KR20210085636A - Steam Heat Exchanger Operating System and Method - Google Patents

Abstract

The present invention relates to a system and method for operating a steam heat exchanger, which smoothly discharges condensed water despite fast changes in load of a steam heat exchanger heating a fluid by using steam, thereby stably operating the steam heat exchanger. The system for operating a steam heat exchanger according to the present invention comprises: a steam heat exchanger for performing heat exchange between steam and a low-temperature heat transfer medium to heat the low-temperature heat transfer medium; a condensed water heat exchanger for cooling condensed water produced while the low-temperature heat transfer medium is heated by the steam heat exchanger; a condensed water pump for discharging the condensed water from the condensed water heat exchanger; a water level measurer for measuring water levels of the steam heat exchanger and/or condensed water heat exchanger; a second condensed water valve for controlling a flow rate of the condensed water supplied by the condensed water pump through control of opening/closing to a condensed water tank; and a water level controller for controlling the second condensed water valve according to the water level value measured by the water level measurer to adjust the water level of the steam heat exchanger and the condensed water heat exchanger.

Description

Steam Heat Exchanger Operating System and Method}

The present invention relates to a steam heat exchanger operating system and method capable of stably operating a steam heat exchanger by smoothly discharging condensed water despite a rapid load change of a steam heat exchanger that uses steam to heat a fluid.

In general, natural gas is produced in a cryogenically liquefied liquefied natural gas (LNG) state at a production site and then transported over a long distance to a destination by an LNG carrier. LNG is obtained by cooling natural gas to a cryogenic temperature of about -163°C under normal pressure, and its volume is reduced to approximately 1/600 compared to that of natural gas in gaseous state, so it is very suitable for long-distance transportation by sea.

An LNG carrier stores LNG in an LNG storage tank, operates through the sea, and unloads it to an onshore LNG terminal. The LNG transported by the LNG carrier is regasified using the LNG regasification system of the onshore LNG terminal, and the regasified gas is supplied to gas demanders such as gas power plants and city gas suppliers.

An onshore LNG regasification system requires a site for installing an LNG regasification system near a pier where an LNG carrier can dock, and it is difficult to secure a site due to opposition from local residents. In addition, it is economically disadvantageous due to high installation and operating costs, and there may be situations in which it is impossible to regasify LNG due to external factors such as natural disasters or terrorism, so it has structural limitations. In addition, it is difficult to apply in countries with insufficient gas supply infrastructure, and it is not easy to supply gas in regions with severe fluctuations in demand for city gas.

An LNG regasification vessel has been developed and applied to compensate for the disadvantages of such an onshore LNG regasification system. An LNG regasification vessel is an LNG RV (LNG Regasification Vessel) or LNG FSRU (Floating Storage Unit) in which an LNG regasification system is installed on an LNG carrier in order to regasify LNG at sea and supply natural gas to onshore gas demanders. and Regasification Unit) or a floating offshore structure (hereinafter collectively referred to as 'LNG regasification vessel').

In general, an LNG regasification system installed in an LNG regasification vessel includes a high pressure pump and a regas network that compresses low-pressure LNG stored in an LNG storage tank to a pressure required by a gas demander. Including a vaporizer (high pressure vaporizer) to vaporize by heating to the required temperature. The regasified gas vaporized through the high-pressure pump and the vaporizer is transferred to a gas consumer through a gas pipe network.

In the LNG regasification system, the LNG can be regasified by directly or indirectly heat-exchanging LNG and seawater or fresh water using seawater or fresh water, which is easily supplied and supplied, as a heat source. When seawater or freshwater is used as a heat source, the regasification capacity is affected by the temperature of the seawater, and if the seawater cooled by the cooling heat of LNG is released into the sea as it is, it causes environmental pollution problems such as ecosystem disturbance. There is this.

Meanwhile, steam may be used as a heat source for vaporizing LNG. 2 schematically illustrates a steam heat exchanger operating system in which steam is used as a heat source to heat fresh water, which is a heat transfer medium to be exchanged with LNG, and supply it to a vaporizer in an existing LNG regasification system.

2, the steam heat exchanger (SE) exchanges heat with steam and low-temperature fresh water, and supplies fresh water, that is, high-temperature fresh water, to a vaporizer (not shown) by heat exchange, and low-temperature steam or condensed water whose temperature is lowered by heat exchange is It is completely condensed or cooled in the condensate heat exchanger (CE) and stored in a condensed water storage tank (not shown).

