RU190719U1 - Device for cleaning the surface of ice and compressed snow - Google Patents

Abstract

The invention relates to the cleaning of the surface from ice and compressed snow using rotating working elements and can be used for various surfaces, such as metal, asphalt or concrete. A device for cleaning the surface from ice and compressed snow, comprising side bearing supports arranged parallel to each other, connected to them of the central shaft and rods located perpendicular to the side bearing supports between them, and also located on the rods of the body is small and large impact elements, while the mass of large impact elements is at least twice the mass of small impact elements. The technical result consists in increasing the efficiency of cleaning the surface of ice and compacted snow while eliminating the possibility of damage to the surface being cleaned.

Description

The utility model relates to the cleaning of the surface from ice and compressed snow with the help of rotating working elements and can be used for various surfaces, such as metal, asphalt or concrete.

A device for cleaning the surface is known (Device and method for cleaning the surface: patent No. 2552747, Russian Federation, application No. RU2014107929, application. 03/03/2014, publ. 10.06.2015) containing a cylindrical body mounted on a shaft, around a circle on axes parallel to it the axis of the shaft, installed percussion elements with the possibility of radial movement due to made in the last longitudinal groove. The percussion elements of the device are made in the form of hexagons with sides extended along the longitudinal axis of the groove and mounted with the possibility of rotation around the axis with the provision of impulsive impact force for the working zones. Dividing washers are placed between the percussion elements. This device is the closest in technical essence to the claimed utility model and therefore was adopted as a prototype.

The disadvantage of the prototype is the relatively low efficiency of cleaning the surface from ice and compressed snow. This is due to the design features of the prototype device, namely, the presence of only one type of impact elements located at the same level relative to the surface being cleaned, as well as their shape, which does not contribute to ice splitting, which allows only milling of ice and compressed snow.

The technical result consists in increasing the efficiency of cleaning the surface from ice and compressed snow while eliminating the possibility of damage to the surface being cleaned.

The technical result is achieved in that the device for cleaning the surface from ice and compressed snow, comprising a housing consisting of two lateral bearing supports arranged parallel to each other, a central shaft connected to them and rods arranged perpendicular to the lateral supporting supports between them, as well as shock according to the utility model, the elements located on the body rods contain small impact elements and large impact elements, while the mass of large impact elements is greater than the mass of small impact elements in at least twice.

Performing percussion elements of two types (small and large), taking into account the difference in mass at least twice, improves the efficiency of cleaning the surface from ice and compressed snow due to the possibility of combining two types of cleaning at the same time, namely milling and tearing off ice and compressed snow directly from the surface without damaging it with small percussion elements (due to their low mass), and splitting thick ice above the surface without contact with it (large percussion elements). All this allows you to avoid deformations of the surface being cleaned when cleaning from thick layers of ice and compressed snow.

The presence of elements that are at least twice as large as the mass of small elements makes it possible to increase the cleaning efficiency due to the fact that heavier impact elements allow splitting and milling faster those areas of frost and compressed snow that small impact elements could not cope with. Since the objective function of small elements is to remove frost and compressed snow directly from the surface interacting with it, their mass may not be significant, but should be sufficient to split and mill the layers of ice and compressed snow of small height. Since the areas with icing and compacted snow have fragments with a high layer of formations, such areas split and grind heavier elements that can destroy the more dense and high layers of icing and compressed snow.

Performing a central shaft connected to the side supports helps to exclude spiral strains during rotation that adversely affect the reliability of the device and the cleaning efficiency, as well as increase the risk of damage to the surface being cleaned. In the most preferred embodiment of the utility model, small percussion elements and large percussion elements are arranged on each rod of the housing alternately. Additionally, in a preferred embodiment of the utility model, the length of small impact elements exceeds the length of large impact elements to ensure the difference in distance between the two types of impact elements to the surface being cleaned. In addition, in the preferred embodiment of the utility model, each impact element has at least one acute angle. Also in the preferred embodiment of the utility model, the device is equipped with additional rods equipped with polymer brushes and located between the rods on which the percussion elements are mounted. All of these modifications further enhance the effectiveness of the device in terms of cleaning the surface from ice and compacted snow.

