RU2110057C1 - Tuber damage simulator - Google Patents

Abstract

FIELD: agricultural engineering. SUBSTANCE: rod-shaped drum 1 has window 2 for loading and is made of several sectors. Ends of extreme rods 5 of every sector are attached rigidly, and ends of rods 5 positioned between them are secured by means of flexible rubberized belt. Simulator is provided with cams to engage drum. EFFECT: more efficient operation. 3 dwg

Description

 The invention relates to devices for studying the physicomechanical properties of potatoes and can be used to determine damage to potato tubers during optimization of potato harvesting machines, as well as in the selection of new varieties of potatoes intended for mechanized cultivation.

 Closest to the invention is a device for determining the damage to root crops, containing a bar drum with a loading window.

 A disadvantage of the known design is that the test conditions of root crops do not fully correspond to the actual conditions of cultivation and harvesting of root crops, in particular potatoes. The device does not create conditions of dynamic loads on tubers due to the operation of shakers that occur in harvesting machines, the hollow cylinder is made rigid, which also does not correspond to the actual harvesting conditions, since a bar elevator, in particular a potato harvester, the effect of which imitates a hollow bar cylinder, is made flexible: the rods are interconnected by a rubber strap.

 The purpose of the invention is the approximation of test conditions to the actual conditions of mechanized harvesting of root crops.

 This goal is achieved in that the drum is made of several sectors, the ends of the extreme rods of each sector being fixed rigidly, and the ends of the bars located between them, fixed by means of a flexible rubberized belt, and equipped with cams.

 In FIG. 1 shows a drum of the proposed simulator; in FIG. 2 - simulator, side view; in FIG. 3 is a kinematic diagram of a simulator.

 The tuber damage simulator comprises a bar drum 1 with a tuber loading window 2 mounted on an axis 3 mounted on a frame (not shown). In the drum 1 is fixed the blade 4 (NBB'N '), consisting of rigidly fixed rods. All bars are rubberized. In drum 1, the rods 5 AA ', BB', CC ', DD', EE ', FF', GG ', HH' are rigidly fixed, and the bars 5 in each sector between points B and C, C and D, D and E , E and F, F and C, C and H, H and A, as well as from the opposite side of sectors B 'and C', C 'and D', etc. interconnected using a flexible rubberized belt 6 (to simplify the circuit in Fig. 1, only the section BCC'B 'is shown), i.e. represent a flexible bar elevator cloth. In addition, the ABB'A 'section is free from rods and is a window 2 for loading tubers. The end drum is closed by organic glass discs 7.

 An inclined platform 8 is installed inside the drum 1 and a cam 9 under the drum. The drum 1 is driven by an electric motor 10 through a clutch 11, a worm gear 12, sprockets 13 and 14. Rotation to the cams 9 is transmitted through gears 15 and 16, with this cams 9 rotate in the direction opposite to the direction of rotation of the drum 1.

 The simulator works as follows.

 A portion of tubers is poured into the rod drum 1 through the window 2. Then, an electric motor 10 is turned on and rotation through the clutch 11, a worm gear 12, sprockets 13 and 14 are transmitted to the drum 1, which begins to rotate. At this moment, the rotation is also transmitted through the gear (gears 15 and 16) to the cams 9, which begin to rotate in the direction opposite to the direction of rotation of the drum 1. The speed of the cams 9 is such that they make eight revolutions per 1 revolution of the drum 1, if eight sectors on the drum.

 Thus, the tubers are shaken on a flexible rod when they are at the lower point of the sector of the drum 1. Next, the blade 4 captures the tubers and raises them to a height at which the tubers freely slide off the blade 4 and fall onto the inclined platform 8. Rolling from the inclined platform 8 , the tubers fall onto the inner surface of the drum 1. The tubers, rolling along the rod surface, fall into the lower part of the drum 1, where they are shaken by eccentrics in a vertical plane. The described cycle is repeated until the required number of revolutions, after which the tubers are poured into the container during the reverse rotation of the drum 1.

 The use of the proposed device allows you to bring experimental tests as close as possible to the real conditions of mechanized cultivation and harvesting of root crops.

Claims (1)

 A tuber damage simulator comprising a bar drum with a loading window, characterized in that the drum is made of several sectors, the ends of the end bars of each sector being fixed rigidly, and the ends of the bars located between them, fixed by means of a flexible rubberized belt, and equipped with cams.

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