Here, the low-temperature steam or condensed water whose temperature is lowered in the steam heat exchanger (SE), and the condensed or cooled condensed water in the condensate heat exchanger (CE) by the pressure difference between the steam heat exchanger (SE) and the condensate heat exchanger (CE), excreted naturally.

In addition, in order to discharge low-temperature steam or condensed water from the steam heat exchanger (SE) to the condensate heat exchanger (CE), the pressure of the steam heat exchanger (SE) is adjusted, and the low-temperature steam is smoothly discharged from the steam heat exchanger (SE) to the condensate heat exchanger (CE). It is designed to control the water level in the condensate heat exchanger.

Meanwhile, the flow rate of steam supplied to the steam heat exchanger SE is adjusted according to the target temperature of the high-temperature fresh water to be heated in the steam heat exchanger SE. In the steam heat exchanger SE, the amount of condensed water generated according to the load change is changed. That is, when the amount of steam supplied to the steam heat exchanger SE is adjusted according to the change in the load of the steam heat exchanger SE as described above, the internal pressure of the steam heat exchanger SE increases with the change in the amount of generated condensed water. will change

When the internal pressure of the steam heat exchanger SE is lowered according to a load change, there is a problem that low-temperature steam or condensed water is not discharged from the steam heat exchanger SE. In addition, since the responsiveness according to the pressure change of the steam heat exchanger SE is not good as described above, temperature control of the high-temperature fresh water discharged from the steam heat exchanger SE is not easy, and the operation range is very narrow.

Accordingly, an object of the present invention is to improve the above-described problems, and to provide a steam heat exchanger operating system and method in which condensed water is smoothly discharged from the steam heat exchanger to improve the responsiveness according to the load variation of the steam heat exchanger. do.

According to an aspect of the present invention for achieving the above object, there is provided a steam heat exchanger for heating a low-temperature heat transfer medium by exchanging steam with a low-temperature heat transfer medium; a condensate heat exchanger for cooling the condensed water while heating the low-temperature heat transfer medium in the steam heat exchanger; a condensate pump for discharging condensate from the condensate heat exchanger; a water level meter for measuring the water level of the steam heat exchanger and/or the condensate heat exchanger; a second condensate valve for regulating the flow rate of condensed water supplied from the condensate pump to the condensate tank by opening/closing control; and a water level controller controlling water levels of the steam heat exchanger and the condensate heat exchanger by controlling the second condensate valve according to the water level measurement value of the water level meter.

Preferably, a first condensate valve for recirculating a part of the condensed water supplied to the condensate tank by the condensate pump by opening/closing control to the condensate heat exchanger; and a current controller configured to control the first condensate valve according to the load of the condensate pump to adjust water levels of the steam heat exchanger and the condensate heat exchanger and maintain a minimum flow rate of the condensate pump.

Preferably, a steam valve for adjusting the flow rate of steam supplied to the steam heat exchanger by opening/closing control; a temperature measuring device for measuring a temperature of a high-temperature heat transfer medium supplied from the steam heat exchanger to a customer; and a temperature controller configured to control a flow rate of steam supplied to the steam heat exchanger by controlling the steam valve according to the temperature measurement value of the temperature measuring device.

Preferably, the method further comprises a second heating medium line configured to bypass a part or all of the low-temperature heat transfer medium supplied to the steam heat exchanger and join the flow of the high-temperature heat transfer medium supplied from the steam heat exchanger to the demand side by bypassing the steam heat exchanger. It is possible to adjust the temperature of the heat transfer medium supplied to the consumer.

Preferably, the demand may be a vaporizer for regasification of liquefied gas.

Preferably, opening and closing is controlled according to the water level measurement value of the condensed water heat exchanger measured by the water level meter, and further comprising a second condensate valve for adjusting the flow rate of the condensed water supplied to the condensate tank by the condensate pump, the It is possible to keep the water level in the condensate heat exchanger constant.

Preferably, it further comprises a first heat medium line for branching some or all of the low-temperature heat transfer medium supplied to the steam heat exchanger and supplying it as a refrigerant of the condensate heat exchanger, and the low temperature heated while being used as a refrigerant of the condensate heat exchanger. The heat transfer medium may be supplied to the steam heat exchanger or may be supplied to a demand by bypassing the steam heat exchanger.

