KR101184616B1 - Difference pressur equalizing of deaerator for generating boiler - Google Patents

Abstract

The present invention relates to a multi-stage degassing apparatus for improving the tray module structure inside the degassing apparatus and relieving the occurrence of differential pressure, thereby improving degassing performance and operational reliability, and the present invention provides a water supply chamber installed inside the degassing apparatus, and the water supply chamber. A spray valve connected to the spray valve for spraying water downward, a spray space formed below the spray valve, a primary tray module installed below the spray space, a reheating zone partitioned below the primary tray module, and the reheat The differential pressure bypass passage for inducing a differential pressure upward by connecting a zone and a spray space, a secondary tray module installed below the reheating zone, and a steam supply device installed below the secondary tray module are combined. High-efficiency degassing unit consisting of secondary and secondary tray modules, spray zone and reheat zone It is characterized by the configuration of the discharge control device for a sudden differential pressure generated from this.

Description

DIFFERENCE PRESSUR EQUALIZING OF DEAERATOR FOR GENERATING BOILER}

The present invention relates to a differential pressure control device for a deaerator for a boiler used in a power generation facility. More specifically, in order to improve the performance and operation reliability of a deaerator, a tray module inside the deaerator is formed in a multi-stage deaeration structure and a spray zone and It relates to the improvement of degassing performance by mitigating the differential pressure generated between reheating zones.

Since the water supplied to industrial boilers used in power generation facilities and chemical factories contains oxygen and gas, if water is used as it is, it will impede the production of steam or hot water. There is a problem that the service life is shortened, and in order to solve such a problem, a deaerator for removing water and oxygen contained in the water supply is used in a water supply system of an industrial power generation system.

The degasser is composed of a degassing heater for degassing the fluid (water) and a storage tank for storing the degassed fluid, and serves to degas the fluid by using a spray valve and a tray stack assembly inside the degassing apparatus.

In a typical deaerator, as shown in FIGS. 1 and 2, high temperature steam in which water injected from the spray valve 3 of the water supply chamber 2 installed above the main body 1 is injected upward from the lower steam supply nozzle 9. After the primary degassing while being guided to the saturation state by a plurality of trays (5) is passed through the tray module 6 installed in a zigzag stacked stack, secondary degassing by the induction of a micro-film and spray valve (3) and tray ( 5) The oxygen and gas are separated by direct contact of water and steam through the medium, and the separated oxygen and gas are discharged into the atmosphere through the exhaust pipe.

Degassing apparatus is originally a plurality of tray assemblies are stacked in a uniform form to increase the contact area and time with the fluid and heating steam to induce degassing action, the internal structure of the conventional degassing apparatus using a spray valve and tray The degassing and water supply is heated by the two-stage contact method in which steam and water are in direct contact. Therefore, the two-stage contact method using only the spray and the tray has a short contact time for efficient degassing of the water supply, and the contact area to be separated by hitting. There was also a problem that the degassing performance of the water supply is not enough.

In particular, in a large number of power plants and plants, initial loads and changes in deaeration are often generated during sudden start-up, start-up, and operation of the deaerator. As a result, instantaneous differential pressure is generated inside the deaerator. Increasing pressure often causes damage to the tray box.

In the conventional deaerator structure, since the differential pressure cannot be effectively processed, there is a problem that the tray box is damaged due to the differential pressure and the deaerator performance is deteriorated. Therefore, the technical of the deaerator is used to improve the performance and operation reliability of the existing deaerator. There is a need for improvement.

An object of the present invention is to provide a multi-stage degassing apparatus having a new structure to improve the tray module structure inside the degasser and to relieve the differential pressure generated between the spray zone and the reheat zone to improve the degassing performance and operation reliability.

In order to achieve the above object, the present invention provides a water supply chamber installed inside the degasser, a spray valve connected to the water supply chamber for spraying water downward, a spray space formed below the spray valve, and installed below the spray space. A primary tray module, a reheating zone partitioned below the primary tray module, a bypass discharge passage connecting the reheating zone and the spray space to direct differential pressure, and a secondary tray installed below the reheating zone. The module and the steam supply device installed below the secondary tray module are combined to form a multi-stage degassing structure having a high efficiency degassing performance formed by combining the primary and secondary tray modules, and between the spray zone and the reheat zone. It is characterized in that it is possible to prevent the breakage of the tray box by reducing the sudden pressure generated.

