RU1790545C - Ejector - Google Patents

Abstract

Usage: refers to vehicles, namely, devices for feeding pipeline transport, and can be used in installations for feeding powder materials, while improving the quality of the coating, expanding technological capabilities and improving the quality of the coating, expanding technological capabilities and reducing energy consumption. SUMMARY OF THE INVENTION: an ejector comprises a housing, c. The invention relates to vehicles, in particular to devices for feeding pipeline transport and can be used in installations for supplying powder materials to a sprayer. Closest to the invention is an injection dispenser, the disadvantage of which is that the shut-off element is made in the form of an adjusting nozzle, which compresses which is a receiving device with an opening for the transported material, a diffuser, a nozzle, an air duct and a shut-off element. The ejector is provided with an additional channel for supplying compressed air. The locking element is made in the form of an annular gap, the plane of which is located in the receiving device perpendicular to the axis of the hole. An annular gap is connected to an additional channel for supplying compressed air. The upper part of the receiver is movable relative to its lower part. The opening of the receiving device is made stepped in the cavity of the annular gap. The inner surface of the lower part of the receiving device is made curved. The annular gap is made at a height from the axis of the diffuser, determined from the ratio of 0.35 D h 0.5 D, where h is the distance from the axis of the diffuser to the annular gap; D is the diameter of the hole made in the receiving device between the annular slot and the hole for the transported material. 4 cp, fl, 3 ill. changing the flow cross section between the rod of the solenoid valve does not allow the use of powder paint as the material being transported, because when it is mechanically exposed to it by squeezing the elastic tube, it is compressed and clogs the conveying holes. In addition, this design of the shut-off element does not allow for remote and smooth adjustment of the flow rate.

Description

powder and receive a torch with the necessary dispersion, as well as regulate the torch when using powders of different granularities. This ejector is characterized by a large wear of the elastic tube due to the strong friction of the powder against its deformable, jet surface and frequent exposure of the electromagnetic valve stem to the tube material.

The purpose of the invention is to improve the quality of the coating, expand technological capabilities and reduce energy consumption.

This goal is achieved by the fact that in the proposed device comprising a housing with a receiving device for collecting transported material, a diffuser and a coaxially mounted nozzle fixed in the housing, an air shut-off element covering the receiving opening, air supply channels, according to the invention, an air shut-off element made in the receiving device in the form of an annular gap into which air is supplied through an autonomous air supply channel, providing smooth regulation, due to Neny flow rate and pressure of air sampling particulate material. The receiving device is made of two parts, between which there is a slot connected to an opening located in the receiving device; holes on different sides of the slit are made with different diameters, forming one stepped hole. The upper part of the device is mounted in the housing with the possibility of movement, provides a change in the live section of the slit during transportation of powder with different specific gravity. The lower part of the hole is made curved, and its height is determined from the dependence 0.35 D h 0.5 D, where D is the diameter of the hole in the cross section of the diffuser, h is the distance from the axis of the diffuser to the slit,

The slit in the receiving device is made perpendicular to the axis of the hole or at an angle with the conical hole.

Figure 1 shows a cross section of an ejector; figure 2 and 3 - schematically shows the interaction of air flows in the hole of the receiving device with full and partial overlap of the hole.

The ejector comprises a housing 1 with a receiving device made therein, which serves to collect the transported powder material from a container (not shown in the drawing), and consisting of upper 2 and lower 3 parts, a nozzle 4, a diffuser 5, mounted on the housing 1, and - Spirit supply channels b, 7 for supplying conveying air to the nozzle 4 and supplying guide air to the annular

slots 8, located between the upper 2 and lower 3 part of the receiving device, made with holes 9, forming a ledge in the plane of the slit 8, Moreover, the inner surface of the upper part 3 of the receiving

The device is curved, and its height is determined from the ratio of 0.35 D h 0.5 D, where D is the diameter of the hole 9, and h is the distance from the axis of the diffuser 5 to the annular gap 8.

The lower part of the receiving device is fixed in the housing 1 motionless, and the upper part 2 is fixed in the housing 1 by means of a thread 10 and can be adjusted relative to the lower part of the magnification

or reducing the live section of the annular gap 8.

Along the periphery of the annular gap 8, an annular groove 11 is made in the housing 1, which serves as a surge chamber for the control air. The annular gap 8 is made in a plane perpendicular to the axis of the hole 9.

The annular gap 8 in combination with the hole 9 when compressed air is supplied to it

serves as an air shutoff element for the ejector, regulating the flow of powder materials into the cavity 12.

The ejector works as follows.

Through channel 7, a compressed ejector is fed into the ejector.

air: which, exit through the annular gap

8. is separated in hole 9 into streams A and B,

The air flow L creates a backwater and

will prevent the ingress of powder material into the cavity 12, and the air stream B purges the cavity 12 and the diffuser 5 from the remaining powder. After the compressed air is supplied through the channel 6 and the pressure and flow rate of the air supplied through the channel 7 are reduced

the air flows A and B are combined and directed into the cavity 12, smoothly bending around the curved inner surface of the hole 9 of the lower part 3 of the receiving device. Such organization of air flows A and B, depending on pressure and flow rate, will in a wide range regulate the intake (suction) of powder materials from the container (not shown in the drawing) until the bore 9 is completely blocked.

The use of powders with different fineness and specific gravity is carried out by raising the upper part 2 of the receiving device and increasing the living cross section of the annular gap 8.

The execution of the hole 9 stepwise on the plane of the annular gap 8 contributes to a more efficient operation of the air flow A while blocking the hole 9, and the curved surface of the lower part 3 increases the stability of regulation

feeding the powder material into the cavity 12. An annular slot 8 is formed perpendicular to the axis of the opening 9 and improves the control efficiency with less air consumption.

Claims (5)

1. An ejector comprising a housing, in which a receiving device with an opening for the transported material, a diffuser, a nozzle, an air supply channel and a shutter element are formed. This is inherent in that, in order to improve the quality of coatings, expand technological capabilities and reduce energy consumption, the ejector is provided with an additional channel for supplying compressed air, the locking element is made in the form of an annular gap, the plane of which is located in the receiving device perpendicular to the axis of the hole, and the annular gap is connected a can with an additional channel for supplying compressed air. 2. The ejector according to claim 1, characterized in that the upper part of the receiving device is movable relative to its lower part. 3. An ejector according to claim 1, characterized in that the opening of the receiving device is stepped in the cavity of the annular gap. 4. An ejector according to claim 3, characterized in that the inner surface of the lower part of the receiving device is curved. 5. Ejector according to claims 2 and 3, characterized in that the annular gap is made at a height from the axis of the diffuser, determined from the ratio of 0.35 D h 0.5 D, where h is the distance from the axis of the diffuser to the annular gap, D - the diameter of the hole made in the receiving device between the annular gap and the hole for the transported material. Figl FIG. 2 Fie.Z