KR200443601Y1 - High Temperature condensation-water Recovery Device - Google Patents

Abstract

The present invention relates to an ultra-high temperature condensate recovery apparatus, and an upper tank for storing and storing the condensate; A lower tank having a maximum water surface located below the upper tank; A discharge pipe provided in communication with the lower side of the upper tank such that condensed water is naturally discharged from the upper tank by gravity; The condensate discharged from the upper tank is introduced into the lower tank, and one end is connected to the lower side of the lower tank and communicated with the discharge pipe so that the ultra-high temperature condensate collected in the lower tank is transferred to the high pressure tank of the boiler. The other end is an inlet and outlet pipe connected to the high pressure tank of the boiler; Water level sensing means for sensing the condensate level in the lower tank; A booster steam line for supplying steam into the lower tank to increase the pressure inside the lower tank and to transfer condensed water to the high pressure tank of the boiler through the outlet pipe; A recycling line for reclaiming the upper tank for recycling of steam remaining from the condensed water and the remaining steam in the lower tank; A three-way valve for selectively supplying steam in the lower tank through the booster steam line and selectively performing steam exhaust in the lower tank through the recycle line; The main controller for controlling the three-way valve based on the signal sensed by the water level sensing means; do not employ a separate motor-driven pump to prevent electrical and mechanical damage of the pump by the ultra-high temperature condensate through a configuration including a The present invention relates to an ultra high temperature condensate recovery device capable of pumping ultra high temperature condensate by a specially designed piping structure together with a condensate tank.

Condensate, Tank, Water Level Detection, Magnetic, Three Way Valve

Description

High Temperature Condensation-water Recovery Device

The present invention relates to an ultra high temperature condensate recovery device, and more particularly, to a specially designed piping structure together with a condensate tank without employing a separate motor-driven pump to prevent electrical and mechanical damage of the pump by the ultra high temperature condensate. The present invention relates to an ultra high temperature condensate recovery device capable of pumping ultra high temperature condensate.

In general, in an installation requiring steam supply, water is heated by a boiler to generate steam. In order to generate steam in the boiler, the water supplied to the boiler must be heated 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.

In general, a 6 ° C increase in feed water reduces fuel consumption by about 1%. In addition, the feed water of the boiler is chemically treated, but the condensed water is chemically stable distilled water, so that it can be sufficiently recycled as boiler feed water without a separate chemical treatment. Therefore, the condensate can be reused as the boiler feed water after being recovered in that it is possible to reuse the retained calories and does not need a separate water treatment, and many condensate recovery devices for such condensate reuse are known.

Here, the condensate recovery apparatus using an Ogden pump is mentioned as a conventional condensate collection apparatus. Ogden pump is designed to recover condensate effectively without cavitation that can occur in general pump. It is electrically safe by using steam or compressed air as power and it is low in operating cost because it uses small amount of steam about 3kg / hr.

The Ogden pump operates in a similar way to the piston where condensed water enters the pump and the water level rises, which supplies the power steam and pushes the condensed water into the return pipe by the pressure of the supplied steam. Sent to and reused. In addition, when there is no condensate entering the pump, the pump is automatically stopped, and there is no inflow of power steam. Automatic pumping occurs when condensate flow resumes. Ogden pumps have a relatively large pumping capacity, but if the condensate load is very large or the condensate return line is very long, only one pump will run out of capacity. Therefore, two or three pumps can be installed in parallel. .

On the other hand, as a conventional condensate recovery device used in addition to the condensate recovery device using an Ogden pump, a condensate recovery device using a water level control pump. Here, in the condensate recovery apparatus using the water level control pump, as shown in FIG. 1, the air in the condensate tank 21 installed at atmospheric pressure is introduced into the condensate tank 21 through the condensate inlet pipe 23. Discharged through the 28 and the condensate tank 21 is provided with a water level control electrode rod 26 so that when the condensate reaches the control level, the stop valve 24a installed in the condensate discharge pipe 24 pipe is opened and the pump ( After the condensate in the condensate tank 21 is reused as boiler feed water by the operation of 30), the condensate is recirculated to the condensate inlet pipe 23 and circulated.

However, the condensate recovery device using the conventional water level control pump has a limitation in transferring condensate of very high temperature. In other words, the condensate recovery device using the water level control pump collects condensate into the condensate tank and transfers the collected condensate to the pump so that the condensate can be reused in the boiler. The condensed water causes the pump to heat, which causes the pump to overheat, causing malfunction and breakage of the motor.

