RU123420U1 - ROTARY SNOW LOADER AND WORKING BODY OF THE SNOW LOADER - Google Patents

Abstract

1. A rotary snow loader containing a casing open in front, in which a working body is installed, made in the form of a rotor with a thrower in the central part of the rotor and a feeder with counter-directed working blades inclined in the direction of the thrower, located in several rows on both sides relative to the median vertical plane rotor, while the casing is equipped with an ejection window, characterized in that the first rows of feeder rotor blades, located in the middle part of the rotor, are displaced to the right and left relative to the median vertical plane of the rotor with the formation of a zone free from rotor blades between them, in which the overlapping zone thrower blades, while each thrower blade contains a central part in the form of an arc and two side inclined walls forming an expanding wedge-shaped radial recess, while the angle of inclination of the side walls of the thrower blade relative to the rotor centerline is less than the corresponding angle of inclination of the rotor blades. spruce. 2. Rotary snow loader according to claim 1, characterized in that the angle of inclination of the side walls of the thrower blade relative to the centerline of the rotor is less than the corresponding angle of inclination of the rotor blades of the feeder by 1-15 °. Rotary snow loader according to claim 1, characterized in that the width "a" of the thrower blades 15 is 0.9-1.1 of the width "b" of the middle zone. Rotary snow loader according to claim 1, characterized in that the width of the central zone of the rotor free from the rotor blades is 0.95-0.85 of the diameter D of the ejection window. Rotary snow loader according to claim 1, characterized in that in the lower part of the casing in front of and under the rotor with blades, replaceable

Description

Technical field

The utility model relates to road and municipal engineering, in particular, to devices for removing snow from road surfaces using rotating blade rotors.

State of the art

Known rotary snow loader containing a casing in which the working body of the snow loader is mounted, made in the form of a cylindrical rotor with two counter-directional screws located symmetrically relative to the center of the rotor. In the rear wall of the casing, in the center of the rotor, there is a window for removing snow, behind which a centrifugal wheel of the throwing apparatus of the snow loader is installed. The centrifugal wheel is kinematically connected with the rotor of the working body. Above the centrifugal wheel there is a branch pipe for removing snow into the vehicle or on the side of the road (certificate of the Russian Federation for utility model No. 21606, IPC Е01Н 5/09, 01/27/2002). The indicated snow loader copes well with loose snow, but when removing compacted snow and snow with ice, the performance of the snow loader drops sharply. In addition, the presence of a centrifugal wheel in the throwing apparatus kinematically connected with the working body significantly complicates the design of the snow loader and its maintenance.

Closest to the declared snow loader is a snow blower described in the patent of the Russian Federation for utility model No. 47912, IPC E01H 5/09, 09/10/2005). The mounted rotary snow loader contains a common thrower rotor with radial blades and a feeder with counterclockwise working blades inclined in the direction of the thrower located in several rows on both sides relative to the median vertical plane of the rotor. The specified rotor is mounted in supports in the housing casing with an exhaust window upward above the thrower into the exhaust rotary guide pipe. The blades of the feeder are made in the form of separate blades of shock action, installed mainly uniformly radially and axially in several rows, the planes of these blades of the feeder are inclined to the axial line of the rotor. In the central zone of the rotor, the feeder blades on the right and left sides of the median vertical plane of the rotor are in contact with each other and are connected end to end. The thrower blades are in the form of concave, in the direction of rotation, predominantly semi-tubular scoops mounted on a common rotor, predominantly in the middle of the thrower and predominantly in the middle of the rotor angle between the converging end-to-end blades of the feeder. In a known snow loader, the feeder blades are located in the central zone of the rotor, where the thrower blades are also located. The feeder blades at the central zone have the same angle of inclination relative to the rotor center line as outside this zone.

From the working conditions of the rotor, the main function of the feeder blades is to crush the mass of snow to be removed and move the snow to the central zone. In accordance with this, it is advisable to choose the angle of inclination of the blade of the feeder to ensure effective crushing and movement of snow in the Central zone of the rotor. In the central zone of the rotor, the main function of the blades is to form a flow directed into the exhaust pipe to effectively remove snow. The blades of the feeder cannot generate such a stream of snow with sufficient efficiency, since when they are exposed to the snow, a considerable speed of longitudinal movement is reported to the removed snow, which interferes with the formation of the stream of snow directed by the blades of the thrower into the outlet window. Thus, in the known snow loader there are unproductive power consumption in the formation of a stream of snow directed to the exhaust window.

The objective of the proposed utility model is to offer a snow loader in which there will be less power consumption for the formation of a stream of snow directed to the exhaust window.

