are designed as semi-cylindrical surfaces. aside from that the throwing blades can be bulged in the direction of rotation of the rotating shaft. This brings with the advantage that the throwing blades themselves have a snow-lifting effect and the pressure to eject is increased. Due to the training according to the invention the screw surfaces and the arrangement of the webs ensure perfect snow pumping guaranteed and thereby the function of the snow ejection shovels connected to the rotating shaft promoted in a special way. The flat position of the bars in the Snow removal area for the spin process added. This type of execution is suitable especially for small and cheap snow removal machines and z. B. also for exchange the mowing device on grass mowers and the like.

Several exemplary embodiments of the invention are illustrated in the drawing, 1, 9, 12 and 13 show diagrams of possible embodiments.

FIG. 2 is a partial longitudinal section for along the rotating shaft a portion that of the normal to the rotary shaft intersection surfaces A-B and C-D of Fig. 1 is limited. Fig. 3 shows one restricted to the shaft and the webs Side view.

Figs. 4, 5, 6, 7 and 8 are cross sections of in the snow removal direction successive webs with a partial plan view of the shaft. In Fig. 4, 5, 6, 7 and 8, the shaft is continuously offset by 90 ° Position. For the application of a shown diagrammatically in FIGS. 9 and 13, respectively Clearing devices with counter-rotating twin screw surfaces are shown in Figures 10 and 14 Cross-sections perpendicular to the shaft are shown.

Fig. 11 shows a cross-sectional detail obtained along section line G-H.

The clearing and conveying screw of the device according to the invention consists of the rotating shaft 1 and the screw surfaces connected to it in single or multiple numbers. In the embodiment according to FIG. 1, only one screw surface 2 is provided, which surrounds the shaft 1 as a screw surface with a constant profile, the screw surface running uniformly over at least one screw thread and the inner boundary line of the screw surface 2 running at a distance 3 from the shaft 1.

The screw surface 2 is made hollow to the delivery side, like this particularly evident from Fig. 2, but also from Fig.1, preferably the lower one Part of the same, is clearly visible.

The hollow screw surface on the conveying side consists of a clearing zone 4 and a conveying zone 5. The angle of inclination 6 between the clearing zone 4 and the axis of the rotating shaft 1 is smaller than the angle of inclination 7 of the conveying zone 5 with the axis of the rotating shaft 1. The clearing zone 4 can be in the Pass the conveying zone 5 of the screw surface after a more or less pronounced kink line.

The helical surface 2 is connected to the shaft 1 by several webs, which act as push-off surfaces for the snow. It can be seen that the distance 3 between the inner boundary line of the helical surface 2 and the shaft 1 only is slightly interrupted by the webs 8, 9, 10, 11, 12. These bars are in the axial sense obliquely to the shaft 1. This can be seen clearly from FIGS. 4 to 8, which always in plan view of the shaft 1, but from representation to representation with the viewing direction shifted by 90 °, showing the webs in cross-sections. At the Embodiment, the webs 8, 9, 10, 11, 12 surround the shaft 1 according to radial rays, which include angles of 90 ° with each other, but at different angles to the shaft 1 normal levels lie. The projection obtained in FIG. 3 in the direction of the shaft 1 shows the webs 8, 9, 10, 11 and 12 perpendicular to each other protruding from the shaft.

The inclination angle 13 of greater than the angle of inclination 14 of the discharge point of the snow already nearer web 9. Proceeding from the snow removal point farthest web 8, the inclination angles 15, 16, 17 of the against the discharge point of the snow getting closer webs 10, 11 , 12 getting smaller. Accordingly, in the side view of FIG. 3, the surface of the web 8 appears in the greatest width. The width dimensions of the webs 9, 10, 11 and 12 that are visible in the projection are reduced evenly; the projection of the width of the web 12 has the smallest extent. In the exemplary embodiment, the arrangement is such that the differences between adjacent angles 13-14 or 14-15 or 15-16 or 16-17 decrease by the same amount.