The utility model is illustrated by a drawing, where in FIG. 1 shows the claimed device in an axonometric projection; FIG. 2 shows the claimed device in cross section, and FIG. 3 shows the inventive device mounted on the chassis frame.

The device for cleaning the surface from ice and compressed snow comprises a housing which consists of two lateral bearing supports 1 arranged parallel to each other, a central shaft 2 and rods 3 located perpendicular to the lateral supporting supports 1 between them. The device also contains small percussion elements 4 and large percussion elements 5, located on the rods of the housing. At the same time, the mass of large impact elements is at least twice the mass of small impact elements. Small percussion elements 4 and large percussion elements 5 are located on each rod 3 of the housing alternately. In addition, the length of the small percussion elements 4 exceeds the length of the large percussion elements 5. At the same time, the small percussion elements 4 are closer to the surface to be cleaned compared to the large cleaned elements 5 when mounted on one rod 3. Each percussion element has at least one acute angle and the groove for installation on the rod, the size of the groove exceeds the diameter of the rod to allow rotation of the impactor relative to the axis of the rod. The device is also equipped with additional rods 6, equipped with polymer brushes 7 and located between rods 3, on which small percussion elements 4 and large percussion elements 5 are located. The claimed utility model is intended for use on a special chassis frame (as shown in Fig. 3), but it can also be installed on other similar devices, for example, in the form of a removable hinged structure on a walk-behind tractor, utility equipment or similar equipment.

The claimed utility model works as follows.

The device is installed on the chassis frame and connect the central shaft 2 with the engine. The design is moved to the surface to be cleaned and the engine is turned on, which transmits torque to the central shaft 2 and, accordingly, the inventive device begins to rotate relative to the central axis parallel to the axis of the rods. During rotation, the percussion elements 4, 5 of one of the rods 3 are in contact with the surface being cleaned and produce a shock effect. At the same time, small percussion elements 4, which make ice milling on the surface and split thin layers of ice, come into contact with the surface, and large percussion elements 5 touch the surface in those areas where there are high and dense ice sections, which split them. Milling, splitting and splitting of ice occur due to the sharp corners of the impact elements. Upon further rotation of the device with the surface being cleaned, polymer brushes 7 are in contact, which discard the chopped pieces of ice to the side. After that, small percussion elements come into contact with the surface being cleaned, and so on.

The claimed utility model is illustrated by examples.

Example 1

Were conducted bench tests of two images of the device for cleaning the surface for a comparative study of the effectiveness of cleaning and damage to the surface.

Sample 1 was a device according to the invention, comprising a housing including side bearing supports, a central shaft and rods, as well as small and large impact elements. Moreover, the mass of large impact elements is twice the mass of small impact elements, in particular, the mass of large impact elements was 60 g. with a length of 30 mm, and the mass of small percussion elements was 30 g. with a length of 50 mm.

Sample 2 was a device, which was based on the design features of the prototype, comprising a housing, including side bearing supports, a central shaft and rods, as well as impact elements. The mass of percussion elements was 30 grams. with a length of 50 mm.

Test setup: Asphalt pavement was cleaned during the winter period, having ice formations with heights from 3 to 10 cm. The ambient air temperature was -7 degrees.

Sample 1 and Sample 2 were moved over a surface that did not have frost towards the surface with frost at a speed of 0.3–0.5 meters per second (1–2 km / h). When the frost reached, the movement continued further 3 m, and cleaned up.

After that, an assessment of the quality, speed and efficiency of cleaning was carried out. The cleaning efficiency was expressed in the maximum frost height removed by the Sample from the surface.

Test results

Sample 1 removed frost 9 cm high throughout its entire journey (3 m) by cleaning the surface to asphalt. However, in some places there were spots of thin, unreleased frost, which required a delay of the Sample above this place. Since there were no delays, the speed remained constant and was 0.45 m / s (1.6 km / h).

