DE975946C - Throwing wheel for snow blowers - Google Patents

Description

Throwing wheel for snow throwers The invention relates to a throwing wheel for Snow blowers, in which the carrier of the throwing blades is designed as a body of revolution is that against the throwing direction of the snow already loosened by other means is rejuvenated.

Throwing wheels for snow blowers are already known in which the carrier of the throwing blades is designed as a body of revolution. So is z. B. a Throwing wheel known, in which the essential part of the support by a torus surface is limited and in which the throwing blades from the circumference of the wheel to immediately reach to the top of the carrier. In the middle area of the throwing wheel are therefore the Throwing blades relatively close together, so that the surfaces of these throwing blades together with the surface of the rotational body, slow down the snow that has been thrown in and because of the slender tip of the wearer, it only moves relatively slowly deflect the perimeter areas of the throwing wheel. In addition, the snow hits this one known execution in a fairly wide edge area of the throwing wheel under one steep angle on the torus surface, which is formed there almost as a ring surface is. In this peripheral area, the snow is slowed down and picked up by the throwing shovels and accelerated in the tangential direction. Because of this sudden change of direction and braking that is imposed on the snow that has been thrown in becomes the power requirement for the drive increased. With this well-known throwing wheel, the snow is inclined from thrown in below. It is also already a version of a throwing wheel known, in which the throwing blades are strongly cut out in the middle part, so that they the very small cone in this embodiment in the Touch near the base of the throwing wheel. Also with this known throwing wheel due to the accumulation of the blades in the middle part a great resistance for the Thrown snow formed, which from this central area only slowly entered the Peripheral areas can be discharged because of the centrifugal forces that cause the discharge effect of the snow towards the circumference, are low in the middle part. Even with this one known embodiment, the thrown snow is strongly braked and one subject to sudden change of direction.

In contrast, according to the invention, the carrier is the throwing vanes designed as a cone, the tip of which extends into the plane of the foremost edges of the Throwing shovels are sufficient, with the tip of the cone pointing in the direction in which the snow is thrown in. The cone is shaped so that its base diameter is not much smaller than the diameter of the throwing wheel. The conical surface starts from the base surface into a torus surface that leads to near the edge of the throwing wheel, the torus surface merges into a circular ring surface immediately at the edge of the throwing wheel. The shovels of the throwing wheel are so arcuately cut out inwards that they reach the conical carrier about halfway up. It is not essential that the cone is formed by a straight generating line, but the generating line can also deviate slightly from the straight line in its shape, so that instead of a Exact cone is a cone-like body.

The formation of the throwing wheel according to the invention is achieved that the snow thrown into the middle part of the throwing wheel through the conical surface to the outside, whereby it only appears at such a distance from the axis hits the blades, in which the centrifugal force is already noticeable. aside from that the snow, which is thrown in approximately in the axial direction, at all points which it hits the cone, deflected at the same angle. All of this works on the drive and the efficiency of the throwing wheel and increases the Snow blower performance.

According to a preferred embodiment of the invention, the throwing blades are designed as surfaces of a hollow cylinder, the rearmost generatrix in with respect to the direction of rotation of the throwing wheel parallel to the throwing wheel radius assigned to them lie, but lead against this by an eccentricity in the direction of rotation.

Instead of hollow cylindrical throwing blades, blades in Form of helical surfaces can be used, or the throwing vanes can be the surfaces of truncated cones correspond.

According to an advantageous embodiment of the invention is the dead Space behind the throwing vanes in the direction of rotation by means of additional sheets covered so that there are neither air eddies nor accumulations of snow behind these throwing blades can form.

Embodiments of the invention are described below with reference to the drawing For example, described in Figs. i and 2 in plan view with throwing wheels show three and six cylindrical blades, respectively; Figures 3 and 5 are cross sections through the throwing blades according to FIGS. 1 and 2; 4 shows the throwing wheel after these two Embodiments in a central section through the throwing wheel axis, and FIGS. 6 and 7 leave the shape of the throwing blades according to FIGS. I and 2 on the developed circumference recognize the stationary cylindrical drum housing; Fig. 8 shows in plan view a throwing wheel with six helical blades; Fig. 9 is a central section through the throwing wheel according to FIG. 8 along the throwing wheel axis; Fig. Io shows the shape of the Throwing wheel blades according to FIG. 8 on the developed circumference of the stationary cylindrical Drum housing.

