RU2399346C1 - Stem fodder classifier - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: invention relates to agricultural machinery for preparation of fodder and is intended for stem fodder separation into fractions. The stem fodder classifier contains a housing equipped with guide-mounted rollers, a set of screens of trapezoid cross section in the lower bases thereof rectangular holes are arranged, trapezoid shaped trays installed at a slant, chute boards installed at a slant, vessels for collection of fractioned stem fodder, a drawbar rigidly connected to the housing and positioned on the drive side, an electric motor. The classifier is additionally equipped with a spring positioned on the side opposed that of the drive with its one end connected to the housing and the other end attached to a stationary support and a motor control system whose output is connected to a 3-phase AC network. The electric motor performs linear forward movement and is represented by a 3-phase linear asynchronous motor. The secondary element of the 3-phase linear asynchronous motor is the drawbar rigidly connected to the housing and positioned on the drive side. The 3-phase linear asynchronous motor winding is connected to the output of the motor control system.

EFFECT: usage of the invention enables reduction of stem fodder classifiers overall dimensions and costs combined with improved reliability of their operation.

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Description

The invention relates to agricultural machinery for the preparation of feed and is intended for the separation of stalk feed into fractions.

A classifier of stalk feeds is known, including a housing equipped with rollers mounted on guides, a set of trapezoidal screens, in the lower bases of which there are rectangular openings, obliquely mounted trapezoidal trays, obliquely mounted pitched boards, containers for collecting stalks divided into fractions. An electric motor is an asynchronous rotation motor through a belt drive connected to a mechanism for converting rotational motion into reciprocating, connected to the housing by means of a rod rigidly connected to the housing.

The disadvantages of the known classifier of stalk feeds are reduced technical and economic indicators due to the increased weight and size characteristics of the drive. (GM Cookta. Machines and equipment for the preparation of feed. - M.: Agropromizdat, 1987. - 303 pp., Ill.).

The aim of the invention is to improve technical and economic indicators (reducing the cost, overall dimensions and mass of the drive, increasing the efficiency, reliability and performance of the classifier of stalk feed).

This goal is achieved by the fact that the classifier of stalk feeds, comprising a housing equipped with rollers mounted on rails, a set of trapezoidal screens, in the lower bases of which are provided rectangular openings, obliquely mounted trapezoidal trays, obliquely mounted pitched boards, containers for collecting stalks divided into fractions feed, draft, rigidly connected to the housing and located on the drive side, the electric motor according to the invention is equipped with a spring placed on the side opposite to the drive, one end of which is connected to the housing, and the other end is fixed to a fixed support, the engine control system, the input of which is connected to a three-phase AC network, and the electric motor performs linear translational motion and is made in the form of a three-phase linear asynchronous motor, with the secondary an element of a three-phase linear induction motor is a rod, rigidly connected to the housing and located on the drive side, while the winding of a three-phase linear asynchronous vigatelya connected to the output engine control system.

Due to the fact that the stalk feed classifier is equipped with a spring placed on the side opposite to the drive, one end of which is connected to the housing, and the second end is fixed to a fixed support, the engine control system, the input of which is connected to a three-phase AC network, and the electric motor performs linear translational movement and is made in the form of a three-phase linear induction motor, and the secondary element of a three-phase linear asynchronous motor is a rod, rigidly connected to the housing and located on the drive side, wherein the three-phase winding of the linear induction motor is connected to the output of the engine control system, an improvement of technical and economic indicators (reduced weight and dimensions, reduces the cost of the drive increases the reliability and performance of the classifier stebelnyh feed).

Figure 1 presents a diagram of the classifier of stalk feed. The invention is illustrated by the circuit shown in figure 1.

The stalk feed classifier comprises a housing 1 equipped with rollers 5 mounted on guides 6, a set of sieves 2 of trapezoidal cross-section, in the lower bases of which there are rectangular openings, obliquely mounted trapezoidal trays 3, obliquely mounted pitched boards 4, containers 10 for collecting separated stalk feeds, rod 7, rigidly connected to the housing 1 and located on the drive side, a spring 11 located on the opposite side of the drive, one end of which is connected to the housing 1, and the second end is closed captive on a fixed support, the engine control system 9, the input of which is connected to a three-phase AC network, a three-phase linear induction motor 8. A secondary element of a three-phase linear asynchronous motor is a rod 7, rigidly connected to the housing 1 and located on the drive side. The winding of a three-phase linear induction motor is connected to the output of the motor control system 9.

The classifier of stalk feeds works as follows.