In addition, the cavitation (cavitation) is generated in the pump, the motor driving the pump is idle, there is a problem that the power is wasted, the purpose of the condensate recovery device for energy saving does not achieve the original purpose. In addition, by venting the flash steam generated in the collection of ultra-high temperature condensed water into the atmosphere (Vent) to cause the loss of steam, the vapor due to the loss of steam due to the vent diffuses into the workplace deteriorates the work environment and contaminates the workplace There was a problem such as, the structure is very complicated and sensitive to the impact of the water hammer (water hammer), the failure is frequent, and thus there is a problem of increasing the maintenance cost and the investment of expensive equipment costs.

Accordingly, the present invention has been made to solve the problems described above, to provide an ultra-high temperature condensate recovery apparatus that can automatically recover and reuse the low-pressure condensate without using a general motor-driven pump. There is this.

In addition, the present invention has another object to provide a condensate recovery device that can be used universally for any fluid regardless of fluid characteristics, such as low and high pressure fluid and low and high temperature fluid.

Ultra high temperature condensate recovery apparatus according to the present invention for solving the object as described above and the upper tank (10) for storing and storing the condensate; A lower tank 20 having a maximum water surface lower than the upper tank 10; A discharge pipe 30 provided in communication with the lower side of the upper tank 10 so that the condensed water is naturally discharged from the upper tank 10 by gravity; The condensed water discharged from the upper tank 10 is introduced into the lower tank 20, and the ultra-high temperature condensed water collected inside the lower tank 20 is transferred to the high pressure tank 200 of the boiler so as to communicate with the discharge pipe. And one end is connected to the lower side of the lower tank, the other end and the inlet and outflow pipe 40 is connected to the high pressure tank; Water level detecting means (50) for detecting the condensate level in the lower tank (20); Booster steam line 60 for supplying steam into the lower tank 20 so as to increase the pressure inside the lower tank 20 to transfer the condensed water to the high pressure tank 200 of the boiler through the outflow pipe (40). and; A recycling line (70) for reclaiming the upper tank (10) for rehabilitation of the steam generated from the residual steam and the ultra-high temperature condensed water in the lower tank (20); A three-way valve (80) for selectively performing steam supply in the lower tank through the booster steam line (60) and steam exhaust in the lower tank through the recycle line (70); And a main controller (MC) for controlling the three-way valve based on the signal sensed by the water level sensing means (50), wherein the water level sensing means (50) measures the level of condensate collected in the lower tank (20). It further includes a water level level display unit (D) formed in communication with one end of the lower tank so that it can be visually seen from the outside, and detects the water level inside the lower tank 20 to transmit a water level detection signal to the main controller (MC), the main When the controller MC determines that the water level in the lower tank 20 reaches a predetermined low water level based on the water level detection signal transmitted from the water level sensing means 50, the booster steam line 60 of the three-way valve 80 ) Side is closed and the recycling line 70 is opened to lower the internal pressure of the lower tank 20 so that condensed water flows into the lower tank 20, and the water level in the lower tank 20 is preset. If it is determined to reach, the booster line 60 side of the three-way valve 80 is opened, the recycle line 70 side is closed to increase the pressure inside the lower tank 20, condensate water lower tank 20 Is discharged at a high pressure from the high pressure tank 200 of the boiler to control the pressure in the lower tank 20 by the three-way valve (80), the lower tank 20 when the three-way valve (8) is broken On / off valve 100 is further provided to maintain the pressure in the lower tank within the safe range, the ON / OFF valve 100 is the condensed water level in the lower tank 20 exceeds the predetermined high water level The water level sensing means 50 detects this and transmits a high level emergency signal to the main controller MC, and the main controller MC opens the ON / OFF valve 100 based on the high level emergency signal to lower the tank. Condensate level in (20) and the resulting pressure Force is maintained in a safe range.

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The present invention pumps low-pressure condensate without using a separate motor-driven pump to be recovered to the condensate tank, thereby reducing maintenance costs due to malfunction and damage caused by overheating of the pump and idling of the motor. In addition, the power consumption can be reduced, and the structure is simple, the production cost is reduced.

In addition, the present invention has the advantage that it can be used universally for any fluid regardless of the fluid characteristics, such as low and high pressure fluid and low and high temperature fluid.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the ultra-high temperature condensate recovery apparatus according to the present invention.

