RU47912U1 - MOUNTED ROTARY SNOW CLEANER - Google Patents

Abstract

The utility model relates to road and municipal engineering, in particular, to devices for removing snow from road surfaces using rotating blade rotors. The tasks to be solved are simplification of the design, increasing the reliability and trouble-free operation, reducing the weight of the installation and energy saving. The technical result is achieved in that the feeder blades are made in the form of separate impact blades, mounted mainly uniformly radially and axially in several rows. When viewed from the front, the rotor rotates from top to bottom, the planes of these feeder blades are inclined to the axial line of the rotor, and in the left part of the feeder from the thrower, the blades are tilted from the rotor center line counterclockwise in the quadrant, and the blades are tilted from the axial to the right of the feeder part rotor lines within a quadrant clockwise. Mostly in the middle of the thrower, the convergence is butt of the upper edges of the left and right parts of the row of the feeder blades nearest to the thrower. The thrower blades have 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. The transmission of rotation from the drive motor to the common rotor of the feeder and thrower is carried out with the possibility of slipping during overloads, for example, using a belt drive, and with the possibility of automatically connecting the transmission to the drive motor at a speed of rotation of the specified motor is not less than the nominal threshold value.

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

From the patent literature the working body for the snowplow is known (USSR Author's Certificate No. 20146, IPC E 01 H 5/09, publ. 09/08/1967, Bull. No. 18), including a single horizontal rotor shaft, on which are located a screw feeder with a right and left augers with coils directed towards each other and out of phase, between which there is a thrower in the form of blades on the rotor, each of which is rigidly attached to the screw of the right or left screw by one side, while the rotor blades are made with restrictive plates, fixed nnym an angle to the free sides of the blades. The disadvantage of this working body is the complexity of its design, its manufacture and high energy consumption of operation.

Also known is a rotary snow blower (Utility Model Certificate No. 0005599, IPC E 01 H 5/09, publ. December 16, 1997), which is taken as a prototype for the proposed utility model. The snow blower contains a milling feeder with two screws with spirals converging to the axis of symmetry of the carrier vehicle, and a throwing device with an exhaust pipe rotatable in the horizontal plane, the throwing mechanism is made of two throwing blades mounted motionlessly on the shaft of the screw of the milling feeder radially and at an angle of 180 degrees relative to each other, while the rotation of the shaft of the screw of the milling feeder and at the same time throwing blades provides a common drive device. The disadvantage of this device is also the complexity of the design and high energy consumption of operation.

Utility Model Disclosure

The tasks to be solved in the proposed device are the simplification of the design, increasing the reliability and trouble-free operation, reducing the weight of the installation and energy saving.

The technical result is achieved by the fact that the mounted rotary snow blower contains a common thrower rotor with radial blades and a feeder with blades inclined towards the thrower. The specified rotor is mounted in supports in the housing casing with an exhaust window upward above the thrower into an exhaust rotary guide pipe. There is also a drive unit with kinematic transmission of rotation to the rotor and mounting the housing to the transport medium.

It is noteworthy that the feeder blades are made in the form of separate impact blades, mounted mainly uniformly radially and axially in several rows. When viewed from the front, the rotor rotates from top to bottom, the planes of these feeder blades are inclined to the axial line of the rotor, and in the left part of the feeder from the thrower, the blades are tilted from the rotor center line counterclockwise in the quadrant, and the blades are tilted from the axial to the right of the feeder part rotor lines within a quadrant clockwise. Mostly in the middle of the thrower, the convergence is butt of the upper edges of the left and right parts of the row of the feeder blades closest to the thrower. The thrower blades have 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. The transmission of rotation from the drive motor to the common rotor of the feeder and thrower is carried out with the possibility of slipping during overloads, for example, using a belt drive, and with the possibility of automatically connecting the transmission to the drive motor at a speed of rotation of the specified motor is not less than the nominal threshold value.

More specifically and additionally: the feeder blades have a flat working surface towards the thrower and stiffeners on the rear side. Number of rows

feeder blades equal to three, the angular distance between the rows is mainly 120 °, the angle of inclination of the planes of the blades is mainly 55 ° to the center line of the rotor. When sweeping a rotor with blades onto a plane, inclined blades in adjacent rows are located along common straight lines, that is, as spiral strips divided into separate sections with gaps between them.

