RU2115462C1 - Gas cleaning device - Google Patents

Abstract

FIELD: any industry where cleaning of gas flow is required; chemical and food-processing industries in particular. SUBSTANCE: gas cleaning device has housing with tangential in branch pipe, atomizer, outlet branch pipe, drip pan and liquid discharge pipe line. Atomizer is made in form of hollow taper sleeve provided with disk in its upper portion rigidly connected with cylinder through delivery branch pipe with outlet valve inside it. Cylinder is provided with piston linked with connecting rod by means of pin; connecting rod is mounted on crankshaft located in lower portion of housing. Shaft opposite inlet branch pipe is provided with impeller with spring. EFFECT: enhanced efficiency. 2 dwg

Description

 The invention relates to wet cleaning of gases from impurities and can be used in any industry where cleaning of the gas stream is required, in particular in the chemical and food industries.

 A device for wet gas cleaning, including a housing with an outlet pipe and a droplet eliminator, a hopper receiver with an outlet and inlet pipes. A shaft with a spray element in the form of blades and a bowl with a pipe for supplying liquid are coaxially located in the housing.

 The disadvantage of this device is the need for energy for the rotation of the spray element, a constant flow of cleaning fluid and high hydraulic resistance.

 An object of the invention is to reduce the consumption of cleaning fluid and save energy.

 The task is achieved in that the device includes a housing with a tangential inlet pipe, a spray, an outlet pipe and a droplet eliminator, a pipe for draining the liquid. What is new is that the atomizer is a hollow conical cup having brackets on the upper part on which the disk is mounted, while the atomizer is rigidly connected to the cylinder through the discharge pipe, inside which there is an exhaust valve, the cylinder being equipped with a piston, which is connected by means of a finger to a connecting rod mounted on the crankshaft located in the lower part of the housing, while the shaft from the inlet pipe side is equipped with an impeller with a spring, an additional pipe for supplying fluid a tee inside which there is an exhaust valve and a nozzle for adjusting the liquid level, and the outlet nozzle and droplet eliminator are located coaxially with the body.

 In FIG. 1 shows the proposed device for gas purification, a longitudinal section; in FIG. 2 is a section AA in FIG. one.

 The device comprises a housing 1 with an inlet pipe 2 and an outlet pipe 3.

 A nozzle 4 (not shown) is coaxially mounted in the housing 1, and is rigidly connected to the cylinder 5 through the discharge pipe 6. Inside the discharge pipe 6 there is an exhaust valve 7.

 The sprayer is a hollow conical glass 8, having in the upper part of the brackets 9, on which the disk 10 is mounted.

 The cylinder 5 is equipped with a piston 11, which is connected to the connecting rod 12 by means of a finger 13. The connecting rod 12 is mounted on the crankshaft 14, which is located in the lower part of the housing 1. An impeller 15 with a spring 16 is also located on the crankshaft 14.

 A pipe 17 is connected to the cylinder 5 for supplying liquid, inside of which there is an inlet valve 18.

 On the housing there is also a pipe 19 for adjusting the liquid level and a pipe 20 for draining the liquid. The outlet pipe 1 is provided with a droplet eliminator 21.

 The device operates as follows.

 Contaminated gas flow through the inlet pipe 2 is supplied to the housing 1, driving the impeller blades 15. This leads to the rotation of the crankshaft 14 and the movement of the piston 11 in the cylinder 5 by means of the connecting rod 12 and pin 13.

 During the movement of the piston 11 down in the cavity of the cylinder 5 creates a vacuum. In this case, the exhaust valve 7 is locked, and the inlet valve 18 is unlocked, and the cleaning fluid from the hopper of the housing 1 through the pipe 17 for supplying fluid is sucked into the cavity of the cylinder 5.

 When the piston 11 moves up, the inlet valve 18 closes, and the exhaust valve 7 is unlocked, and the cleaning liquid under the pressure of the piston 11 is supplied to the discharge pipe 6, and from there to the spray gun. On the inner surface of the glass 8, the water rises, hits the disk 10 and is sprayed into the internal cavity of the housing 1.

 In the lower part of the body under the action of centrifugal forces, large particles are separated from the dust and gas stream. Then the untwisted stream rises and enters the spray zone, where it is mixed with the liquid sprayed by it. In this case, coagulation of dust particles and the acquisition of hydrophilic properties by them occurs, one hundred leads to intensive dust collection.

 Enlarged and moistened dust particles together with the cleaning liquid flow down the inner surface of the housing, and the purified gas passes through a droplet eliminator 21 and is removed through the outlet pipe 3.

 Compared with the prototype, while maintaining the intensity of interaction of the dust and gas stream with the liquid, due to self-irrigation, the consumption of the cleaning liquid is reduced and additional energy costs are saved.

Claims (1)

 A device for wet gas purification, comprising a housing with a tangential inlet pipe, a spray, an output pipe and a droplet eliminator, a pipe for draining liquid, characterized in that the spray is made in the form of a hollow conical cup equipped with a disk in the upper part, rigidly connected to the cylinder through the discharge pipe inside which there is an exhaust valve, while the cylinder has a piston connected by a finger to the connecting rod mounted on the crankshaft located in the lower part of the housing, the shaft By contrast impeller inlet is provided with a spring, the apparatus is provided with a liquid supply pipe, inside which is situated an inlet valve and nozzle for adjusting the liquid level and the outlet and the drip tray arranged coaxially housing.

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