SU935678A1 - Apparatus for drying gas - Google Patents

Description

The invention relates to techniques for gas processing.

A device for drying a gas is known, comprising a housing with nozzles for supplying and discharging cold and warm moist gas streams and a multisectoral rotor with a nozzle in each section and gas distribution chambers located on different sides of the rotor and forming with sections and. pipes for the movement of each of the gas flows against the direction of rotation of the rotor [l].

The disadvantage of this device is the low operational reliability.

This is due to the fact that the moisture that has fallen from the heat of the moist gas gas stream during further rotation of the rotor partially freezes on the surface of the nozzle.

The purpose of the invention is to increase operational HaflewHOQTH when performing a rotor with a purge section.

The goal is achieved in that two adjacent gas distribution chambers of the channel of the heat of the wet gas flow, located on one side of the rotor, are interconnected by means of an air duct with a moisture separator located in it, and the pipe for removing the heat of the wet gas stream is connected by two bypass channels, respectively, to the pipe for supplying a cold gas stream and through the purge section of the rotor with a pipe for supplying a heat-free gas stream.

The drawing shows a schematic diagram of the proposed device ₂₀ device.

A device for drying gas contains a housing 1 with nozzles 2, 3, 4, 5 for supplying and discharging cold and warm moist gas streams

935678 4 and a multi-section rotor 6 installed in the housing I with a nozzle in each section and gas distribution chambers 7, 8 located on opposite sides of the rotor 6, forming channels 5 with sections and nozzles

9, Yu for the movement of each of the gas flows against the direction of rotation of the rotor. Two adjacent gas distribution chambers 11, 12 canal 10 la 10 of the heat moist gas stream located on one side * of the rotor 6 are interconnected by means of an air duct 13 with a moisture separator 14 located in it, and 15 pipe 5 for the removal of the heat moist gas stream connected via two bypass channels 15, 16, respectively, to a pipe for supplying a cold gas flow 20 and through a purge section 17 of the rotor 6 to a pipe 4 for supplying a moist heat gas stream.

In addition, the device is equipped with 25 air cooler 18, an intercooler 19, fans 20, 21.

The device operates as follows. thirty

Warm moist gas flow through the pipe 4 protrudes into the channel

10. In contact with the nozzle of the rotor 6, which has a temperature below the dew point temperature, the heat moist _J5 gas stream is dried and cooled.

Concentrated moisture is discharged from the rotor sections by a gas stream and separated from the gas stream in a moisture separator ₄₀ 14. The gas stream freed from suspended moisture flows again into the rotor sections having a negative temperature. In these sections warm moist _4b vy gas stream is cooled and dehumidified to desired values, and through the pipe 5 is supplied to the consumer.

The moisture that has fallen out of the warm moist gas stream and has frozen on the surface of the nozzle thaws upon rotation of the rotor 6 in the indicated direction.

In order to avoid the entry of warm moist air into the cold gas stream channel 9, part of the drained cooled thermal wet gas stream is supplied via the bypass channel 16 to the purge section

17. Bypass channel 16 allows you to coordinate and stabilize the pressure of both gas streams. The cold gas stream to the device can be supplied from the cooler 18 and the intermediate cooler 19 and, depending on the specific application conditions of the device, may have a closed circulation circuit.

Introduction to the device of the moisture separator 14 and the bypass channels 15, 16 can improve operational reliability.

Claims (1)

This invention relates to a gas treatment technique. A device for drying is known, comprising a housing with connections for supplying and discharging cold and warm humid gas flows and a multistage mounted rotor in the housing with a nozzle in each of the sections and located on different sides of the rotor distribution chambers with sections and. The nozzles channels for the movement of each of the gas flows against the direction of rotation of the rotor. The discharge of this device is low operational reliability. This is due to the fact that the moisture discharged from the thermal moist gas flow during the further rotation of the rotor partially freezes on the surface of the nozzle. The purpose of the invention is to increase the operational reliability when performing a rotor with a blowing section. The goal is achieved by the fact that two adjacent gas distribution chambers of a thermal humid gas flow channel located on one side of the rotor are interconnected by means of an air duct with a moisture separator located in it, and a branch pipe for diverting thermal moist gas flow is connected via two bypass channels, respectively for the supply of cold gas flow and through the purge section of the rotor with a pipe for the supply of thermal moist gas flow. The drawing shows a schematic diagram of the proposed device. The device for gas drying comprises a housing 1 with nozzles 2, 3,, 5 for supplying and discharging cold and warm moist gas streams 3 and a multi-section rotor 6 mounted in housing 1 with a nozzle in each of the sections and located on different sides of the rotor 6 gas distribution chambers 7, 8, forming with sections and nozzles channels 9, 10 for moving each of the gas flows against the direction of rotation of the rotor. Two adjacent gas distribution chambers 11, 12 10 of the thermal moist gas flow, located one side of the rotor 6, are interconnected by means of an air duct 13 with a partitioned water separator I in it, and a branch pipe 5 for diverting the thermal moist gas flow is connected by two bypass channels 15, 16, respectively, with a pipe 2 for supplying a cold gas flow and through the purge section 17 of the rotor 6 - with a pipe for supplying a heat-moist gas flow. In addition, the device is equipped with an air cooler 18, between an exact cooler 19, and fans 20, 21. The device works as follows. A warm humid gas stream through port k protrudes into channel 10. With thermal contact with the rotor nozzle 6 having a temperature below the dew point temperature, the thermal wet gas stream is dried and cooled down. The concentrated moisture from the gas flows out of the rotor sections and is separated from the gas flow in the dehumidifier 1. The gas flow released from the suspended moisture enters the rotor sections again, having a negative temperature. In these sections the warm moist gas flow is cooled and dried to the required values and through patra side 5 comes to the consumer. Having dropped out of the warm humid gas flow and frozen on the surface of the nozzle, when the rotor 6 rotates in the indicated direction, it thaws. In order to prevent warm humid air from entering the cold gas flow channel 9, a part of the dried cooled thermal wet gas flow is supplied through the bypass channel 16 to the purge section 17. Bypass channel 16 allows the pressure of both gas flows to be adjusted and stabilized. The cold gas flow to the device may be supplied from the cooler 18 and the intermediate cooler 19 and, depending on the specific conditions of use of the device, may have a closed circulation loop. The introduction of moisture separator 1 and bypass channels 15, 16 into the device makes it possible to increase operational reliability. Apparatus of the Invention A gas drying device comprising a housing with nozzles for supplying and discharging cold and warm moist gas streams and a multi-section rotor installed in the housing with a nozzle in each of the sections and gas distribution chambers located on opposite sides of the rotor forming with the sections and nozzles channels for moving each of the gas streams against the direction of rotation of the rotor, characterized in that, in order to increase operational reliability when the rotor is performed with the blowing section, two cm The hot gas distribution chambers of the warm humid gas flow channel located on one side of the rotor are interconnected by means of an air duct with a moisture separator located in it, and the branch pipe for diverting the warm moist gas flow is connected via two bypass channels respectively to the cold gas flow nozzle and through purge section of the rotor with a pipe for supplying a warm moist gas stream. Sources of information taken into account in the examination 1. USSR author's certificate in application No. 290.83.BES / 29-04, cl. F 2k F 5/00, 1980.