KR20180047994A - Steam generator with condensation-water recovery device - Google Patents

Abstract

The present invention relates to a steam generator having a condensed water collecting container. According to the present invention, the steam generator comprises: a pre-heating tank for heating water; a heating tank in which the water heated in the pre-heating tank is sprayed in a hot pressed shaped; a collecting container for collecting the condensed water discharged from the heating tank; a condensed water collecting line connecting the heating tank to the collecting container; and a condensed water transporting line for transporting the condensed water from the collecting container to the heating tank. Therefore, according to the present invention, the steam generator can collect the entire condensed water while forming a sealed circuit without causing loss of re-evaporated steam and condensed water so that the present invention can be operated at affordable price according to maximization of efficiency in energy usage.

Description

STEAM GENERATOR WITH CONDENSATION-WATER RECOVERY DEVICE,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a steam generator having a condensate recovery container, and more particularly, to a steam generator that recovers condensate generated while passing through a heater and preheats supplementary water to improve energy utilization efficiency.

Generally, in installations where steam supply is required, the water is heated by the boiler to generate steam. In order to generate steam in the boiler, it is necessary to heat the feed water to the boiling point corresponding to the steam generation pressure, so that the higher the temperature of the initially supplied water, the more fuel can be saved.

Generally, when the feed water temperature rises by 6 ° C, the fuel consumption is reduced by about 1%. Also, the boiler feed water is treated chemically, but the condensed water is chemically stable distilled water, so it can be recycled as boiler feed water without additional chemical treatment. Therefore, condensate can be reused as boiler feed water after recovery in that it can reuse the calorific value and does not need separate water treatment.

Korean Patent No. 10-0898380 (re-evaporation steam and condensate recovery device) Korean Registered Utility Model No. 20-0400868 (Condensate Recovery of Closed Circuit Circulation Steam Boiler)

Accordingly, it is an object of the present invention to provide a steam generator capable of operating economically by maximizing the efficiency of energy utilization by recovering the entire amount of condensed water without causing loss of re-evaporated steam and condensed water in the state where the closed circuit is constituted .

According to an aspect of the present invention, there is provided a steam generator comprising: a preheating tank for heating water; a heating tank in which water heated in the preheating tank is injected in the form of a heated seawater; A condensate water collection line connecting the heating tank and the recovery container, and a condensate water transportation line for transferring condensate water from the recovery container to the preheat tank.

Preferably, the recovery container includes a water level sensor, and when the water level of the condensed water in the recovery container exceeds a predetermined water level, the water level sensor senses the water level, operates the circulation pump installed in the condensate water conveyance line, And conveys the condensed water in the recovery container to the preheat tank.

The condensed water recovering apparatus according to the present invention has the effect of economical operation by maximizing the efficiency of energy utilization by using all the recovered condensed water without generating loss of re-evaporated steam and condensed water in the state of constituting the closed circuit.

FIG. 1 is a configuration diagram showing a steam generator including a condensate recovery device according to an embodiment of the present invention.
Fig. 2 is a view showing the heating heater shown in Fig. 1. Fig.
3 is a detailed perspective view of the heating heater shown in Fig.
FIG. 4 is a view for explaining a state of separation of steam and condensed water by the separation membrane shown in FIG. 1. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

FIG. 1 is a configuration diagram showing a steam generator 10 including a condensate recovery device according to an embodiment of the present invention. 1, the steam generator 10 includes a water supply source 170, a preheat tank 140, a high pressure pump 150, a heating tank 100, a recovery vessel 120, a condensate collection line 110 ), And a transportation line (130). In this embodiment, the condensate recovery is implemented as a recovery vessel 120, a condensate recovery line 110, and a transportation line 130.

1, the condensate recovery line 110 is disposed between the heating tank 100 and the recovery container 120 and conveys the condensed water discharged from the heating tank 100 to the recovery container 120 . The recovery container 120 is a means for recovering the condensed water discharged from the heating tank 100 and preferably has a box-like structure so that the water discharged from the heating tank 100 can be temporarily stored.

The recovery container 120 includes a water level sensor 125 therein. The water level sensor 125 is a means for sensing the level of water stored in the recovery vessel 120 and is configured to generate a level detection signal when water is stored in the recovery vessel 120. In addition, the water level sensor 125 calculates the water level in the recovery container 120 for a predetermined time, and operates the circulation pump 135 installed on the transportation line 130 when the water level sensor 125 is above a predetermined reference value.

The circulation pump 135 is installed on the transportation line 130 and the circulation pump 135 serves to provide power for transferring the condensed water from the recovery container 120 to the preheating tank 140. The transfer line 130 connects the recovery vessel 120 and the preheating tank 140 and receives the power from the circulation pump 135 to transfer the condensed water from the recovery vessel 120 to the preheating tank 140 .

The preheating tank 140 is a means for storing water that can be reused as steam for temporarily storing the condensed water temporarily stored in the recovery container 120. The preheating tank 140 can store separate water by the operator and is also supplied from the recovery container 120 It is preferable that the condensed water to be stored is additionally stored.

The heating tank 100 causes the high pressure pump 150 to inject the heating water supplied from the preheating tank 140 into the heating tank 100 at a high pressure. For this purpose, a water injection nozzle 104 is provided at the tip of the heating water pressure supply line or the upper part of the heating tank 100 connected to the high pressure pump 150.

