RU212678U1 - MILLING GROUND WORKING BODY - Google Patents

Abstract

The utility model relates to earth-moving machinery, in particular to machines with a milling working body for laying and cleaning channels. The technical result of the utility model is to increase productivity while reducing energy consumption. The technical result is achieved due to the fact that the cam of the milling earthmoving working body has two cutouts, with a depth and width sufficient to lose contact of the incoming end roller with the cam and free short-term rotation of the tooth around its axis against the direction of rotation of the disks until it stops against the protruding end of the corresponding tie beam. Milling earth-moving working body, including a frame, disks interconnected by tie beams and movably mounted on bearing supports of a horizontal axis, with axes rigidly installed in the holes of the disks perpendicular to their planes, on which, with the possibility of rotation between the tie beams, teeth with end rollers are installed , interacting with a cam rigidly mounted on the horizontal axis of the disks, the cam of the milling earthmoving working body has two cutouts, depth and width sufficient to lose contact of the incoming end roller with the cam and free short-term rotation of the tooth around its axis against the direction of rotation of the disks until it stops at the protruding end corresponding tie bar.

Description

The utility model relates to earth-moving machinery, in particular to machines with a milling working body for laying and cleaning channels.

Known milling working body of an earth-moving machine [Author's certificate RU No. 208581, IPC class. E02F 3/18, E02F 5/18, 2021], which includes a frame, supports, a cutter with cutting knives fixed on it and with blades transporting soil, hingedly mounted on the short legs of the cutter, with the possibility of contact with stops and with the possibility of turning under the action of stops around the axis of its hinge at an angle of 100-135°.

The disadvantage of this milling working body of an earth-moving machine is inefficient work with wet soil, which has a high coefficient of internal friction and high sticking ability. To unload the soil from the blades to the conveying body, the rotation of the blades at an angle of 100-135° is not sufficient to completely free the blades from the soil. Part of the soil remains on the blades and falls with further rotation of the milling working body outside the conveying body into losses at the bottom of the face, which reduces productivity.

The closest analogue to the claimed is a milling earthmoving working body [Author's certificate RU No. 1716002, IPC class. Е02А 5/02, 1992], which includes disks interconnected by tie beams and movably mounted on bearing supports of a horizontal axis, with axes rigidly installed in the holes of the disks perpendicular to their planes, on which, with the possibility of rotation between the tie beams, teeth with end rollers interacting with a cam rigidly mounted on the horizontal axis of the disks.

The disadvantage of this design is inefficient operation with wet soil having a high coefficient of internal friction and high sticking ability.

Under such conditions, the inclination of the tines without shaking them is not sufficient for complete release from the soil. Part of the soil remains on the teeth, reduces the filling of the teeth with a new portion, reducing productivity, and creates additional resistance to the penetration of the teeth in the cutting zone, increasing energy consumption.

The technical result of the utility model is to increase productivity while reducing energy consumption.

The technical result is achieved due to the fact that the cam of the milling earth-moving working body has two cutouts, with a depth and width sufficient to lose contact of the incoming end roller with the cam and free short-term rotation of the tooth around its axis against the direction of disk rotation until it stops against the protruding end of the corresponding tie beam.

The specified set of essential features ensures the emergence of milling earthmoving working body of new properties that are different from the prototype.

Thus, the claimed features of the utility model meet the criterion of "novelty".

In FIG. 1 shows a diagram of a milling earth-moving working body, side view, in Fig. 2 - section A-A in Fig. one.

A milling earth-moving working body, including a frame 9, discs 1 interconnected by tie beams 5 and movably mounted on bearing supports 12 of a horizontal axis 7, with axes 8 rigidly installed in the holes of the discs 1 perpendicular to their planes, on which, with the possibility of rotation between the tie bars beams, teeth 3 are installed with end rollers 6 interacting with a cam 4 rigidly mounted on the horizontal axis of the disks, characterized in that the cam 4 of the milling earth-moving working body has two cutouts 10, with a depth and width sufficient to lose contact of the incoming end roller 6 with the cam 4 and free short-term rotation of the tooth around its axis against the direction of disk rotation until it stops against the protruding end of the corresponding tie beam 5.

Milling earthmoving working body works as follows.

When the cutter rotates, at the moment tooth 3 approaches the soil cutting zone, the roller 6 meets the cam disk 1. In this case, the tooth 3 on the hinge axis 8 rotates according to the value of the specified cutting angle. In the zone of ejection of the cut soil into the zone of the receiving and transporting device 13, the roller 6 runs into the first cutout 10 in the cam disk 4, loses contact with the cam disk and, under the action of gravity of the soil located on it, the tooth 3 leans back to position 11 until it hits the corresponding tie beam 5. At the same time, the non-adhering part of the soil falls off from tooth 3 onto the receiving and transporting device 13. With further rotation of the cutter, roller 6 again meets cam disk 1, tooth 3 abruptly returns to the position of the specified cutting angle and shakes off part of the adhered soil . Further, when the roller 6 runs into the second cutout 10 in the cam disk 4, the tooth 3 leans back to position 2, hits the tie beam 5 again and abruptly returns to the position of the specified cutting angle, which practically frees the tooth from adhering soil.

There is the following causal relationship between the set of essential features of the utility model and the achieved technical result.

The presence of two cutouts 10 in the cam disk 4, with a depth and width sufficient to lose contact of the incoming end roller 6 with the cam 4 and free short-term rotation of the tooth around its axis against the direction of rotation of the disks until it stops against the protruding end of the corresponding tie beam 5, provides twice repeated tilting of the tooth 3 back, the impact of tooth 3 on the tie beam and a sharp tossing of the soil located on tooth 3. Such a process increases the productivity of the milling working body due to a larger volume of soil dumped from each tooth to the receiving and transporting device 13, and reduces the energy intensity of work by eliminating the re-transfer of soil adhering to the teeth 3 and reducing the resistance force to cutting new portions of soil with cleaned teeth 3. Sources of information:

1. Copyright certificate RU No. 208581, IPC class. E02F 3/18, E02F 5/18, 2021.

2. Copyright certificate RU No. 1716002, IPC class. E02A 5/02, 1992.

Claims (1)

Milling earth-moving working body, including a frame, disks interconnected by tie beams and movably mounted on bearing supports of a horizontal axis, with axes rigidly installed in the holes of the disks perpendicular to their planes, on which, with the possibility of rotation between the tie beams, teeth with end rollers are installed , interacting with a cam rigidly mounted on the horizontal axis of the disks, characterized in that the cam of the milling earth-moving working body has two cutouts, depth and width sufficient to lose contact of the incoming end roller with the cam and free short-term rotation of the tooth around its axis against the direction of rotation of the disks until it stops into the protruding end of the corresponding tie bar.

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