SU1023155A1 - Fluidic inverting vacuum amplifier - Google Patents

Abstract

JET INVERTER VACUUM AMPLIFIER, containing a receiving and feeding capillary, strengthened with a gap, and controlling a capillary, perpendicular to the feeding capillary, characterized in that, in order to simplify the design and improve its manufacturability, the receiving and feeding capillary. coaxial, the control capillary closes the outlet opening of the supply capillary by a value of 0.1-0.6 times the diameter of this opening, and the gap between the supply and the reception capillaries is equal to the outer diameter of the control cap ill.

Description

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. This invention relates to automatic control and can be applied in pneumatic automation systems. A known inverse jet amplifier, whose action is based on the separation of the boundary layer from the wall, contains a power channel, two output channels angled to each other and two control channels arranged at right angles to the power channel 1. Such amplifiers are widely used in engineering controls and controls, but are characterized by a relay characteristic, are not sensitive to signals in the vacuum area, and have a large flow of supply air. Most proposed is an inkjet inverse vacuum booster containing a receiving and feeding capillaries, reinforced with a gap, and a control capillary located perpendicular to the supply capillary 2. The control of such an amplifier can be carried out using negative pressures 2. However This amplifier is characterized by the complexity and low-tech design. The purpose of the invention is to simplify the design of an inkjet inverse amplifier controlled by negative pressures, and to improve the manufacturability of its fabrication. The supply and supply capillaries are made in conjunction with a 4fO axially, the controlling capillary covers the outlet opening of the supplying capillary 0.1-0.6 times the diameter hole, and the size of the gap between the feeding and receiving capillaries is equal to the outer diameter of the controlling capillary. FIG. 1 shows a jet inverse amplifier; in fig. 2 and 3 show the direction of flow in the amplifier when the control signal changes. The jet inverse amplifier contains rigidly fixed coaxially arranged with a gap D supplying 1 and receiving 2 capillaries and located perpendicularly controlling a capillary 3 with an outer diameter D. The jet inverse amplifier works as follows. The supply pressure is supplied to the supplying capillary p 1, the gas that flows from the supplying capillary 1 strikes the wall of the controlling capillary 3 at the outlet of the supplying capillary, part of it falls into the receiving capillary 2 and creates some dynamic pressure (most) is discharged into the atmosphere through the gap between capillaries 1 and 2. With an increase in the vacuum in the control capillary 3, the part of the flow entering the receiving capillary r 2 increases, the dynamic head (PIDM) increases. This is due to the attraction of the jet to the end wall of the controlling capillary, pa 3. The technical and economic effect from the introduction of the proposed jet inverse amplifier consists in a significant reduction in the cost of pneumatic control systems

Claims (1)

A JET INVERSE VACUUM AMPLIFIER containing a receiving and supplying capillaries fixed with a gap and a control capillary located perpendicular to the supplying capillary, characterized in that, in order to simplify the design and increase its manufacturability, the receiving and supplying capillaries are made coaxial, the control capillary the outlet opening of the supply capillary is 0.1–0.6 times the diameter of this hole, and the gap between the supply and receiving capillaries is equal to the outer diameter of the control capillary . SU ..,. 1023155