SU1058893A1 - Dearation column - Google Patents

Abstract

A DEAER COLUMN contains one jetting and bubbling plates installed one above: the other and a bypass device with a partition at one end facing the upper end of the body, characterized in that with the aim of increasing the maximum load and. compactness, the bypass device is made in the form / of a steam-emitting duct mounted above the jet tray with steam transfer nozzles under the water level on the jet tray, the vapor space of which is in communication with the space above the duct tubing of non-condensation gases, while the other end of the partition is adjacent to the upper the end of the box.

Description

This invention relates to heat energy engineering and industrial heat engineering / namely, to deaeration columns. A deaeration column is known, comprising a water dispenser, a bubbling plate and a drain cup; A bypass device built in the form of a hydraulic valve flooded with water at low loads is built into the plate. The disadvantage of such a device is the uneven distribution of steam in the liquid layer before it is fed to the bubble plate. Also known is a deaeration head, containing jet and bubble plates installed one above the other and bypassing devices with a partition 2J attached to one end of the upper end of the body. This design of the deaeration column is characterized by a number of shortcomings that do not allow to realize all the capabilities of the bypass devices. Steam bypass through known bypass devices does not provide uniform steam distribution in the fluid layer on the jet plate, which results in a small value of the contact surface and, therefore, small the magnitude of the coefficients of heat and mass transfer. When the bypass device is turned on, the steam breaks through its zone, adjacent to the partition walls, as a result of which local velocity of the vapor in the fluid and unacceptable mechanical discharge from the water distributor are created. This leads to exposure of the perforation, and ultimately to the disruption of the normal flow pattern, and a sharp deterioration in the performance of the deaeration column, as part of the contaminated water flows from the jet tray to the outlet of the column, mine jet compartment and even a bubbling plate. At the same time, the section of the jet tray, which coincides with the input section of the bypass device a couple, cannot be perforated, since in the mode with the bypass device running, this section is exposed, which contradicts the requirement of increasing the live section of the ink gun with increasing hydraulic load of the deaerating column . This, in turn, leads to an additional decrease in the maximum load of the apparatus and an increase in its dimensions. The purpose of the invention is to increase the ultimate load and compactness. This goal is achieved by the fact that in the deaeration column containing jet and bubbling plates installed one by one above the other and bypass device with a partition at one end to the upper end of the body, the bypass device is made in the form of a steam dispensing box with branch pipes installed above the top end of the body. steam bypassing the pore level of water. on a jet plate, the steam space of which is communicated with ripocTpaiicTBOM over a duct of non-condensable gas outlet tubes, with the other end of the partition rimykaet to the upper end of the box. FIG. 1 schematically shows a deaeration column, a longitudinal section J in FIG. 2 shows section A-A in FIG. 1. The deaeration column contains an inkjet plate 2 and a bubbling plate 3, one by one above the other, and a bypass device with a partition 4 adjoining one end to the upper end of the housing 1, the bypass device being made in the form of a steam dispensing duct 5c installed above the jet plate 2 nozzle b bypass steam under the water level on the jet plate 2. The vapor space of the jet plate 2 is in communication with the space above the duct 5 by the outlet 7 pipes of non-condensing gases, while the other end of the burner Heads 4 are adjacent to the upper end of the box 5. In addition, the deaeration column is installed on the accumulator tank 8, and the case 1 of the column is equipped with nozzles 9 and 10, respectively, of steam supply and exhaust vapor and a nozzle 11 for supplying deaerated water. Case 1 also contains a water drain device 12. The deaeration column operates as follows. The deaerated water flows through pipe 11 to the jet plate 2, from where it is jetted to the bubble plate 3 and then through the spillway device 12 to the tank accumulator 8. Heating steam is supplied to the housing 1 through pipe 9 under the bubble plate 3, on which the water is heated to saturation temperature and its final deaeration. Having passed through a layer of water on the bubble plate 3, the steam enters the mass condensation zone, where it condenses into water jets, which merge from the jet plate 2, thus preheating and coarse deaeration of water occur. The non-condensing steam and gas streams released during de-aeration are discharged from the housing 1. through the branch pipe 10 of the vapor outlet. As the load increases, the steam consumption increases and the pressure drop on the bubble plate 3 increases. Excess steam through the duct 5 through the nozzles 6 bypasses the floor to the water level on the jet

plate 2. At the same time, part of the steam condenses in water, heating it. Non-condensing steam from the vapor volume of the jet tray 2 through pipes 7 is withdrawn to the zone of mass condensation of the gift.

Placing the bypass device on the jet plate 2 will significantly increase the maximum permissible load of the deaeration column compared to structures in which the bypass device is placed at the level of the bubble plate, because the water level on the jet plate is always lower than the level of the bubble plate and rising slightly with increasing hydraulic load

 In addition, the placement of the bypass device on the jet plate serves as an additional independent step of steam transfer from the steam-conducting volume to the mass condensation zone. With such a steam supply, the required degree of uniform distribution of steam in the water layer on the jet tray 2 and the specified value of the contact surface of the phases is achieved, which will increase the intensity of heat and mass transfer processes. By equalizing the steam distribution after the ejection of the inkjet tray 2, the local steam velocities are reduced, the perforations in the steam passage zone are eliminated, and the maximum values of heat and mass transfer coefficients are provided, and consequently, the maximum throughput of the bypass device is increased.

Such an implementation device allows you to increase the ultimate load and compactness.

AND

Claims (1)

DEAERATION holding plates installed on top of another inkjet .. _______________ plates and a bypass device with one partition dipping one end to the upper end of the housing, characterized in that, in order to increase the maximum load and. of compactness, the bypass device is made in the form of a vapor-emitting duct installed above the jet this is the other end of the septum wall- § • "I Q Xia QO 00 GO I