According to another aspect of the present invention for achieving the above object, heat exchange between steam and a low-temperature heat transfer medium in a steam heat exchanger to heat the low-temperature heat transfer medium, and heat the low-temperature heat transfer medium and condensed condensed water in the condensate heat exchanger. Cooling, discharging the cooled condensate from the condensate heat exchanger using a pump, measuring the water level of the steam heat exchanger and the condensate heat exchanger to control the flow rate of the condensed water discharged from the condensate heat exchanger, steam heat exchanger A driving method is provided.

Preferably, according to the load of the pump, a portion of the condensed water discharged from the condensate heat exchanger by the pump is recirculated to the condensate heat exchanger to secure the minimum flow rate of the pump.

Preferably, by measuring the temperature of the heat transfer medium that is heated in the steam heat exchanger and supplied to the demand, it is possible to control the flow rate of steam supplied to the steam heat exchanger.

The steam heat exchanger operating system and method according to the present invention, by forcibly discharging the condensed water from the steam heat exchanger, it is possible to quickly and smoothly discharge the condensed water even with a rapid load change of the steam heat exchanger, so that the system can be operated stably.

In addition, in order to smoothly discharge condensate from the steam heat exchanger, the minimum flow rate of the condensate pump is secured by maintaining the water level of the steam heat exchanger and the condensate heat exchanger constant regardless of load fluctuations, and the dry conditions of the condensate heat exchanger and the condensate pump are maintained. Avoid dry runnig.

1 is a schematic diagram illustrating a steam heat exchanger operating system according to an embodiment of the present invention.
2 is a schematic diagram illustrating a steam heat exchanger operating system according to the prior art.

In order to fully understand the operational advantages of the present invention and the objects achieved by the embodiments of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the configuration and operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. Here, in adding reference signs to the elements of each drawing, it should be noted that only the same elements are indicated by the same reference signs as possible even if they are indicated on different drawings. In addition, the following examples may be modified in various other forms, and the scope of the present invention is not limited to the following examples.

In an embodiment of the present invention to be described later, the liquefied gas may be a liquefied gas that can be transported by liquefying the gas at a low temperature, for example, LNG (Liquefied Natural Gas), LEG (Liquefied Ethane Gas), LPG (Liquefied Petroleum). Gas), liquefied ethylene gas (Liquefied Ethylene Gas), liquefied propylene gas (Liquefied Propylene Gas) may be a liquefied petrochemical gas. Alternatively, liquid gas such as liquefied carbon dioxide, liquefied hydrogen or liquefied ammonia may be used. However, in the embodiments to be described later, an example in which LNG, which is a representative liquefied gas, is applied will be described.

In addition, although the steam heat exchanger operating system and method according to an embodiment of the present invention, which will be described later, is described as an example applied to a ship, it may be applied on land.

In addition, in an embodiment of the present invention, the vessel will be described as an example of an LNG regasification vessel. LNG regasification vessels include all types of vessels equipped with LNG regasification facilities that can regasify and supply LNG to gas demanders, that is, vessels with self-propelled capabilities such as LNG RV (Regasification Vessel), and LNG FSRU (Floating FSRU). It may be an offshore structure that does not have propulsion capability like the Storage Regasification Unit), but is floating in the sea. However, in the embodiment to be described later, the LNG FSRU will be described as an example.

Hereinafter, a steam heat exchanger operating system and method according to an embodiment of the present invention will be described with reference to FIG. 1 .

The steam heat exchanger operating system according to an embodiment of the present invention provides a steam heat exchanger 100 for heating a low-temperature heat transfer medium by exchanging steam with a low-temperature heat transfer medium, and condensing while heating a low-temperature heat transfer medium in the steam heat exchanger 100 . Water level for measuring the water level of the condensate heat exchanger 200 for cooling the condensed water, the condensate pump 300 for discharging condensed water from the condensate heat exchanger 200, the steam heat exchanger 100 and/or the condensate heat exchanger 200 The second condensate valve (CV2) is installed between the meter (LT), the condensate pump 300 and the condensate tank (not shown), and controls the flow rate of condensate supplied from the condensate pump 300 to the condensate tank by opening/closing control. ) and a water level controller (LIC) for controlling the water level of the steam heat exchanger 100 and the condensate heat exchanger 200 by controlling the second condensate valve CV2 according to the water level measurement value of the water level meter LT.