2 is an overall configuration diagram of the ultra-high temperature condensate recovery apparatus according to the present invention, Figure 3 is a block diagram showing the control relationship of the ultra-high temperature condensate recovery apparatus according to the present invention, Figure 4a to 4d is the ultra-high temperature condensate recovery according to the present invention 5 is a view showing the operation of the device, Figure 5 is a perspective view of the main portion of the water level detection means of the ultra-high temperature condensate recovery device according to the present invention.

As shown in Figure 2, the ultra-high temperature condensate recovery apparatus according to the present invention is to recover the condensate of about -1.0 ~ 10kg / ㎠ (about 80 ° ~ 190 °), the upper tank 10, the lower tank ( 20, discharge pipe 30, outflow pipe 40, water level detection means 50, booster steam line 60, recycle line 70, three-way valve 80, pressure gauge 90, main controller (MC) It is configured to include).

The upper tank 10 is a tank in which condensed water of low pressure is generated while the steam generated by the boiler is used in the place of use and the heat is taken down and lowered below the temperature heated by the first boiler. Here, the condensate collected in the upper tank 10 is slightly lower than the temperature due to the heating of the first boiler, but still maintains a high temperature.

On the other hand, the upper tank 10 is positioned to be higher than the maximum surface of the lower tank 20 to be described later is configured to be naturally discharged by the gravity of the ultra-high temperature condensed water flowing into the upper tank 10.

The lower tank 20 is a tank for storing and storing the condensed water discharged when the condensed water stored in the upper tank 10 is naturally discharged by gravity. As described above, the maximum of the lower tank 20 The water surface is configured to be located below the upper tank (10). Here, the one end side of the lower tank 20 is provided with a flange portion 22 formed in the protruding communication respectively up and down, the flange portion coupled to the water level sensing means 50 to be described later to measure the level of condensate in the lower tank It becomes possible.

The discharge pipe 30 is formed in communication with the lower side of the upper tank 10 in order to discharge the condensed water from the upper tank 10 to the lower tank 20. Here, the discharge pipe 30 is connected to the outflow pipe 40 to be described later.

On the other hand, the discharge pipe 30, the first check valve 34 for preventing the backflow of the condensate naturally discharged by gravity from the upper tank 10 and the first stop valve 32 for controlling the discharge of the condensate is It is provided.

The outflow pipe 40 has one end connected to the lower side of the lower tank 20, the other end is connected to the high pressure tank 200 of the boiler. Here, when the lower tank 20 reaches the low water level, the outflow pipe 40 allows the ultra-high temperature condensed water discharged through the discharge pipe 30 from the upper tank to the lower tank 20, and also the lower tank 20. ) Is installed to transfer the ultra-high temperature condensate collected when the high water level is reached to the high pressure tank 200 of the boiler. That is, the inlet and outlet are configured to be simultaneously performed in one pipeline.

On the other hand, a second check valve 42 for preventing the back flow of condensate and a second stop valve 44 for controlling the discharge of the condensate are also provided on the conduit of the outflow pipe 40.

The water level detecting means 50 is a portion for detecting the condensate water level in the lower tank 20 is coupled to the flange portion 22 is provided with a communication port protruding out of the lower tank 20, the level of the ultra-high temperature condensate collected therein Level level display unit (D) is provided so that it can be confirmed from the outside. The water level detecting unit 50 detects the water level of the condensate and transmits a corresponding detection signal to the main controller MC, which will be described later. Here, the water level sensing means 50 is composed of a magnetic float level transmitter (magnetic float level transmitter) provided to detect the water level by the action of the magnetic field of the permanent magnet, the low pressure and high pressure fluid or low temperature and high temperature Regardless of fluid characteristics such as fluid, it is possible to measure water level precisely for general purpose.

Here, as shown in FIG. 5, the magnetic float level transmitter is coupled to the flange portion 22 protrudingly communicated with one end side of the lower tank 20, and includes a water level level display unit D. As shown in FIG. Inside the water level display unit (D) is formed a float with permanent magnets that flow up and down as the water level changes. A water level detecting rod is provided outside the water level level display unit D to generate a signal according to the water level change. This configuration of such magnetic float level transmitters is already known and will not be described further in detail.

