SU1210691A1 - Pneumatic batcher of piece items - Google Patents

Description

The invention relates to agricultural machinery, in particular, to sowing machines, and can be used in the dosing of piece goods.

The aim of the invention is to improve the accuracy of the orientation of objects, speed and reliability of the process.

The drawing shows the diagram of the dispenser.

The dispenser contains a transport pipeline 1 with a feeder 2, a source of compressed air (not shown), an inkjet sensor 3 indicating the flow of objects with a chamber 4 and a channel 5 connected to the channel 6 of the control of the jet amplifier 7,

output channel 9. From the channel of the annular nozzle 14 air enters the pipeline 1 and accelerates the flow of objects into the zone of the sensor 3. At the same time, the pressure from the chamber 12

c through channel 16 and amplifier 17 is supplied to nozzle 18, a jet from which, through opening 19, delivers objects to pipeline 1. Passing - w, objects passing from sensor 3 screen the stream flowing from it, and part of the dynamic pressure acts through channels 5 and 6 to the stream flowing from channel 8 and directs to the output channel 10. Through the tank 11, the chamber 13, the air flows from the nozzle 15 into the atmosphere, entraining the air from the pipeline 1. Part of the pipeline 1 to the zoomer-in entrance channel 8 and the output nozzles, 5 and 15 performs the function of mixtures 9 and 10, the latter is included emkosttelnoy ejector chamber. The flow rate is 11. On the pipeline there is a jet stream from the nozzle 15 which determines the great actuator in the form of two-dilution in the pipeline I. Adjacently arranged chambers 12 and 13. Thus, on the objects alternately by ring nozzles 14 and 15, the pulses aerodynamic at an angle to the pipeline. Camera 12 ka-20 forces in different directions. From aerodynamics, the nalom 16 through the amplifier 17 is connected to the well-known that when the bodies move, any formative jet actuating mechanism in the form of a nozzle 18 located in the zone of the feeder 2 opposite the metering window 19.

To eliminate the removal of objects in the pipeline is the grid 20.

The dispenser works as follows.

In the absence of objects in the pipeline 1, the air from the chamber 4 of the sensor 3 freely flows into the cavity of the pipeline and, due to the ejection effect, creates a vacuum in the channel 5, which through the control channel 6 of the amplifier 7 acts on the air stream flowing out of the channel 8 and directs it to output channel 9 and camemes in a gaseous medium (liquid), they are oriented so as to have the least resistance. As a result of the influence of the alternating aerodynamic forces, the objects occupy a stable position, having a center of mass in the direction of the force of gravity.

Discrete automatic control system with an additional nozzle 18 synchronizes the process of supplying objects and their orientation, which improves the quality of the process, and the absence of moving parts simplifies the design and increases its reliability. Orientation quality

determined by amplitude, frequency and well 12. Sensor 7 is single-stable, 35 pulse. The capacity And regulates - i.e. The jet from channel 8 is stably supplied with a cycle time.

output channel 9. From the channel of the annular nozzle 14 air enters the pipeline 1 and accelerates the flow of objects into the zone of the sensor 3. At the same time, the pressure from the chamber 12

through the channel 16 and the amplifier 17 is fed into the nozzle 18, the jet from which, through the opening 19, delivers objects into the pipeline 1. The passage - w, past the sensor 3 objects shield the stream flowing from it, and part of the dynamic pressure through the channels 5 and 6 affects the outgoing From channel 8 a jet and directs it to outlet channel 10. Through tank 11, chamber 13, air flows from nozzle 15 into the atmosphere, drawing air from pipeline 1. Part of pipeline 1 to nozzles 14 and 15 functions as a mixing ejector chamber. The flow rate of the jet from the nozzle 15 determines the magnitude of the vacuum in the pipe I. Thus, the objects are alternately affected by pulses of aerodynamic forces of different directions. It is known from aerodynamics that when bodies move, any form of nozzles 14 and 15 performs the function of a mixing ejector chamber. The flow rate of the jet from the nozzle 15 determines the magnitude of the vacuum in the pipe I. Thus, the objects are alternately affected by pulses of aerodynamic forces of different directions. It is known from aerodynamics that when bodies move, any form

we are in a gaseous environment (liquid), they are oriented so as to have the least resistance. As a result of the influence of alternating aerodynamic forces, the objects occupy a stable position, having a center of mass in the direction of the force of gravity.

Discrete automatic control system with an additional nozzle 18 synchronizes the process of supplying objects and their orientation, which improves the quality of the process, and the absence of moving parts simplifies the design and increases its reliability. Orientation quality

is determined by the amplitude, frequency and duty cycle of the pulses. Capacity And regulates, with the duration of the cycle.

Claims (1)

PNEUMATIC PIECE OF PIECES, containing a transport pipeline in communication with a feeder having a metering window, and an actuator connected through a jet amplifier with a jet sensor for indicating the density of the articles, and a source of compressed air, characterized in that, in order to improve the accuracy of orientation of objects , speed and reliability of the process, it is equipped with an additional inkjet actuator and amplifier, with an additional actuator located lies in the area of the feeder opposite the dispensing window and is connected by a feedback channel through amplifiers and an actuator with an inkjet density indication sensor, while the actuator is made in the form of two adjacent flow chambers with annular nozzles that are located at an angle to the pipeline. Q <p