In addition, according to the load of the first condensate valve (CV1) and the condensate pump 300 for recirculating the condensed water supplied to the condensate tank by the condensate pump 300 by the opening/closing control to the condensate heat exchanger 200, the first condensate water It further includes a current controller (CIC) for controlling the valve (CV1) to adjust the water level of the steam heat exchanger (100) and the condensate heat exchanger (200) and to maintain the minimum flow rate of the condensate pump (300).

In addition, a steam valve (SV) for controlling the flow rate of steam supplied to the steam heat exchanger 100 by opening/closing control, and a first temperature measuring device for measuring the temperature of the high-temperature heat transfer medium discharged from the steam heat exchanger 100 ( TT1) and the second temperature gauge (TT2) and the first temperature gauge (TT1) and / or the second temperature gauge (TT2) according to the temperature measurement value by controlling the steam valve (SV) to supply to the steam heat exchanger (100) It further comprises a temperature controller (TIC) for adjusting the flow rate of the steam.

In this embodiment, the heat transfer medium is described as an example of fresh water (fresh water).

Low-temperature water (cold water) to be supplied to a vaporizer (not shown) in order to vaporize LNG is supplied to the steam heat exchanger 100 along the heating medium line WL, and by heat exchange with steam in the steam heat exchanger 100 The heated hot water (warm water) is supplied to the vaporizer along the heating medium line WL.

Low-temperature water cooled while vaporizing LNG in the vaporizer may be circulated back to the steam heat exchanger 100 along the heating medium line WL.

In this embodiment, steam is an economizer that recovers waste heat of a marine engine to generate steam or a boiler that generates steam with thermal energy generated by burning LNG fuel (not shown). ) may be the steam produced in

The steam generated in the steam generating device is supplied to the steam heat exchanger 100 along the steam line SL.

The steam supplied to the steam heat exchanger 100 may be cooled while heating low-temperature water to become low-temperature steam, or some or all of it may be condensed. All of the low-temperature steam not condensed in the steam heat exchanger 100 may be condensed by heat exchange in the condensate heat exchanger 200 , and the condensed water condensed in the steam heat exchanger 100 is cooled in the condensate heat exchanger 200 or Alternatively, it may be transferred to the condensate tank without heat exchange.

Hereinafter, an example in which all of the steam is condensed in the steam heat exchanger 100 will be described.

The condensed water condensed in the steam heat exchanger 100 is discharged from the steam heat exchanger 100 and transferred from the steam heat exchanger 100 to the condensed water heat exchanger 200 along the steam line SL.

In the condensed water heat exchanger 200, the low-temperature water supplied to the steam heat exchanger 100 along the first heat medium line WL1 branched upstream of the steam heat exchanger 100 from the heat medium line WL, and the steam line ( SL), the condensed water transferred from the steam heat exchanger 100 to the condensed water heat exchanger 200 exchanges heat, so that the low-temperature water is heated and the condensed water is cooled.

The condensate discharged from the condensate heat exchanger 200 is discharged by the operation of the condensate pump 300 and is transferred to the condensate tank along the vapor line SL.

Condensate stored in the condensate tank can be fed back to the steam generator.

In addition, according to this embodiment, the condensate is branched from the steam line SL between the condensate pump 300 and the condensate tank and is connected to the steam line SL between the steam heat exchanger 100 and the condensate heat exchanger 200 . Through the branch line SL1, some or all of the condensed water transferred to the condensate tank may be recirculated to the condensate heat exchanger 200 .

On the other hand, according to the present embodiment, the steam heat exchanger 100 through the second heat medium line (WL2) branched from the heat medium line (WL) upstream of the steam heat exchanger 100 is connected to the downstream of the steam heat exchanger (100) ), some or all of the low-temperature water supplied to the steam heat exchanger 100 may be transferred directly to the vaporizer without being supplied.

That is, all of the low-temperature water may be supplied to the steam heat exchanger 100 and all heated and supplied to the vaporizer, some of the low-temperature water is heated in the steam heat exchanger 100 and the remaining part bypasses the steam heat exchanger 100 . It can also be supplied to the vaporizer by controlling the temperature by mixing in the downstream of the steam heat exchanger 100 in a state that is not heated.

According to the present embodiment, the steam valve SV is controlled by measuring the temperature of the hot water heated and discharged from the steam heat exchanger 100 with the second temperature measuring device TT2, or mixed water in which hot water and low temperature water are mixed. The steam valve SV may be controlled by measuring the temperature of the first temperature measuring device TT1.