To solve this problem, a rotary snow loader is proposed, comprising a front-open casing in which a working body is mounted, made in the form of a rotor with a thrower in the central part of the rotor and with working blades opposite to the direction inclined in the thrower, located in several rows on both sides relative to the middle vertical the rotor plane, while the casing is equipped with an exhaust window located above the thrower, over which there is a curved pipe for removing snow, while in the snow load The first rows of rotor blades located in the central part of the rotor are displaced to the right and left relative to the median vertical plane of the rotor with the formation between them of a zone free of working blades, the width of which is less than the transverse dimension of the exhaust window, in which the thrower blades overlap this zone, each thrower blade contains a central part in the form of an arc and two side inclined walls forming an expanding wedge-shaped radial recess, while the angle of inclination of the side walls of the blade thrower relative to the axial line of the rotor is less than the corresponding angle of inclination of the blades.

Moreover, the angle of inclination of the side walls of the thrower blade relative to the rotor center line is less than the corresponding angle of inclination of the working blades of the feeder by 1-15 °.

In addition, the width "a" of the thrower blades is 0.9-1.1 of the width "b" of the middle zone.

In this case, the width of the rotor-free central zone of the rotor is 0.95-0.85 of the diameter D of the exhaust window.

In addition, a removable carbide knife of the blade of the harvested material is fixed in front of and under the rotor with blades.

To solve this problem, we also propose a working body of a rotary snow loader, containing a rotor with a thrower in the central part of the rotor and with counter-directional working blades, inclined in the direction of the thrower, located in several rows from two sides relative to the median vertical plane of the rotor, in which, according to the utility model, the first rows rotor blades located in the central part of the rotor are displaced to the right and left relative to the median vertical plane of the rotor with the formation between n the area of the thrower blade that is free of working blades, in which each thrower blade is located, each thrower blade contains a central part in the form of an arc and two side inclined walls forming an expanding wedge-shaped radial recess, while the angle of inclination of the side walls of the thrower blade relative to the center line the rotor is less than the corresponding angle of inclination of the blades.

The angle of inclination of the side walls of the thrower blades relative to the rotor center line is less than the corresponding angle of inclination of the working blades by 1-15 °.

In the proposed snow loader, the functions of the feeder blades and the thrower blades are divided and the feeder blades do not participate in the formation of the snow flow directed to the exhaust window.

Accordingly, the angle of inclination of the working blades of the feeder is selected from the condition of capturing the snow and moving it to the middle zone, where it is picked up by the thrower blades and thrown out through the exhaust window into the nozzle and then into the swivel outlet pipe for loading into the vehicle or for moving snow to the side of the road or on the lawn. To increase the efficiency of snow emission, it is necessary that, in contrast to the working blades of the feeder, most of the energy transferred to the snow by the thrower blades is expended to give it tangential (circumferential) speed, which is ensured by the installation of the thrower blades at a smaller angle to the rotor axis.

The technical result achieved is to increase the efficiency of snow removal by directly clearing the road from snow and when clearing the road from snow formed in the shaft by snow removal equipment.

A brief description of the drawings.

The utility model is illustrated by drawings.

Figure 1 shows a General view of the rotary snow loader in isometry (with the removed near side wall of the rotor casing)

Figure 2 shows the cross section of the snow loader in the median plane.

Figure 3 shows the working body of the snow loader.

Utility Model Disclosure

The hinged rotary snow loader comprises a hinged casing 1, having a casing 2 open on the front side of the casing, in which a working body 3 is mounted, made in the form of a rotor 4 with a thrower in the central part of the rotor and a feeder 5 with counterclockwise working blades 7 inclined in the direction of the thrower, located in several rows on two sides relative to the median vertical plane of the rotor. The specified rotor 4 is installed in the supports in the casing 2 of the housing and is connected to the engine of the snow loader using the appropriate kinematic transmission.

The casing 2 includes a lower wall 8 with an interchangeable carbide knife 9 attached to it dumping material: snow, pieces of ice, etc., a cylindrical rear wall 10 with an exhaust window 11 made therein and side walls 12. To the exhaust window 11 a pipe 13 with a diameter D is connected. Above the pipe 13 there is a rotary sectional outlet pipe 14 with a rotary mechanism.

The working blades 7 of the feeder are located on two sides relative to the median vertical plane of the rotor 4. The blades 7 of the feeder are made in the form of separate blades of shock action, installed mainly uniformly radially and axially in several rows. When viewed from the front, the rotor rotates from top to bottom, the planes of these blades 7 of the feeder are inclined to the axial line of the rotor 4 at an angle a, and in the left part of the feeder the inclination of the working blades 7 to the center line of the rotor 4 is counterclockwise, and to the right of the thrower feeder inclination of the working blades 7 of the feeder to the rotor center line in the opposite direction. In this example of implementation, the working blades 7 of the feeder are arranged on each side in three horizontal rows and four vertical rows, but there may be a different number of rows of working blades 7 .. The first rows of working blades 7 of the feeder located in the middle part of the rotor are shifted to the right and to the left relative to the median vertical plane of the rotor with the formation between them of a zone of width "b" free of working blades 7. In this zone, thrower blades 15 overlapping this zone are placed, with each thrower blade containing a central part 16 in the form of an arc and two side inclined walls 17, forming, as shown in FIG. 3, an expanding wedge-shaped radial recess, while the angle β of the side the walls of the blade 16 of the thrower relative to the axial line of the rotor 4 is less than the corresponding angle α of inclination of the working blades 7 of the feeder by 1-15 °.

