RU159403U1 - BUNKER LOADING DEVICE - Google Patents

Abstract

A bunker loading device designed for workpieces having the shape of bodies of revolution with asymmetries of the ends, one of which is cylindrical and the other asymmetric, containing a hopper formed by a shell and a fixed base, a rotating disk with through sockets alternating with teeth to capture these processing items , and mounted on a fixed base under a rotating disk, an annular orientator with a groove facing the through sockets of the rotating disk and whose section repeats the profile a symmetrical end of the workpiece, while the width of the upper part of the groove does not exceed the diameter of the cylindrical end of the workpiece, characterized in that the groove of the annular orientator is made with a gradually varying depth in the direction of rotation of the rotating disk, and in the portion of the annular orientator located in the lower part of the hopper, the depth the groove is minimal and does not exceed 1/4 of the height of the asymmetric end of the workpiece, and in the section of the ring orientator located at the top of the hopper, the depth of the groove max flax and is equal to the height of the asymmetric end of the workpiece, while the distance from the bottom of the groove of the ring orientator to the surface of the rotating disk is constant around the entire circumference of the ring orientator, the end surface of the ring orientator with the groove facing the rotating disk is curved and the direction of its rise corresponds to the direction of rotation a rotating disk, and the angle of its rise does not exceed the angle of friction of the cylindrical end of the subject of processing on the end surface of the annular orientator.

Description

The technical solution relates to machine tool construction, namely to devices for automatically loading technological machines and automatic lines with objects of processing the shape of bodies of revolution with implicitly expressed asymmetry of the ends.

Known bunker loading device containing a hopper formed by a shell and a fixed base, a rotating disk with through sockets, alternating with teeth to capture objects of processing the shape of bodies of revolution (see in the book. N.I. Kamyshny. Automation of loading machines. M .: Mechanical Engineering , 1977.288 s., Pp. 92-93, Fig. 84).

The disadvantage of this bunker boot device is the inability to load objects of processing the shape of bodies of revolution with implicitly expressed asymmetry of the ends, one of which is cylindrical and the other asymmetric, for example, conical, step or spherical.

Known bunker loading device containing a hopper formed by a shell and a fixed base, a rotating disk with through sockets, alternating with teeth to capture objects of processing the shape of bodies of revolution with implicitly expressed asymmetry of the ends, one of which is cylindrical and the other asymmetric, and mounted on a fixed base under the rotating disk, an annular orientator with a groove facing the through sockets of the rotating disk, the cross section of which repeats the profile of the asymmetric end face of the object work, and the width of the upper part of the groove facing the through sockets does not exceed the diameter of the cylindrical end of the subject of processing (RF Patent 100942. IPC B23Q 7/02. Bunker loading device / VV Golubenko, EV Davydova, V.V. Price. Publish. 10.01.11. Bull. No. 1).

The disadvantage of this bunker loading device is the increased wear of the annular orientator, and, as a result, the reliability of the bunker loading device is reduced due to the friction of the asymmetric ends of the processing objects on the inner surface of the groove along almost the entire circumference of the annular orientator.

The objective of the technical solution is to increase the reliability of the bunker boot device by reducing wear on the annular orientator.

The specified technical problem is solved due to the fact that the bunker loading device comprises a hopper formed by a shell and a fixed base, a rotating disk with through sockets, alternating with teeth to capture objects processed by the shape of bodies of revolution with asymmetry of the ends, one of which is cylindrical and the other asymmetric and an annular orientator mounted on a fixed base under a rotating disk with a groove facing the through sockets of the rotating disk, the cross section of which repeats the profile of the end-symmetric processing object.

What is new is that the groove cross section smoothly changes in the direction of rotation of the rotating disk in such a way that in the portion of the annular orientator located at the bottom of the hopper, the depth of the groove facing the through sockets of the rotating disk is minimal and does not exceed ¼ the height of the asymmetric end face of the workpiece, and in the area of the annular orientator located in the upper part of the hopper, the depth of the groove facing the through sockets of the rotating disk is maximum, but does not exceed the height of the asymmetric end of the object about work, while the distance from the bottom of the groove facing the through sockets to the surface of the rotating disk remains unchanged but the entire circumference of the ring orientator, the end surface of the ring orientator with the groove facing the rotating disk is made curved and the direction of its rise coincides with the direction of rotation of the rotating disk and the angle of elevation of the end surface of the annular orientator does not exceed the angle of friction of the cylindrical end of the processing subject along the end surface of the annular orientator.

The essence of the technical solution is illustrated by drawings, where:

in FIG. 1 shows a diagram of a hopper loading device in a section along the axis of a rotating disk with sockets;

in FIG. 2 shows a sectional view of an enlarged fragment of a portion of the annular orientator located in the lower part of the hopper of the bunker loading device (fragment I of Fig. 1);

in FIG. 3 shows a sectional view of an enlarged fragment of a portion of the annular orientator located in the upper part of the hopper of the hopper loading device (fragment II of FIG. 1).