The following results from the illustration: When the worm rotates in operation, the helical surface in Fig. 1 moves from the point where the reference number 2 is entered against the viewer forwards and downwards. The bars give 8, 9, 10, 11, 12 the snow through their rotating motion due to their inclination after the angles 13, 14, 15, 16, 17 with respect to the shaft 1 an axial advance to the dropping point. With the progressive decrease in the successive Inclination angles 13, 14, 15, 16, 17 and the enlargements that go hand in hand with them the inclination to the shaft 1 is the axial impulse to convey the snow through each of the successive effective webs 8, 9, 10, 11, 12 larger. The last, in the torn view of Fig. 1 no longer visible web can already in Area of the discharge point for the snow arranged and so strong, so with so be inclined at a slight angle of inclination against the shaft that the axial conveying component the force exerted on the snow by the web surface versus that of the snow a circumferential acceleration in the sense of the throwing off component withdraws.

With ordinary spokes of the usual design, the Invention intended effects can never be achieved.

In practical use, an embodiment in particular comes into play Consider at which in front of a centrifugal wheel, the box 28 of which is indicated in FIG is, two transversely standing auger with opposite function in the sense of Fig. 9 and 12 are arranged in front of a housing rear wall 26 enclosing them.

In the embodiment according to FIG. 9, the counter-rotating screw surfaces are designed in pairs in the sense of double-thread screws. Accordingly, the screw surfaces promote 2 and 21 from the right and the screw surfaces 22 and 23 from the left to the center of the arrangement, So to the place of the centrifugal wheel housed in box 28, which the of it covered snow via a chimney 29 to the side and correspondingly far next to it brings the road to the deposit.

The counter-rotating screw surfaces, for example 2 and 22, can be attached to the shaft 1 offset in the circumferential direction. this goes from Fig. 9 for the screw surfaces 2 and 22 as well as for the screw surfaces 21 and 23. The broaching process is facilitated by the fact that the outer shaft ends have conically formed end disks 18, 19 against the centrifugal wheel, which at the same time for fastening the outer ends of the screw surfaces 2, 21, 22, 23 to serve.

As can be seen from FIG. 10, the housing rear wall 26 is provided with a support body 27 for the support arm 25, which is in a supporting connection with the engine or its box 24. In the embodiment according to FIG. 10, the support arm is not straight, but is designed to be pre-curved from the upper edge of the rear housing wall 26 downwards to the engine box 24 in the clearing direction, in such a way that in the side view there is a curvature, the center of which is far behind the rotating shaft 1, is approximately below the cab of the facility. In cross section, this support arm, as shown in FIG. 11, is advantageously tapered forwards and backwards to form edges 30, 31. This special design of the support arm 25 improves the clearing process not insignificantly, since the edges have a cutting effect and the support arms cannot offer any resistance to the introduction of snow into the area of the blower wheel 28.

Another special feature of the invention, as can be seen from FIG. This significantly improves the amount of snow thrown into the blower wheel. Of course, twin screws, as shown in FIG. 9, can also be used in this case. Due to the particularly flat position the webs 32 in the region in front of the spinning wheel is located, 33 ..., the advantageous effect is further enhanced. In this embodiment, the rotating shaft 1 is mounted laterally, preferably slightly indented from the ends of the rotating shaft 1.

13 and 14 show a further embodiment of a snow-clearing device in which the snow-throwing members are mounted in the center of the rotary shaft 1. The screw surfaces 2, 21, 22 and 23 are connected to throwing vanes 34 fastened in the center of the rotating shaft 1. The snow conveyed to the center in the wave area is thrown into the discharge chute 35 by the throwing blades 34. The throwing vanes 34 are advantageously designed as semicylindrical surfaces which are hollow towards the front and can stand normal to the rotating shaft 1 or, as shown in FIG. 13, have their ends protruding in the direction of rotation of the shaft 1. It is also possible for the throwing blades 34 to be fastened tangentially to the rotating shaft 1 and to be inclined forward in the direction of rotation of the shaft 1. The number of throwing blades 34 advantageously corresponds to the number of screw surfaces. The effect of the throwing vanes 34 is supported by the flat position of the webs 36 in the ejection area.