The present invention is to form a degassing device in four stages to significantly improve the performance and operation reliability of the deaerator and to discharge the differential pressure generated during the deaerator operation process between the primary and secondary tray modules so that the internal mechanism due to the differential pressure generation It is possible to prevent the damage of the degassing can be expected safe operation.

1 is a side view showing the configuration of a conventional degasser
Figure 2 is a longitudinal cross-sectional view of a conventional degasser
Figure 3 is a cross-sectional configuration of the main technology of the present invention

According to the present invention, a plurality of spray valves (3) spraying water downwardly are installed in a water supply chamber (2) installed above the degassing main body (1), and the spray space (4) formed below the spray valve (3) is provided. The tray module 6 having a plurality of trays 5 arranged at a lower side thereof is installed, and a degassing apparatus having a steam supply nozzle is installed at the bottom thereof.

The present invention comprises a reheating zone (7) partitioned below the tray module (6) of the degassing apparatus; A bypass discharge passage 8 connected between the reheating zone 7 and the spray space 4 and inducing a differential pressure upward; A secondary tray module 10 installed below the reheating zone 7; By combining with the steam supply nozzle 9 installed below the secondary tray module 10 to form a multi-stage degassing apparatus having a high efficiency degassing performance is formed by combining the primary and secondary tray modules up and down, It is characterized by preventing the breakage of the tray box by controlling the discharge of the differential pressure rapidly generated between the spray zone and the reheating zone.

The bypass discharge passage 8 is installed outside the main body, and the lower end 11 is connected to the side wall of the reheating zone 7, and the upper end 12 is connected to the side wall of the spray space 4 so that the differential pressure generated from the lower side is transferred to the outside. Through the exposed bypass discharge passage 8 is introduced into the upper spray space (4) is to be discharged to the exhaust port (13).

In the present invention, the water supplied through the water supply chamber and the spray valve (3) is widely sprayed downward in the spray space (4) is provided to the primary tray module (6), the sprayed water supply to the primary spray module (6) During the passage, the water and the non-condensable gas are separated into the primary separated state and re-separated secondly from the secondary tray module 10 through the reheating zone (7), and then the water is discharged to the storage tank through the lower drain. .

In the degassing process, the reheating zone 7 maintains a high temperature atmosphere by the high temperature steam pressure injected from the steam nozzle, so that the water falling from above and the non-condensable gas are reheated in the reheating zone 7, the second tray module 10. Degassing is effectively performed during the passage.

In addition, in the degassing process, the non-condensable gas separated from the water is minimized to be re-dissolved by the falling water from the upper primary tray module, and the differential pressure rapidly generated in the degassing section and the spray zone immediately bypasses the bypass passage (8). After discharged upward through the spray space (4) is discharged to the outside through the exhaust port (13).

The present invention is to install the secondary tray module 10 in the lower portion of the primary tray module 6 compared to the conventional degassing configuration limited to the spray zone and the primary tray module and the primary, secondary tray module (6) By partitioning the reheating zone (7) between (10), the degassing action in four stages greatly improves the performance.

1: deaerator main body
2: water supply chamber
3: spray valve
4: spray space
5: tray
6: 1st Tray Module
7: reheating zone
8: bypass discharge passage
10: secondary tray module

Claims (2)

A water supply chamber 2 for supplying water provided on the upper side of the degasser main body 1; A plurality of spray valves 3 connected to the water supply chamber 2 for spraying water downward; A spray space 4 formed below the spray valve 3; A primary tray module 6 installed below the spray space 4 and having a plurality of trays 5 stacked thereon; A reheating zone (7) partitioned below the primary tray module (6); A bypass discharge passage 8 for inducing a differential pressure upward as a tube connecting the reheating zone 7 and the spray space 4; A secondary tray module 10 installed below the reheating zone 7; The steam supply device 9 installed below the secondary tray module 10 is configured to be coupled to form a multistage degassing device formed by installing the first and second tray modules up and down, and is rapidly generated between the spray zone and the reheat zone. A differential pressure control device for a deaerator for a power generation boiler, comprising a device for discharging a differential pressure and a gas.
2. The differential pressure control device according to claim 1, wherein the bypass discharge passage (8) connected between the reheating zone (7) and the spray space (4) is installed on both sides of the main body.

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