The height of the thrower scoop is predominantly equal to the height of the feeder blades, the volume of the thrower scoop corresponds to the capacity of the feeder, the throughput of the exhaust window and the exhaust pipe, in particular, the width of the thrower scoop is equal to the width of the exhaust window and the exhaust pipe.

The exhaust pipe is made box-shaped with a regulator of the discharge range at the end, the side projection of the pipe has an inclined curved shape of a predominantly logarithmic spiral, instead of the bottom wall in the pipe there are tightening rails to reduce the weight and material consumption of the pipe.

A diesel engine is used as a drive engine. The nominal speed of rotation of the drive motor when connecting the rotor through a kinematic transmission is 1800 ... 2200 rpm. As rotor bearings, high-speed radial rolling bearings are used.

Also, in the lower part of the casing of the case, in front of and under the rotor with blades, a carbide knife of the blade of the material to be removed is fixed with the possibility of shifting as it wears.

The body mounts are adjustable for its canopy, for example, instead of a bucket on a standard front loader.

The device used appropriate control, sensor and signal equipment.

A brief description of the drawings.

Figure 1 is a schematic view of the device in isometric view (with the proximal side wall of the rotor casing removed)

Figure 2 is a cross section of the middle of the rotor thrower with blades.

In the figures, the numbers indicate the following elements of the device:

1 - a single rotor of the feeder and thrower, 2 - blades of shock action of the feeder; 3 - throwing scoops; 4 - the casing of the rotor as the front of the device; 5 - an exhaust window above a thrower with an exhaust box-shaped nozzle with an outlet range regulator at the end; 6 - belt drive to the rotor from the rotation drive; 7 - a drive motor with a belt drive automatic transmission (clutch); 8 - fastening elements of the housing of the device to the transport medium; 9 - carbide knife below the base of the casing under and in front of the rotor to separate the snow to be removed from the surface being cleaned.

A casing with a semi-cylindrical (mainly) open cavity form for placement and rotation of the rotor with blades and scoops. An ejection window in the upper back of this cavity above the thrower to eject material through the nozzle.

The schematic drawings do not show the necessary control, sensor and signal equipment.

The arrows indicate the direction of rotation of the rotor and the direction of the ejection of snow flow through the exhaust window and the exhaust pipe.

Implementation of a utility model.

The range of material to be cleaned by the proposed device is from freshly fallen dry or wet snow to dense icy snow shafts (a clean selection of the lower layers of snow and snow, there is no need for preliminary loosening-crushing of the grader with a knife and moving it off the curb with the grader, from road fences, from passenger transport stops, from houses on the hard surface of the road, everything is transformed into an ejected dense snow stream with small scattering and snow falling from the stream in the ejection).

The condition of a sufficiently high rotor speed ensures that pieces of snow hit the blades of the impact feeder (with impact crushing of ice and compacted snow), the transition of snow from the blade to the blade, the rapid acceleration of the snow-ice mass, the transition to a dense, uniform high-speed snow flow and throwing material through the exhaust pipe. Reducing the energy intensity of the main operation (and the features of the working body do not need additional vehicle effort to move forward) and auxiliary operations, increasing productivity,

saving the volume of the truck body due to snow compaction during the shock stop of the high-speed flow ejected from the nozzle in the body.

High machine performance and the principle of operation of a high-speed working body allows you to change the technological schemes of work and get savings on auxiliary operations and manual work. The ability of the working body to independently crush the compacted snow and ice makes it possible to remove the shafts without using the auxiliary operation of breaking the shaft and moving it away from the fence with a grader. A clean selection of the lower layers of snow and rolling reduces the need for manual additional cleaning. When loading snow, it is compacted in the car body, which means that you can get savings on the number of vehicles involved.

Performance and maneuverability allow cleaning in any road conditions. Using the loader’s base makes the car agile and able to remove snow in hard-to-reach places and simultaneously clean the track of the road and the conditions of the track (exits, junctions, bus stops). The snow blower can work near residential buildings, at bus stops, near fences, without causing damage to them. The formation of a dense snow stream during ejection from the snow blower and its small dispersion during movement allows the snow to be thrown over buildings (for example, kiosks, car pavilions) and the right of way without snow falling on them.

The snow blower can clean shafts much higher than the vertical size of the receiving hole of the rotor casing and the height of the snow is limited only by safety rules. The work of the snow blower is safe and does not require special fencing of the place of work. The snow blower does not interfere with traffic and pedestrians.

