SU1676505A1 - Silo feed storage unloading device - Google Patents

Abstract

l / l3o6pjTehtte ogogits to villages, ojn machine phosphoente O About Objective and hpe shadows - increase w in the technological process of unloading the feed by removing its residues to the stems of the wound The device should be aligned along the shaft for less than a distance from the wall to the shaft and less than the distance from the wall to the shaft for less than the distance from the wall to the shaft for less than the distance from the wall to the shaft for less than the distance from the wall to the shaft for less than the distance from the wall to the shaft for less than the distance from the wall to the shaft for less than the distance from the wall to the shaft for less than 1 m from the wall to the shaft for less than 1 m the distance between the wall and the hp of the hp is shown. moreover, from the back of its working surface, a brush is made by means of a rigid bond, made of elastic elements that have a variable, increasing rigidity towards the separator 1 surface in the form of / cut conugue, through which they contact the storage wall. Thanks to this, during the work of the sweeper, the brush rotates together with the displacer with (with elastic elements about the same layer of feed left by the presence of technological protective wall between the wall and the outermost disc compartment, which reduces the friction of the latter on the near-wall does the technological process of unloading feed 5 or

Description

FIELD OF THE INVENTION The invention relates to agricultural machine building, in particular to unloaders of stalked fodder from tower storages.

The purpose of the invention is to increase the reliability of the process of unloading feed for the estimates of removal of its residues from the walls of the storage

FIG. 1 schematically shows a device for unloading feed storage tanks from the side, FIG. 2 - node I in FIG. 1, front view; Fig 3 is also a view from above 1; Fig 4 shows the interposition of the disk separator and the brush in Fig 5 axonometric projection

The device contains disk separators 1, each of which is mounted on the shaft 2 and is connected by means of vertical posts 3 with three radial rods 4, which are located relative to each other at an angle of 120 °. The rods 4 are rigidly fixed to the body of the unloading body, in which quality the pneumatic belt 5 with the V-belt drive 6 from the electric motor 7 is used. The body of the pneumatic bolt 5 through the unloading pipe 8 is connected to the current collector 9 fixed on the suspension triangle formed by three spacers beams 10, located relative to each other at an angle of 120 °. Beams 10 through three side 11

ABOUT

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and one central 12 cables are connected to an electric winch (not shown) mounted outside the tower and intended for vertical movements of the device.

The circular movement of the rod 4 around the axis of the tower is made from the gearmotor 13 through the chain transmission 14. In the operating mode of the device for unloading the feed storage tanks, the unloading pipe 8 and the gearmotor 13 are closed with a cone-shaped casing 15 equipped with a hatch with a lid for installation the discharge deflector 16. The beams 10 are located above the rod 4 and are provided at the ends facing the wall 17 of the tower with support wheels 18 with a horizontal axis of rotation. The ends of the rods 4 have support wheels 19 with a vertical shaft of rotation 20, and the wheels 19 are arranged so that their maximum distance from the axis of the tower does not exceed the minimum radius of the tower, which as a rule does not have a strictly cylindrical shape throughout its height due to construction defects or for a number of other reasons.

At least on one of the rods 4, a clutch 21 is spring-mounted on the side of the tower wall 17, spring-loaded 22, which, together with the clutch 21, is fixed to the rod 4 by means of washers 23 and pin 24, a flange hub 25 of the shaft 20 fixed to the upper plate of the clutch 21 longitudinal grooves. The flange hub 27 of the column 3 is attached to the bottom plate of the coupling 21 provided with annular grooves 26. The longitudinal movements of the coupling 21 are limited by the rigidity of the spring 22 so that, with maximum compression of the latter, the end face of the rod 4 does not extend beyond the support wheel 19.

A brush 28 is rigidly fixed on the shaft 2, the non-grounded ends of the elastic elements 29 of which form the surface 30 in the shape of a truncated cone, the larger base of which is located on the side of the disk compartment 1, is made in the form of the surface 31, equidistant from the working surface 32 of the separator 1 The overhang of the non-grounded ends of the elastic elements 29 of the brush 28 is equal to the size of the gap formed by the working edge of the disk separator 1 and the storage wall 17, which is the farthest from the axis of rotation of the device. The size of this gap is limited by the installation of the support wheel 19 with respect to the coupling 21 and the rod 4, taking into account the angle of attack of the disk separator 1 and the walls 17 of the store. The size of this gap is limited by the installation of the support wheel 19 with respect to the coupling 21 and the rod 4, taking into account the angle of attack of the disk separator 1 and the parameters of the brush 28. The brush 28 is made of elastic elements 29 that have different stiffness due to the use of an elastic material of different cross section. Moreover, the stiffness of the elements 29 increases in the direction of the larger base 31 of the truncated cone 30.