On the other hand, as shown in Figures 2 and 4a to 4d, the booster steam line (60) is coupled to one side of the three-way valve to be described later provided on the upper side of the lower tank (20). The booster steam line 60 is the steam flow into the lower tank 20 to increase the pressure inside the lower tank 20, the ultra-high temperature condensed water is transferred to the high-pressure tank 200 of the boiler through the outflow pipe (40). It is provided to be.

The recycling line 70 has one side communicating with the upper side of the other side of the three-way valve to which the above-described booster steam line 60 is coupled, and the other side communicating with the upper tank 10. The recycling line 70 reduces the pressure in the lower tank by evacuating the re-evaporation steam generated from the remaining steam and the ultra-high temperature condensed water in the above-described lower tank 20 to be recovered to the upper tank 10 described above, As a result, condensed water is smoothly introduced into the lower tank 20 from the upper tank 10. In addition, the re-evaporation steam is recycled to the upper tank 10 as the re-evaporation steam is discharged to the low pressure steam using place through the upper tank is recycled.

Here, in the case of, for example, a paper mill where the re-evaporation steam is re-recovered to the upper tank 10 and discharged to a low pressure steam using place through the recycling line 70, the low pressure steam is transferred to the hot air fan side and used as a corrugated cardboard factory. In this case, low pressure steam is recycled in the acceleration steam. Therefore, in addition to the smooth recovery of the condensed water through the discharge of the flash steam, it is possible to reduce the energy savings as the flash steam is recycled in a low pressure steam use such as a hot air fan or accelerated steam.

One side of the three-way valve 80 is connected to the lower tank 20, the other two sides are respectively connected to the booster steam line 60 and the recycling line 70, the lower through the booster steam line 60 A valve for selectively performing steam supply to the tank 20 and steam discharge in the lower tank 20 through the recycling line 70. Here, the three-way valve 80 is controlled according to the change in the water level inside the lower tank (20).

That is, as shown in the block diagram of Figure 3, the magnetic float level transmitter provided in the lower tank 20 detects the water level inside the lower tank to transmit a water level detection signal to the main controller (MC), the main When the controller MC determines that the water level in the lower tank 20 reaches a predetermined low water level based on the water level detection signal transmitted from the magnetic float level transmitter, the booster steam line 60 of the three-way valve 80 As the side is closed and the recycling line 70 is opened to discharge residual steam and flash steam to the upper tank, the pressure inside the lower tank 20 drops, so that the condensed water is lowered as shown in FIGS. 4A and 4B. 20) Allow it to flow inside.

On the other hand, after the residual steam and the re-evaporation steam of the lower tank 20 is recovered back to the upper tank 10 through the recital line 70, the steam in the low pressure state is a hot air fan of the paper mill, corrugated cardboard factory, acceleration High energy savings can be achieved by recycling to low pressure steam applications in various industries, such as horses. Here, if the residual steam and the re-evaporation steam is continuously introduced into the upper tank 10 from the lower tank 20, and the low pressure steam is not recycled to the low pressure steam destination, the pressure of the upper tank 10 explodes as the pressure increases. It is desirable to have an emergency vent (signal abbreviation) for removing such hazards.

Meanwhile, when the water level in the lower tank 20 is determined to reach a predetermined high water level as shown in FIG. 4C, the main controller MC opens the booster line 60 side of the three-way valve 80. As the recycling line 70 closes to increase the pressure inside the lower tank 20, the condensate is discharged from the lower tank 20 at a high pressure to be transferred to the high pressure tank of the boiler. In this way, by controlling the pressure in the lower tank 20 by the three-way valve 80 it is possible to function like a pump without having a separate pump.

In addition, the lower tank 20 may be further provided with a pressure gauge 90 to visually check the internal pressure from the outside.

Through this configuration, condensate of low pressure can be pumped and transferred to a high pressure tank of a boiler without having a separate motor driven pump, thereby preventing malfunction and damage of the device due to the high temperature of the condensate.

On the other hand, as shown in Figure 2, the lower portion of the lower tank 20 is provided with an ON / OFF valve 100. When the three-way valve 80 malfunctions due to a failure, condensed water continuously flows into the lower tank 20, thereby increasing the pressure in the lower tank 20, such that an explosion of the lower tank 20 exists. . This risk can be eliminated by the automatic opening and closing by the ON / OFF valve 100.