Regulation of the direction of ejection allows you to choose the location of snow storage. The rotary exhaust pipe allows you to throw snow both on the right of way and load it into the car body.

The device operates as follows.

They turn on the drive motor and, after accelerating to a nominal speed of 1800 ... 2200 rpm, the clutch automatically engages and engages a belt drive and then a common single feeder and thrower rotor, regardless of the presence or absence of snow and ice being removed. In the case of snow, its high-speed and highly efficient cleaning begins with the feeder blades to the thrower and thrower ladles (see figure 2) into the exhaust window and out through the exhaust pipe (see figure 1). In the event of a decrease in the rotation speed of the drive motor below the nominal range, the clutch automatically shuts off and, consequently, the snow blower rotor stops and operation ends.

In conclusion, the description presents selected technical indicators of the production model of the device: performance - under ordinary conditions - 1800 ... 2000 t / h; the maximum possible - up to 5000 t / h; on a dense icy snow shaft - at least 800 t / h; snow discharge distance - up to 50 m; regulation of a direction of a stream 200 °; drive motor power 118 kW.

Claims (12)

1. Mounted rotary snow blower containing a common thrower rotor with radial blades and a feeder with blades inclined towards the thrower, the specified rotor is mounted in supports in the housing casing with an exhaust window upward above the thrower in an exhaust rotary guide pipe, a drive unit with kinematic transmission of rotation to the rotor , mounting the housing to the transport medium, characterized in that the feeder blades are made in the form of separate impact blades, installed mainly uniformly radial but also axially in several rows, the planes of these feeder blades are inclined to the rotor center line, while in the left part of the feeder, the blades are tilted from the rotor center line counterclockwise to the rotor axial line, and the blades are tilted from the center line to the right of the feeder part the rotor within the quadrant clockwise, mainly in the middle of the thrower, converging end-to-end of the upper edges of the left and right parts of the row adjacent to the thrower; thrower blades have the form of concave in the direction of rotation, mainly semi-tubular scoops, mounted on a common rotor mainly in the middle of the thrower and mainly in the middle of the rotor angle between the convergence of the butt of the feeder blades; transmission of rotation from the drive motor to the common rotor of the feeder and thrower with the possibility of slipping during overloads - belt transmission, and with the possibility of automatically connecting the transmission to the drive motor at a speed of rotation of the specified motor is not less than the nominal threshold value. 2. The snow blower according to claim 1, characterized in that the feeder blades have a flat working surface in the direction of the thrower and the stiffening ribs on the rear side. 3. The snow blower according to claim 1, characterized in that the number of rows of the blades of the feeder is three, the angular distance between the rows is mainly 120 °, the angle of inclination of the planes of the blades is mainly 55 ° to the center line of the rotor. 4. The snow blower according to claim 1, characterized in that when sweeping the rotor with the blades onto the plane, the inclined blades in adjacent rows are located along common straight lines. 5. The snow blower according to claim 1, characterized in that the height of the thrower scoop is predominantly equal to the height of the feeder blades, the volume of the thrower scoop corresponds to the capacity of the feeder, the capacity of the exhaust window and the exhaust pipe, in particular, the width of the thrower scoop is equal to the width of the exhaust window and the exhaust pipe. 6. The snow blower according to claim 1, characterized in that the exhaust pipe is made box-shaped with a regulator of the emission range at the end, the side projection of the pipe has an inclined curvilinear shape of a predominantly logarithmic spiral, instead of a lower wall, there are tightening bars in the pipe. 7. The snow blower according to claim 1, characterized in that a diesel engine is used as the drive engine. 8. The snow blower according to claim 1, characterized in that the nominal speed of rotation of the drive motor when connecting the rotor through a kinematic transmission is 1800 ... 2200 rpm. 9. The snow blower according to claim 1, characterized in that high-speed radial rolling bearings are used as rotor bearings. 10. The snow blower according to claim 1, characterized in that in the lower part of the housing casing in front of and under the rotor with blades is fixed with the possibility of rearrangement as the wear and tear of the carbide blade of the material to be removed. 11. The snow blower according to claim 1, characterized in that the mounting of the housing is made adjustable for its canopy, for example, instead of a bucket on a standard front-end loader. 12. The snow blower according to claim 1, characterized in that the corresponding control, sensor and signal equipment are used in the device.