In all embodiments, the main component of the throwing wheel is formed by the throwing wheel cone i, which serves as a carrier for the throwing wheel blades, with the radius R. - The tip S of the throwing wheel cone i, which rotates clockwise or in the opposite direction around axis AA ', is the direction s des Thrown in, already loosened snow facing. The tip S is advantageously removable, whereby the attachment of different throwing wheels on the same throwing wheel axis AA 'is facilitated. At point B the conical surface i merges into a torus surface 2 with a radius r1 and this then again into a circular ring surface 3. This throwing wheel cone i, 2, 3 causes the snow thrown into the throwing wheel to be deflected towards the outer circumference of the throwing wheel.

On the throwing wheel cone i, 2, 3 there are three or more throwing blades 4. fastened in such a way that its upper one, rounded after an arc with the radius r3 Part only touches the conical surface of the throwing wheel cone below the tip S at n and then with this, the segment of the toroidal surface 2 and the base of the throwing wheel cone forming annular surface 3 is connected. The cylinder surface circumscribed by the throwing wheel cone with the generating o-2t at the same time limits the throwing wheel blades 4 to the outside. These have the task of the throwing wheel cone 1,: 2, 3 against the periphery of the cone to catch deflected snow, to accelerate it to the peripheral speed of the throwing wheel and in a substantially radial direction out of the cylindrical drum housing 7, in which the throwing wheel is mounted, through an opening left free in its circumference 8 to be thrown out.

For this purpose, the throwing wheels can have blades of various shapes. In the embodiments according to FIGS. 1 to 7, the blades have the shape of cutouts from hollow cylinders. The generatrices of the hollow cylinder with the radius r. Curved throwing blades are parallel to the throwing wheel radius R assigned to them, but are shifted relative to this by the eccentricity E in the direction of rotation D. The axes C of the hollow cylinders lie halfway up the throwing wheel carrier i. The throwing blades thus touch the carrier halfway up. The individual leaves q. The throwing blades are, as already mentioned above, firmly connected to the throwing wheel cone i, 2, 3 in their part adjoining the throwing wheel cone i, while their rounded part facing the throwing side and the part touching the imaginary cylinder circumference of the throwing wheel are free. It is therefore the limits of the circumference of the throwing wheel blades q. freestanding from o via r3 to n and from o to u , while the part from u via r1 to u is firmly connected to the throwing wheel cone i.

To prevent the formation of air vortices or undesirable accumulations of snow on the back of the rotor blades q. 6 and 7 can be arranged opposite to the throwing wheel blades curved cylindrical cover surfaces 6, through which the dead spaces 5 are covered. Instead of these oppositely curved cylindrical cover surfaces, cover surfaces of other suitable shapes can also be selected. In the plan view (Fig. I and 2) the upper end o and the lower end u of each throwing wheel blade coincide, while the throwing blade center m remains in the direction of rotation of the throwing wheel and passes the axis AA 'at a distance of eccentricity E. From the development of the cylinder circumscribed by the throwing wheel cone (FIGS. 6 and 7) the direction of rotation D of the throwing wheel, the direction of the loose snow thrown into the throwing wheel, the shape of the throwing blades q. from o through m to u, the radius of which is y. as well as the cover surfaces 6 to be connected and the dead spaces 5 covered by them can be seen. The continuous curvature of the throwing wheel blades q is obtained from the cuts made perpendicular to the generatrix of the hollow cylinder (FIGS. 3 and 5). from its upper end o over the middle m to the lower end u with the radius r2 and the direction of rotation D of the throwing wheel can be seen.

In the embodiment according to FIGS. 8 to 10, the blades are formed from guide surfaces and from throwing parts adjoining them, the guide surfaces being designed as helical surfaces, the generatrices of which are essentially parallel to the base of the body carrying the blades, and the throwing parts are the Have the shape of hollow semi-cylinders. The latter could, however, also be designed in the form of truncated hemispheres. In these embodiments, the generatrices of the guide surfaces pass through the axis AA 'of the throwing wheel, the outer radius of which is again R, and are essentially parallel to the base surface uu of the throwing wheel cone i. Here, too, the individual blades of the throwing wheel blades 4 are firmly connected to the throwing wheel cone 1,2,3 in their part adjoining the throwing wheel cone, while their rounded part facing the throw-in side and the part touching the imaginary cylinder circumference are free. Here, too, as in the embodiments of FIGS. 1 to 7, there are free-standing parts of the blades and parts connected to the throwing wheel cone. Here, however, the radius y3, according to which the upper parts of the blades are cut out, changes with the number of throwing blades per throwing wheel.