Claims (16)

CLAIMS: 1. snow removing machine with at least one arranged transversely to the direction of broaching, helically at least once its rotation shaft comprehensive clearing and conveying screw, which screw area surrounding the rotary shaft at a distance and is connected thereto by a number of webs, characterized in that the outer part of the The screw surface (2) forming the clearing zone (4) compared to the conveying zone (5) closer to the rotating shaft (1) to the direction of the rotating shaft (1) in a known manner has a smaller angle of inclination (6) and which the screw surface (2) with the Forming webs (8 ... 10,11,12 ... ) connecting the rotary shaft (1) and provided with a cutting edge to the direction of the rotary shaft (1) differently inclined pressure surfaces. 2. Snow removal machine according to claim 1, characterized in that the screw surface (2) with the The webs connecting the rotary shaft (1) are opposite in the area of the snow removal point the inclination of the screw surface (2) to the direction of the rotating shaft (1) is less inclined exhibit. 3. Snow removal machine according to claim 1 or 2, characterized in that the angle of inclination (17, 16, 15, 14, 13 ... ) of the webs (12, 11, 10, 9, 8 ...) away from the snow removal point always grow. 4. Snow removal machine according to claim 3, characterized in that the angles of inclination of adjacent, from the snow removal point away from successive webs to the rotary shaft (1) by one increase the same value. 5. Snow removal machine according to claim 1, characterized in that that the clearing zone (4) forms at least one fifth of the width of the screw surface (2). 6. Snow removal machine according to claim 1, characterized in that at the ends the rotating shaft (1) with the screw surfaces (2, 21 or 22, 23) connected to the shaft towards conical, full cover disks (18, 19) are arranged. 7. Snow removal machine according to one of claims 1 to 6, wherein the rotating shaft in opposite directions Comprehensive conveying direction, before at least one rotating transversely to the clearing direction Worm surfaces arranged in the centrifugal wheel are closely enclosed by a rear wall of the housing are, characterized in that the from the housing rear wall (26) to the rotating shaft (1) provided between the opposing screw surfaces (2, 21 or 22, 23) Support arm (25) of the engine (24) from the upper edge part to the rotating shaft (1) in Räumrichtung is formed protruding. B. Snow clearing machine according to claim 7, characterized in that the support arm (25) has one front and one rearward in the clearing direction has tapered cross-section to edges (30, 31). 9. Snow removal machine according to one of claims 1 to 6, with two counter-rotating screw surfaces which are arranged in front of at least one centrifugal wheel rotating transversely to the clearing direction and are tightly enclosed by a rear housing wall, characterized in that the laterally mounted rotary shaft (1) encompassing, opposing conveying screw surfaces (2, 2 ') are arranged in the middle of the screw, overlapping one another in front of the centrifugal wheel, and the surfaces of the webs (32, 33 ... ) connecting the screw surfaces (2, 20) to the rotating shaft (1) in the The area in front of the centrifugal wheel deviate at most slightly from the direction of the rotating shaft (1). 10. Snow removal machine after one of claims 1 to 9, characterized in that two clearing and conveyor screws, whose rotating shafts are parallel, are arranged one above the other. 11. Snow removal machine according to claim 10, characterized in that the diameter of the upper screw is smaller than that of the lower screw. 12. Snow removal machine after Claim 10 or 11, characterized in that the lower screw opposite the upper is arranged slightly forward in the clearing direction. 13. Snow removal machine according to one of claims 1 to 6, with two counter-rotating screw surfaces, characterized in that in the middle of the rotating shaft (1), the counter-rotating Screw surfaces (2, 21, 22, 23) with this by individual, in the direction of rotation the rotating shaft (1) are rigidly connected to hollow throwing blades (34). 14. Snow removal machine according to claim 13, characterized in that the throwing blades (34) are semi-cylindrical surfaces are trained. 15. Snow removal machine according to claim 13 or 14, characterized in that that the throwing blades (34) are attached tangentially to the rotating shaft (1). 16. Snow removal machine according to claim 13 or 14, characterized in that the throwing blades (34) in Direction of rotation of the rotary shaft (1) are bulging. Considered publications: Swiss patent specifications No. 224 578, 317 044; U.S. Patent No. 2,610 414