Sample 2 cleaned the surface to pure asphalt only in those areas where the frost height did not exceed 35 mm and for such sites the cleaning degree was 72%, since residual ice layers required a stop over this place. In this case, the constant speed of movement was 0.3 m / s (1 km / h).

The results are shown in table 1.

Table 1 - test results.

Sample Maximum cleaning height, cm Degree of cleaning,% Average speed, MP / sec one 90 85 0.45 2 35 72 0.3

The inability to remove thick layers of frost and the relatively low cleaning rate of Sample 2, before Sample 1, is due to the fact that high layers of frost cannot be removed quickly with small impact elements due to the fact that the masses of small impact elements are not enough. At the same time, Sample 1 had heavy percussion elements that cleaned the upper part of thick layers of ice (from 50 mm) due to its mass, which made it possible to remove layers of ice in 90 mm with an average constant speed of 0.45 m / s.

Example 2

Were conducted bench tests of two images of the device for cleaning the surface for a comparative study of the effectiveness of cleaning and damage to the surface. At the same time, the test scheme did not differ from that given in example 1.

Sample 1 was a device according to the invention, comprising a housing including side bearing supports, a central shaft and rods, as well as small and large impact elements. At the same time, the mass of large impact elements is twice the mass of small impact elements, in particular, the mass of large impact elements was 70 g for a length of 40 mm, and the weight of small impact elements was 40 g for a length of 60 mm.

 Sample 2 was a device comprising a housing, including side bearing supports, a central shaft and rods, as well as small and large impact elements. Moreover, the mass of large impact elements is one and a half times the mass of small impact elements, in particular, the mass of large impact elements was 45 g with a length of 30 mm, and the weight of small impact elements was 30 g with a length of 50 mm

Test results

Sample 1 removed frost 9 cm high throughout its entire journey (3 m) by cleaning the surface to asphalt. However, fine frost spots were observed on the surface, which required a delay of the Sample over this area. Since there were no delays, the speed remained constant and was 0.45 m / s (1.6 km / h).

Sample 2 cleaned the surface to clean asphalt only in those areas where the frost height did not exceed 35 mm and for such sites the cleaning degree was 72%, since the residual frost layers required stopping over this place. The speed of movement was 0.3 m / s (1 km / h).

The results are shown in table 1.

Table 1 - test results.

Sample Maximum cleaning height, cm Degree of cleaning,% Average speed, MP / sec one 90 85 0.45 2 65 48 0.39

In this test example, Sample 2 was able to remove a portion of thick (more than 50 mm) ice layers, but in a smaller amount (no more than 50% of the total surface area) than Sample 1. This is due to the fact that Sample 2 has a lot of large percussion elements, insufficient for splitting the layers of ice, exceeding 50 mm in height, but sufficient for splitting the upper layers of ice in the ranges of 60–90 mm, i.e. their cleaning efficiency is 30 - 40 mm and is close to the efficiency of small percussion elements, which in turn deprives the device of the useful ability to destroy and remove thick layers of ice with a height of 50 mm or more, as Sample 1 can do.

Claims (5)

1. A device for cleaning the surface of ice and compressed snow, comprising a housing consisting of two lateral bearing supports arranged parallel to each other, a central shaft connected to them and rods arranged perpendicular to the lateral bearing supports between them, as well as impact elements located on body rods, characterized in that it contains small percussion elements and large percussion elements, while the mass of large percussion elements is more than the mass of small percussion elements at least twice. 2. A device for cleaning the surface of ice and compressed snow according to claim 1, characterized in that the small impact elements and the large impact elements are located on each rod of the housing alternately. 3. A device for cleaning the surface from ice and compressed snow according to claim 1, characterized in that the length of the small impact elements exceeds the length of the large impact elements. 4. A device for cleaning the surface of ice and compressed snow according to claim 1, characterized in that each impact element has at least one acute angle. 5. A device for cleaning the surface of ice and compressed snow according to claim 1, characterized in that the device is equipped with additional rods equipped with polymer brushes and located between the rods on which the percussion elements are located.

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