The width "a" of the working blades 15 of the thrower (the distance between the left and right lateral edges of the blade 15 of the feeder) is 0.9-1.1 of the width "b" of the middle zone, providing when the rotor 4 rotates, completely or partially overlap the free middle zone of the rotor 4 In this case, the angle of inclination of the side walls of the thrower blade relative to the rotor center line is 1-15 ° less than the corresponding angle of inclination of the working blades.

The diameter D of the pipe 13 is equal to the diameter D of the exhaust window 11 and is consistent with the width "b" of the middle zone, free from the working blades 7 of the feeder. Preferably, the diameter D is slightly greater than the width "b" of the middle zone. For example, the width "b" of the middle zone may be 0.95-0.85 of the diameter D.

The housing 1 is equipped with nodes 18 for mounting a snow loader on a standard front-end loader.

Snow loader operation

The range of harvested material by the proposed snow loader - from freshly fallen dry or wet snow to dense icy snow shafts with crushing of the harvested snow mainly by the working blades of the 7 feeder - a clean selection of the lower layers of snow and run-off, no preliminary loosening-crushing of the grader with a knife and shifting of the grader with the grader with a knife from road barriers, from passenger transport stops, from houses to hard road surfaces. A dense snow stream is formed from the snow removed by the feeder blades moved to the thrower into the thrower by the thrower blades, which is freely diverted through the exhaust window into the nozzle and further outside the cleaning zone.

The condition of a sufficiently high rotor speed ensures efficient crushing of icy pieces of snow by the working blades of the impact feeder (with impact crushing of ice and compacted snow) and the ejection of crushed snow through an exhaust window, which helps reduce the energy consumption of the main operation, crushing and removing snow and auxiliary operations.

The snow loader allows you to remove snow in any road conditions.

The snow loader can be manufactured at engineering enterprises, including factories for the production of road equipment.

Claims (7)

1. A rotary snow loader comprising a front-open casing in which a working body is mounted, made in the form of a rotor with a thrower in the central part of the rotor and a feeder with counter-directional working blades, inclined in the direction of the thrower, located in several rows on both sides relative to the median vertical plane the rotor, while the casing is equipped with an exhaust window, characterized in that the first rows of rotor blades of the feeder, located in the middle part of the rotor, are shifted to the right and left relative to the median the vertical plane of the rotor with the formation between them of a zone free of working blades of the thrower, the thrower blades overlapping this zone, each thrower blade contains a central part in the form of an arc and two side inclined walls, forming an expanding wedge-shaped radial recess, while the angle of inclination of the side the walls of the thrower blades relative to the rotor center line are less than the corresponding angle of inclination of the blades of the feeder. 2. The rotary snow loader according to claim 1, characterized in that the angle of inclination of the side walls of the thrower blade relative to the axial line of the rotor is less than the corresponding angle of inclination of the working blades of the feeder by 1-15 °. 3. The rotary snow loader according to claim 1, characterized in that the width "a" of the working blades 15 of the thrower is 0.9-1.1 from the width "b" of the middle zone. 4. The rotary snow loader according to claim 1, characterized in that the width of the rotor-free central zone of the rotor is 0.95-0.85 of the diameter D of the exhaust window. 5. The rotary snow loader according to claim 1, characterized in that in the lower part of the casing in front of and under the rotor with blades, a replaceable hard-alloy blade blade of the material to be removed is fixed. 6. The working body of the rotary snow loader, comprising a rotor with a thrower in the central part of the rotor and with counter-directional working blades inclined in the direction of the thrower, located in several rows on two sides relative to the median vertical plane of the rotor, characterized in that the first rows of the feeder blades, located in the middle part of the rotor, are displaced to the right and left relative to the median vertical plane of the rotor with the formation between them of a zone free of working blades, in which Covering this area of the thrower blade, each thrower blade contains a central part in the form of an arc and two side inclined walls forming an expanding wedge-shaped radial recess, while the angle of inclination of the side walls of the thrower blade relative to the axial line of the rotor is less than the corresponding angle of inclination of the working blades. 7. The working body according to claim 6, characterized in that the angle of inclination of the side walls of the thrower blade relative to the rotor center line is less than the corresponding angle of inclination of the working blades by 1-15 °.