The disc trap 1, associated with the brush 28, is preferably mounted to take the feed directly from the tower wall 17, taking into account the protective technological gap. All subsequent disk separators 1 are located in such a way that the gap between two adjacent disk separators 1 overlaps with two subsequent, spaced toward the center of the tower on two successive rods 4 following this. Disk separators 1 previously installed at each angle of attack and tilt, oriented to moving the mass to the center of the tower.

The power supply cables 33 of the engine 7 and the gearmotor 13 are laid along one of the expansion beams 10 and then parallel to the cable 11 through blocks (not shown) to the control cabinet (not shown).

When the device is in operation, the disc traps 1, moving together with the radial rods 4, driven by the gearmotor 13 through the chain gear 14, cut off the chips from the feed monolith and then transport the mass separated in this way to the center of the tower, from where the mass of the pneumatic rip 5 is thrown through discharge pipe 8 through the deflector 16 outside the tower. Simultaneously with the disk separator 1, a brush 28 is rigidly mounted on its shaft 2, the elastic elements 29 of which, with their non-gapped ends forming the surface in the shape of a truncated cone 30, scrape off the wall 17 of the feed left in the protective technological gap. At the same time, more rigid front elements (along the movement of the rod 4) elastic elements 29, embedded in the feed monolith at a relatively acute angle, milling the monolith, working as a needle cutter, and transporting the separated mass to the zone of action of the separator 1. In this case, work brushes 28 are similar to such a separator, in which the cutting edges are formed by the ends of the elastic elements 29, and the working surface is the surface 31, equidistantly spaced from the working surface 32 of the disk separators 1. Subsequent layers are the elastic element 29, stiffness

which is reduced, is due to the fact that the brush 28 only contacts the wall 17 along the generatrix of the cone 30, which is caused by the departure of the non-tangled ends of the elastic elements 29, which is equal to the size of the technological gap and is limited by the wheel 19.

As the feed is notched simultaneously with the lowering of the device and the separators 1, the working area of the brush 28 and the elastic elements 29 also moves down.

Due to the high frequency of rotation of the rods 4, the disk trays 1 and the associated brush 28 with a relatively low speed of lowering the device, the elastic elements 29 completely clean the surface of the wall 17.

In case of obstruction of the wall 17 to be cleaned, the support wheel 19, compressing the spring 22, moves the clutch 21, and with it the stand 3 with the separator 1 and the brush 28, while not altering their relative position damage to the wall 17, the separator 1 and the brushes 28. After overcoming obstacles or gradually cutting off the feed monolith, the coupling 21 returns to its original position by the spring 22.

Thus, the reliability of the process of unloading feed from the tower storage is increased due to simultaneous cleaning of the walls with unloading.

Claims (1)

turret from the remnants of forage, which eliminates the use of manual labor, respectively, reduces the technological pauses and ultimately increases the operational performance of the unloader by 20-30% compared to the prototype. The invention includes a device for unloading feed storage tanks containing disk separators, each of which is mounted on a shaft and connected by means of vertical posts to radial rods that have a circular movement drive and support wheels, an unloading working element and expansion beams with a cable suspension system, characterized by that, in order to improve the reliability of the process of unloading the feed by removing its residues from the walls of the storage, coaxially on the shaft of at least one located near the unit xp Anilishe separator on the back side of its working surface is a rigidly mounted brush, made in the form of a truncated cone of elastic elements of a variable, increasing in the direction of the stiffness separator, the larger base of the truncated cone of the brush is located on the separator side and equidistant to its working surface associated with the radial rod and with each other with the possibility of mutual displacement. w Have 4FY /// rf ///////////////// // U //// /// U / U // U / 4Y fig 17 19 if gz I 29 23 22 tt Fig.Z FIG. four