From the developed cylinder circumference of the throwing wheel (Fig. Io) it can be seen that each throwing wheel vane has a guide surface beginning at o in the form of a helical surface has, the generatrix of which goes through the axis A-A 'of the throwing wheel and is parallel to the base surface u-u of the throwing wheel cone lies, and that on this guide surface a cylindrically curved throwing part adjoins. The surface parts facing the throw-in side i of the throwing wheel blades are for every two successive blades q. identical, they only separate at point a at the connection of the one curved with the radius r2 Throwing part. The dead spaces 5 at the back of the throwing part are already through the guide surface of the next following throwing vanes is covered. In the top view (Fig. 8) the beginning o of each throwing shovel coincides with the one at the base of the cone Point u of the previous throwing shovel, during the one in the direction of movement on furthest remaining part m of the cylindrical throwing part through the screw surface the next throwing shovel q. is covered. The development in Fig. 10 leaves again as in FIGS. 6 and 7, the direction of rotation D of the throwing wheel, the direction of the thrown Snow see the shape of the throwing blades with the guide surfaces and the throwing parts as well recognize the covered dead spaces 5. These dead spaces are getting smaller the greater the number of throwing blades q. is.

In principle, other forms of throwing vanes can also be used think that meet the desired requirements. For example, As already mentioned above, the throwing parts have the shape of half truncated cones; even The guide surfaces could consist of helical surfaces with the axis of the throwing wheel cone inclined generatrices be formed. The basic form of the remains essential the body carrying the blades as a cone or cone-like body and the design this body and the throwing blades in such a way that no sudden changes of direction of the thrown snow enter, as well as the shape cut out inwards the throwing vanes, through which, in connection with the conical carrier, a blockage of the throwing wheel in the middle part is avoided.

Claims (4)

PATENT CLAIMS: i. Throwing wheel for snow blowers, in which the carrier the throwing shovels as opposed to the throwing direction of the by other means already dissolved snow is formed rejuvenating bodies of revolution, characterized in that that the carrier (i) of the throwing blades (4) than with his up in the plane of the foremost Edges of the throwing shovels protruding tips against the throwing direction of the snow pointing cone or cone-like body is formed, the base diameter of which is only slightly less than the wheel diameter of the throwing wheel and that at its base in one extending essentially to the edge of the rotating body Torus surface passes over, and that the blades are cut out to the inside and reach the carrier only about halfway up. 2. Throwing wheel according to claim i, in which Cuttings from hollow cylinders serve as throwing parts of the blades, their generators lie parallel to the base of the support for the throwing blades, characterized in that that the generatrix furthest behind in relation to the direction of rotation is the hollow cylinder parallel to the throwing wheel radius (R) assigned to them, but against it advance by an eccentricity (B ') in the direction of rotation (D) (FIGS. i to 7). 3. Throwing wheel according to claim 2, characterized in that the axes (C) of the hollow cylinder are approximately half the height of the carrier (i). 4 .. Throwing wheel according to claim: 2 or 3, characterized in that the dead spaces (5) of the blades (4) are covered. 5. Throwing wheel according to claim 4, characterized in that the cover surfaces (6) are formed by cylindrical surfaces of opposite curvature which adjoin the blades (4) directly. 6. Throwing wheel according to claim i, characterized in that the blades consist of guide surfaces designed as helical surfaces, the generatrix of which are substantially parallel to the base of the carrier (i) of the blades, and of these adjoining throwing parts in the form of half-cylinders or half truncated cones (Fig. 9 and io). 7. Throwing wheel according to claim 6, characterized in that two successive blades overlap each other in such a way that their parts (i) lying next to the entry plane are common. Considered publications: Swiss Patent Specifications No. 22o 693, 278500; USA. Patent Nos. 1,528,969, 2,132,790, 2,047,659 work report of Snow Research Center de. General Inspector for German Roads, “Measurement experiments on snow clearing machines in the winter of 1941/42a, Bd. B 3, Supplements 3, 4 and 6, and Bd. B i, Figs. 6 and 7, from the summer of 1941; Progress reports from road construction and civil engineering, Verlag Straßenbau, Chemie und Technik, Heidelberg, "Measurement tests on snow clearing machines for country roads" by Dr.-Ing. Carl Cr oz e; Vol. 4, p. 15; "Description of the device, operating and maintenance instructions for the hollow thrower HS, on the crawler tractor East", edition 1943, pictures 3 and 12; Spare parts list booklet 23 E for hollow extractor HS.> P. 4. Older Patents Considered: German Patent Nos. 800 304, 881 356.