The original stalk feed is fed through the upper part of the housing 1 to the upper sieve 2. The housing 1 is equipped with rollers 5 mounted on the guides 6, and driven in oscillation along the guides 6 by a three-phase linear induction motor 8, a spring 11 placed on the side opposite to the drive, one the end of which is connected to the housing 1, and the second end is mounted on a fixed support, and a rod 7, rigidly connected to the housing 1 and which is a secondary element of a three-phase linear induction motor 8. The operation of a three-phase line An induction motor is controlled by the engine control system 9, periodically supplying and disconnecting power to its winding according to the signal from the sensors of the position of the housing 1. When moving under the action of inertia arising from the oscillation of the housing 1, small stalk feeds pass through rectangular openings in the mesh 2 through the sieve 2 on an inclined pitched board 4, along which they slide into a container 10 to collect stalk feeds divided into fractions. The remaining part of the stalk feed, not divided into fractions, under the action of inertia forces arising from the oscillation of the housing 1, moves to the rear wall of the housing 1 and through the space between the rear wall of the housing 1 and the sieve 2 falls on an inclined trapezoidal tray 3, which rolls onto the next height of the housing 1 sieve 2 for further separation. This ends the first stage of separation into fractions of stalk feed. Further, the process of separation of stalk feed is repeated several cycles. Thus, at the end of the full cycle of the process of separation of stalk feed in containers 10 for collecting stalk separated into fractions stalk feeds of different sizes. The smallest feed fraction accumulates in the upper tank 10, and the largest feed fraction in the lower tank 10.

According to the theory of linear induction motors (Fridkin P.A. Gearless arc-controlled electric drive. - L.: Energy, 1970; Veselovsky ON, Konyaev A.Yu., Sarapulov F.N. Linear induction motors. - M.: Energoatomizdat, 1991. - 256 p.: Ill.) The velocity of the secondary element is determined by the expression

where τ is the pole division of the motor, m; f ₁ - the frequency of the AC voltage, Hz.

From (1) it follows that, due to the correct choice of the pole division value τ of a three-phase linear induction motor, corresponding to the required for this technological process of separation of the feed speed of the secondary element of a three-phase linear asynchronous motor into fractions of stalk feeds, an increase in the quality of separation and an increase in the performance of the classifier feed.

To convert the translational motion of a three-phase linear induction motor into the oscillatory motion of the stalk feed classifier body, the winding of the three-phase linear asynchronous motor is connected to the mains supply through the engine control system, and a spring fixed to the fixed support is connected to the body of the stalk feed classifier from the side opposite to the drive. When power is applied to the winding of a three-phase linear induction motor, it moves the traction together with the stern feed classifier housing, stretching the spring fixed to the housing. When the housing reaches the position set by the control system, the control system disconnects the winding of the three-phase linear asynchronous motor from the network by the signal of the position sensor. Due to the potential energy stored by the spring when moving the body of the stalk feed classifier, it returns to its original position, while a signal from the engine control system receives a signal to turn on the power to the winding of a three-phase linear induction motor. Next, the specified cycle of work is repeated. (Aipov R.S. Oscillating linear electric drive of machines in agricultural production // Mechanization and Electrification of Agriculture. - 2005. No. 11). Thus, the control system makes it possible to change the amplitude and frequency of oscillation by adjusting the moment of switching on and off the three-phase linear asynchronous engine.

It follows that it is possible to control the vibration frequency of the body of the classifier of stem feeds and to obtain such values of vibration frequencies at which the most intensive separation of the stern feed into fractions is achieved, which, in turn, can significantly improve the separation quality and throughput of the classifier of stem feeds ( Post-harvest seed treatment of grain crops: / VASKHNIL. - M .: Agropromizdat, 1986. - 44 pp., Ill. - b / c.). The need to change the frequency of oscillations of the body classifier of stalk feeds arises depending on the type, variety, moisture content of stalk feeds.

The presence in the kinematic diagram of the spring drive located on the side opposite to the drive, one end of which is connected to the housing and the other end is fixed on a fixed support, allows reducing the energy consumed from the network by returning the housing to its original position under the potential energy of the spring accumulated during moving, which improves the efficiency.

Due to the use of a three-phase linear induction motor in the stalk feed classifier, the secondary element of which is a thrust rigidly connected to the body and located on the drive side, the stalk feed classifier is directly driven. This simplifies the kinematic scheme of the drive, increases reliability and efficiency, reduces the weight, dimensions and cost of the classifier of stalk feed.

With this design of the stalk feed classifier, its kinematic drive scheme is simplified, weight, dimensions and cost are reduced, reliability, efficiency and productivity are increased.

Claims (1)

A stalk feed classifier comprising a housing equipped with rollers mounted on rails, a set of trapezoidal screens, in the lower bases of which are rectangular openings, obliquely mounted trapezoidal trays, obliquely mounted pitched boards, containers for collecting stalks divided into fractions, draft, rigidly connected with a housing and located on the drive side, an electric motor, characterized in that it is provided with a spring placed on the side opposite to the drive, one to the center of which is connected to the housing, and the second end is mounted on a fixed support, an engine control system, the input of which is connected to a three-phase AC network, and the electric motor performs linear translational motion and is made in the form of a three-phase linear asynchronous motor, and the secondary element of a three-phase linear asynchronous motor is traction rigidly connected to the housing and located on the drive side, while the winding of a three-phase linear induction motor is connected to the output of the systems s engine controls.