RU162270U1 - DISC DEVICE FOR GRINDING SUGAR BEET SEEDS - Google Patents

Abstract

A disk device for grinding sugar beet seeds, including a housing, a loading funnel, a lid with a hole in the center that simultaneously functions as a fixed upper disk, a processed seed collection bin with a housing for housing the drive, a lower disk with a planetary drive transmission, characterized in that it drives a planetary the transmission is made in the form of a crosspiece rigidly fixed to the shaft of the geared motor gearbox, kinematically connected to the lower disk with the help of at least three cranks of the same length the planetary gear wheel is mounted coaxially with the gearmotor shaft and is rigidly fixed to the drive mounting plate, and the satellite is firmly mounted on the shaft of one of the cranks, while the support gear and satellite are kinematically connected and placed in a protective housing mounted under the cross .

Description

The utility model relates to agricultural engineering and can be used for pre-sowing preparation of sugar beet seeds by removing the loose parenchyma of the pericarp.

A device for peeling, grinding and grinding grain (as USSR USSR No. 2067025, A01C 1/00, 09/27/1996, bull. No. 27). It contains a frame, a receiving funnel, lower and upper working disks with drives and a discharge hopper. The disadvantages of the device include a high percentage of injuries and crushing of seeds due to the intense exposure to two moving disks.

The closest technical solution to this utility model is, in essence, a disk grinding device (RF patent for invention No. 2501202, АСС 1/00, 12/20/2013, Bull. No. 35). It includes a housing, a loading funnel, a lid with a hole in the center that acts as a fixed upper disk, a lower disk with a drive consisting of an electric motor, a belt and planetary gears, and a hopper for collecting polished seeds. During operation, the lower disk with the help of the carrier rotates around the shaft of the articulated support of the belt drive of the drive and at the same time rotates around its geometric axis.

The disadvantages of the known device include the following. The layout of the drive of the lower disk with the “open” cover does not allow isolating the gear drive and the drive as a whole from the abrasive medium and provide lubrication of the gears. Therefore, the gears, working in an abrasive medium without lubrication, wear out intensively, which leads to their premature failure. In addition, the device works stably only with small diameters of the lower disk, since it is mounted on only one support - on the shaft of one satellite. An increase in the diameter of the lower disk increases the risk of injury to the seeds, as getting into the working area of solid and metal objects leads to bending deformation, i.e. to vibrations of the lower disk, therefore to a violation of the established working gap between the disks. Adjusting the axial displacement of the lower disk by changing the radius of the carrier is automatically accompanied by a change in the parameters and dimensions of the gear itself, which complicates the optimization of the operating parameters of the device.

The task to which the utility model is directed is to increase the operational reliability, durability and efficiency of the grinding device.

The technical result is achieved by the fact that the planetary gear carrier is made in the form of a crosspiece rigidly fixed to the shaft of the geared motor gearbox, kinematically connected to the lower disk by means of at least three cranks of the same length, and the planet gear support gear is aligned with the motor gearbox shaft and rigidly mounted on the drive mounting plate, and the satellite is rigidly mounted on the shaft of one of the cranks, while the support gear and the satellite are kinematically connected to each other and placed in a fixed the protective case embedded under the cross.

In FIG. 1 presents a structural - kinematic diagram of the proposed device for grinding seeds. In FIG. 2 shows a section AA in FIG. 1. and in FIG. 3 - fragment B in FIG. one.

The device (Fig. 1) consists of a loading funnel 1, a cover 2, a housing 3, a magnetic trap 4 of metal impurities, a cylindrical nozzle 5. The cover 2 is made with a hole in the center, and on the inside - with an abrasive coating and performs the function of a fixed upper disk. The feed hopper 1 contains an adjustment flap 6. The cover 2 is connected to the housing 3 through adjusting washers 7 (Fig. 3). The bottom case 3 is connected to the processed seed collection hopper 8 and mounted on the support frame 9. Inside the hopper 8 there is a drive case 10 isolated from an abrasive medium, which contains a mounting plate 11. The drive gear motor 12 is mounted with its flange to the mounting plate 11, and on A cross 13 is rigidly fixed to its shaft. The device contains a lower disk 14 with an abrasive coating, which is kinematically connected to the cross 13 using cranks 15 of the same length (see also Fig. 2). The necessary and sufficient number of cranks 15, providing stable operation of the lower disk 14, is three. The cranks 15 for balancing the inertial forces are made with counterweights 16. To ensure the drive of the cranks 15, and therefore the lower disk 14, the support gear 17 is rigidly fixed to the drive mounting plate 11, and a satellite 18 located in the shaft of one of the cranks 15 is rigidly mounted meshing with the supporting gear wheel 17. The gears 17 and 18 are tightly isolated from the abrasive medium by means of a protective housing 19, which is guaranteed to lubricate these gears.

The proposed device operates as follows. The initial seeds from the loading funnel 1 through a magnetic trap 4 of metal impurities and a cylindrical pipe 5 by gravity arrive at the lower disk 14. The lower disk 14 is structurally offset from the shaft of the gear motor 12 by an amount equal to the length of the cranks 15 and performs two types of movement simultaneously. Using the crosspiece 13, it rotates around the shaft of the geared motor 12, and with the help of one of the cranks 15 kinematically connected with the crosspiece 13, the satellite 17 and the support gear 18 are additionally moved along a circular path. Thus, all points of the lower disk 14, except for the rotational movement around the shaft of the gear motor 12, are simultaneously described in the circle plane of the same radius equal to the length of the cranks 15. Under the action of centrifugal forces, the seeds subsequently fall into the working space between the disks 2 and 14 and, making a movement along a complex spiral-shaped trajectory, gradually move to the periphery of the lower disk 14. As a result, the protruding edges break off and effectively remove the loose layer of the pericarp, more rounded shapes. The polished seeds are collected in the hopper 8. The adjustment of the working gap between the discs 2 and 14 is carried out using interchangeable washers 7 (Fig. 3). Cogwheels and bearings of crank joints are tightly isolated from the abrasive medium by protective glands (not shown conditionally in the figures).

The technical and economic effect is expressed in the fact that increases the operational reliability and durability of the device. In addition, thanks to the installation of the lower disk on three supports, i.e. on the shafts of three cranks, the stability of its work increases. This allows you to increase the diameter of the lower disk of the seeds, and therefore the performance of the grinding device without the risk of injury to the seeds.

Claims (1)

A disk device for grinding sugar beet seeds, comprising a housing, a loading funnel, a lid with a hole in the center that simultaneously functions as a fixed upper disk, a processed seed collection bin with a housing for housing the drive, a lower disk with a planetary drive transmission, characterized in that it drives a planetary drive the transmission is made in the form of a crosspiece rigidly fixed to the shaft of the geared motor gearbox, kinematically connected to the lower disk with the help of at least three cranks of the same length the planetary gear wheel is mounted coaxially with the gearmotor shaft and is rigidly fixed to the drive mounting plate, and the satellite is firmly mounted on the shaft of one of the cranks, while the support gear and satellite are kinematically connected and placed in a protective housing mounted under the cross .

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