That is, as shown in FIG. 4d, when the condensate continues to flow into the lower tank 20 due to a failure of the three-way valve 80, and the condensate level in the lower tank 20 exceeds a preset high level, the magnetic float. The level transmitter detects this and transmits a high level emergency signal to the main controller MC, and the main controller MC opens an ON / OFF valve based on the high level emergency signal to condense water level in the lower tank 20. Accordingly, the pressure can be maintained in a safe range.

So far, the present invention has been described with reference to specific embodiments, but various modifications are possible to those skilled in the art without departing from the scope of the present invention, and such modifications are It is said to be included in the scope of the invention.

1 is a block diagram of a condensate recovery device using a conventional water level control pump.

2 is an overall configuration of the ultra-high temperature condensate recovery apparatus according to the present invention.

3 is a block diagram showing the control relationship of the ultra-high temperature condensate recovery apparatus according to the present invention.

4a to 4d is a view showing the operation sequence of the ultra-high temperature condensate recovery apparatus according to the present invention.

Figure 5 is a perspective view of the main portion of the water level detection means of the ultra-high temperature condensate recovery apparatus according to the present invention.

* Description of the major symbols in the drawings *

10: upper tank 20: lower tank

30: discharge pipe 32: first stop valve

34; First check valve 40: outflow pipe

42: second check valve 44: second stop valve

D: level indicator 50: level detecting means

60: booster steam line 70; Recycling line

80: three-way valve 90: pressure gauge

MC: Main Controller 100: ON / OFF Valve

Claims (5)

In the condensate recovery device, An upper tank 10 for storing and storing condensate; A lower tank 20 having a maximum water surface lower than the upper tank 10; A discharge pipe 30 provided in communication with the lower side of the upper tank 10 so that the condensed water is naturally discharged from the upper tank 10 by gravity; The condensed water discharged from the upper tank 10 is introduced into the lower tank 20, and the ultra-high temperature condensed water collected inside the lower tank 20 is transferred to the high pressure tank 200 of the boiler so as to communicate with the discharge pipe. And one end is connected to the lower side of the lower tank, the other end and the inlet and outflow pipe 40 is connected to the high pressure tank; Water level detecting means (50) for detecting the condensate level in the lower tank (20); Booster steam line 60 for supplying steam into the lower tank 20 so as to increase the pressure inside the lower tank 20 to transfer the condensed water to the high pressure tank 200 of the boiler through the outflow pipe (40). and; A recycling line (70) for reclaiming the upper tank (10) for rehabilitation of the steam generated from the residual steam and the ultra-high temperature condensed water in the lower tank (20); A three-way valve (80) for selectively performing steam supply in the lower tank through the booster steam line (60) and steam exhaust in the lower tank through the recycle line (70); And a main controller (MC) for controlling the three-way valve based on the signal detected from the water level detecting means (50). The water level detecting means 50 further includes a water level level display unit D formed in communication with one side of the lower tank so that the level of condensate collected in the lower tank 20 can be visually checked from the outside, and the lower tank 20 The internal water level is sensed and the water level detection signal is transmitted to the main controller MC. The main controller MC has a water level in the lower tank 20 in advance based on the water level detection signal transmitted from the water level sensing means 50. When it is determined that the set low water level is reached, the booster steam line 60 side of the three-way valve 80 is closed and the recycling line 70 side is opened to lower the pressure in the lower tank 20, thereby lowering the internal pressure of the lower tank 20. When the condensate is introduced into the furnace and the water level in the lower tank 20 is determined to reach a predetermined high water level, the booster line 60 side of the three-way valve 80 is opened and the recycle line 70 side is closed. As the internal pressure of the lower tank 20 is increased, the condensed water is discharged from the lower tank 20 at a high pressure to be transferred to the high pressure tank 200 of the boiler so that the pressure in the lower tank 20 is increased by the three-way valve 80. Control, Under the lower tank 20, when the three-way valve (8) is broken, an ON / OFF valve 100 for maintaining the pressure in the lower tank within the safety range is further provided, the ON / OFF valve 100 is lower When the condensate level in the tank 20 exceeds a preset high level, the level detecting means 50 detects this and transmits a high level emergency signal to the main controller MC, and the main controller MC sends the high level emergency signal. Ultra-high temperature condensate recovery device, characterized in that to maintain the condensate level in the lower tank 20 and the resulting pressure in a safe range by opening the ON / OFF valve 100 based on. delete delete delete delete

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