The hopper loading device comprises a hopper formed by a shell 1 and a fixed base 2, a rotating disk 3 with through sockets 4, alternating with teeth 5 for gripping processing objects 6 of the shape of bodies of revolution with asymmetry of the ends, one of which A is cylindrical and the other B is asymmetric (conical, step or spherical).

An annular orientator 7 with a groove 8 facing the through sockets 4 of the rotary disk 3 is mounted on a fixed base 2 under the rotating disk 3, the cross section of which repeats the profile of the asymmetric end face of the workpiece, while the width b of the upper part of the groove 8 does not exceed the diameter of the cylindrical end A of the workpiece 6.

The cross section of the groove 8 smoothly changes but in the direction of rotation of the rotating disk 3 so that in the section of the ring orientator 7 located at the bottom of the hopper, the depth h _{min of the} groove 8 facing the through sockets 4 of the rotating disk 3 is minimal and does not exceed ¼ of height H asymmetrical processing object B end 6, and an annular portion orientator 7 disposed in the upper part of the hopper, the depth h _max recess 8 facing the passage socket 4 of the rotary disc 3, the maximum but does not exceed the height H of the subject asymmetric end B brabotki 6, wherein the distance m from the bottom of recess 8 facing the passage socket 4, to the surface of the rotary disk 3 is made constant over the entire circumference of the annular orientator 7.

The end surface K of the ring orientator 7 with the groove 8 facing the rotating disk 3 is curved and the direction of its rise coincides with the direction of rotation of the rotating disk 3, and the angle of rise γ of the end surface K of the ring orientator 7 does not exceed the friction angle ρ = arctgµ, where µ - the coefficient of sliding friction of the cylindrical end face A of the workpiece 6 along the end surface K of the ring orientator 7.

Bunker boot device operates as follows.

When the disk 3 rotates, the objects of processing 6, which are filled up in the hopper formed by the shell 1 and the fixed base 2, are agitated, poured and fall into the through holes 4 or fall onto the teeth 5 and, turning around them, also fall into the through holes 4.

Processing objects 6, sunk into the through slots 4 of the rotating disk 3 by the cylindrical end A downward, are supported by them on the end surface K of the ring orientator 7, since the width b of the upper part of the groove 8 does not exceed the diameter of the cylindrical end A of the processing object 6. With further rotation of the rotating disk 3 objects of processing 6, sliding along the curved end surface K of the annular orientator 7, rise in the through sockets 4 and in the upper part of the hopper fall out of them under the action of gravity back into the hopper.

Processing objects 6, sunk down into the through holes 4 with the asymmetric end B, rest on the bottom of the groove 8 of the ring orientator 7 and are held securely in the through holes 4, since the distance m from the bottom of the groove 8 to the surface of the rotating disk 3 remains unchanged around the entire circumference ring orientator 7. With the further rotation of the rotating disk 3, the objects of processing 6, sliding along the asymmetric end B along the bottom of the groove 8, are moved to the upper part of the hopper. Since the depth of the groove 8 in the portion of the annular orientator 7 located in the upper part of the hopper is maximum, the objects of processing 6 are reliably held in the groove 8 and the through sockets 4, are moved by the rotating disk 3 into the delivery zone, and protruded from the through sockets 4 into the receiver (in FIG. not shown).

Since the groove cross section smoothly changes in the direction of rotation of the rotating disk so that in the portion of the annular orientator located at the bottom of the hopper, the depth of the groove is minimal, and only in the portion of the ring orientator located in the upper part of the hopper, the groove depth reaches its maximum value, then the total the friction of the objects to be processed with asymmetric ends on the inner surface of the groove is significantly lower than in the known technical solution (prototype).

Thus, the proposed technical solution reduces wear of the annular orientator and increases the reliability of the bunker boot device.

Claims (1)

A bunker loading device designed for workpieces having the shape of bodies of revolution with asymmetries of the ends, one of which is cylindrical and the other asymmetric, containing a hopper formed by a shell and a fixed base, a rotating disk with through sockets alternating with teeth to capture these processing items , and mounted on a fixed base under a rotating disk, an annular orientator with a groove facing the through sockets of the rotating disk and whose section repeats the profile a symmetrical end of the workpiece, while the width of the upper part of the groove does not exceed the diameter of the cylindrical end of the workpiece, characterized in that the groove of the annular orientator is made with a gradually varying depth in the direction of rotation of the rotating disk, and in the portion of the annular orientator located in the lower part of the hopper, the depth the groove is minimal and does not exceed 1/4 of the height of the asymmetric end of the workpiece, and in the area of the ring orientator located in the upper part of the hopper, the depth of the groove max flax and is equal to the height of the asymmetric end of the workpiece, while the distance from the bottom of the groove of the ring orientator to the surface of the rotating disk is constant around the entire circumference of the ring orientator, the end surface of the ring orientator with the groove facing the rotating disk is curved and the direction of its rise corresponds to the direction of rotation a rotating disk, and the angle of its rise does not exceed the angle of friction of the cylindrical end of the subject of processing on the end surface of the annular orientator.

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