The heating tank 100 also includes a plurality of heating heaters 102 for heating the heating tank 100 so that the heating water seeped through the water injection nozzle 104 can be vaporized immediately. Therefore, the heating seizure water injected through the water injection nozzle 104 is heated to a high temperature of 400 to 700 ° C. by the heating heater 102 in the fine particle state, and is immediately vaporized into the wet steam in the heating tank 100.

The water injection nozzle 104 is installed on the upper part of the heating tank 100 so as to allow the water spray nozzle 104 to reach the heating heater 102 over a large area while dispersing the heating water, As shown in Fig.

Fig. 2 is a view showing the heating heater shown in Fig. 1, and Fig. 3 is a detailed perspective view of the heating heater 102 shown in Fig. The number, shape, or mounting position of the heating heaters 102 for heating the respective heating tanks 100 may be variously changed. Is basically installed below the water injection nozzle 104 on the opposite side of the water injection nozzle 104 of the heating tank 100 as shown in Figs.

3, the heater 102 is a means for vaporizing the water jetted from the water jet nozzle 104 by means of a vapor. As the plurality of the heating heaters 102 are densely installed, The amount of condensed water falling to the bottom of the evaporator 100 is small. Therefore, it is preferable that the plurality of heating heaters 102 are installed in the heating tank 100 in a compact manner.

On the other hand, the heating heater 102 is preferably made of a carbon rod. Carbon fiber has been widely used as an area heating element or a rod-like heating element, and this embodiment corresponds to the latter and is conveniently referred to as a carbon rod.

When the carbon fiber is used as a heating element in the heating heater 102, it is possible to radiate heat with high efficiency without generating a high inrush current. Therefore, the carbon fiber is composed of a heating element made of carbon and a carbon- Both complex heating elements are possible. Since the carbon fiber has a positive temperature coefficient (PTC) effect by controlling the microstructure, the carbon fiber can have the effect of injecting or interrupting the current by utilizing the thermal expansion characteristic without a separate control system. .

 Further, the heating heater 102 may have a long curved shape in the form of a banana-shaped parabola as another embodiment. In this case, it is preferable that the heating heater 102 is curved so as to follow the boundary of the region where the heating water seizure water injected from the water spray nozzle 104 is injected.

Meanwhile, as shown in FIG. 2 to FIG. 3, it is preferable that a fractionation membrane 106 including a fractionation net is additionally installed in the heating tank 100. The fractionation membrane 106 serves to block the condensation of the condensed water and the vapor. For this purpose, the fractionation membrane 106 is disposed below the heating tank 100, Ensure space to accommodate. At this time, by slightly tilting the fractionation membrane 106, the condensed water can be quickly lowered through the fractionation network.

The fractionation net is a means for substantially separating the vapor and moisture in the heating tank 100. The fractionation net is formed in a net shape such as a net having a small scale so that the condensed water generated in the upper part is sent downward, Thereby preventing the wet steam in the tank 100 from re-recombining with the condensate.

The fractionation membrane 106 is formed of a non-combustible material that can withstand high temperatures, and preferably includes a nonwoven fabric. Therefore, the condensed water that has not been vaporized passes through the fractionation membrane 106 and is solid at the bottom of the heating tank 100, and the vaporized vapor is separated from the water by being positioned at the upper part of the heating tank 100, So that a sufficient amount of steam can be produced.

Now, the operation of the condensate recovery device according to the preferred embodiment of the present invention will be described as follows.

The pressurized water supplied to the heating tank 100 is injected into the heating tank 100 through the water injection nozzle 104 in a high-pressure state in the form of fine particles, and is directly vaporized by the heating heater 102 and converted into a wet vapor. So that the vaporized vapor or steam in the heating tank 100 is supplied through the supply line 160. The condensed water collected under the fractionation membrane 106 is recovered to the recovery vessel 120 along the recovery line 110 and the vapor component in the heating tank 100 is returned to the upper and lower positions with respect to the fractionation membrane 106 The steam condition can be maintained regardless.

Next, the water level sensor 125 installed in the recovery container 120 generates a water level sensing signal to sense the level of the condensed water stored in the recovery container 120, and when the water level reaches a certain level, the circulation pump 135 And operates. The condensed water collected in the recovery vessel 120 is pumped by the circulation pump 135 and returned to the heating tank 100 to be reused for steam production.

The foregoing description of the invention is merely exemplary of the invention and is used for the purpose of illustration only and is not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Heating tank 110: Condensate recovery line
120: recovery container 125: water level sensor
130: Condensate delivery line 135: Circulation pump

Claims (2)

A preheating tank for heating the water,
A heating tank in which water heated in the preheating tank is injected in the form of a heated water,
A recovery container for recovering condensed water discharged from the heating tank,
A condensate collection line connecting the heating tank and the recovery container,
A condensate transfer line for transferring condensate from the recovery container to the preheat tank
And a steam generator for generating steam.
The method according to claim 1,
Wherein the recovery container has a water level sensor,
When the water level of the condensed water in the recovery container exceeds a preset water level, the water level sensor detects the water level and operates the circulation pump installed in the condensed water transportation line to transfer the condensed water in the recovery container to the preheat tank .

Images