For example, when the temperature measurement value measured by the first temperature measurement device TT1 and/or the second temperature measurement device TT2 is lower than the target value, the steam valve SV is adjusted to supply the steam heat exchanger 100 . By increasing the flow rate of the generated steam, the temperature of the hot water supplied to the carburetor is increased.

In the steam heat exchanger 100 , condensed water may be discharged from the steam heat exchanger 100 to the condensate heat exchanger 200 by a difference in water level with the condensate heat exchanger 200 .

According to this embodiment, by measuring the water level of the steam heat exchanger 100 and/or the condensate heat exchanger 200 so that condensed water is smoothly discharged from the steam heat exchanger 100 to the condensate heat exchanger 200, the steam heat exchanger When the water level of ( 100 ) and/or the condensate heat exchanger 200 exceeds the set value, the condensate is discharged from the condensate heat exchanger 200 using the condensate pump 300 .

Whether the condensate pump 300 operates and the load of the condensate pump 300 is determined according to a water level measurement value of the steam heat exchanger 100 and/or the condensate heat exchanger 200 measured by the water level meter LT.

For example, when the water level measurement value of the steam heat exchanger 100 and/or the condensate water heat exchanger 200 measured by the water level meter LT exceeds the set value, the second condensate water valve CV2 is opened or the opening amount to increase the flow rate of the condensed water transferred from the condensate heat exchanger 200 to the condensate tank.

At this time, the current controller (CIC) senses the load of the condensate pump 300 , and the flow rate of the condensate supplied from the condensate heat exchanger 200 to the condensate pump 300 is less than the minimum flow rate of the condensate pump 300 . , the condensate is recycled to the condensate heat exchanger 200 through the first condensate branch line SL1 downstream of the condensate pump 300, and the condensate supplied from the condensate heat exchanger 200 to the condensate pump 300 increases the flow of

In addition, the current controller (CIC) may be used as a means for maintaining the water level of the condensate heat exchanger (200).

As described above, according to this embodiment, in the system consisting of a steam heat exchanger and a condensate heat exchanger used to heat low-temperature water to generate high-temperature water, when the amount of steam supplied according to load fluctuations is adjusted, the generated Since the amount of condensate is changed and the internal pressure of the steam heat exchanger and the condensate heat exchanger is lowered at the same time, it is possible to solve the problem that the generated condensate cannot be discharged naturally and the problem that the operation range is narrowed by this.

That is, by using the condensate pump 300, the temperature controller (TIC) and the water level controller (LIC), the condensed water is forcibly discharged from the steam heat exchanger 100 and the condensed water heat exchanger 200, and at the same time the steam heat exchanger ( 100) and by maintaining the water level of the condensate heat exchanger 200 constant, the condensate pump 300 can be operated stably.

Therefore, even if the steam supply amount according to the load fluctuation is adjusted, the condensed water can be smoothly discharged and the system can be operated stably.

In addition, in order to prevent the operation of the condensate heat exchanger 200 and dry running of the condensate pump 300, the water level of the condensate heat exchanger 200 is constantly maintained using a water level controller (LIC), and the current controller (CIC) It is possible to secure the minimum flow rate of the condensate pump 300 by using.

According to the present embodiment, by forcibly discharging the condensed water, the steam supply amount can be smoothly adjusted according to the load fluctuation, and thus the responsiveness of the system according to the load fluctuation can be dramatically improved. In addition, the water level of the condensate heat exchanger 200 may be constantly maintained regardless of load fluctuations by using the condensate pump.

As described above, the embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the present invention in addition to the above-described embodiments is recognized by those of ordinary skill in the art. It is self-evident to Therefore, the above-described embodiments are to be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description, but may be modified within the scope of the appended claims and their equivalents.

100: steam heat exchanger
200: condensate heat exchanger
300: condensate pump
SV : steam valve
CV1: first condensate valve CV2: second condensate valve
SL : Steam line SL1 : Condensate branch line
WL: heating medium line WL1: first heating medium line
WL2: 2nd heating medium line
TT1, TT2 : Temperature measuring instrument TIC : Temperature controller
LT : water level meter LIC : water level controller
CIC: Current controller

Claims (10)

a steam heat exchanger configured to heat the low-temperature heat-transfer medium by exchanging steam with the low-temperature heat-transfer medium;
a condensate heat exchanger for cooling the condensed water while heating the low-temperature heat transfer medium in the steam heat exchanger;
a condensate pump for discharging condensate from the condensate heat exchanger;
a water level meter for measuring the water level of the steam heat exchanger and/or the condensate heat exchanger;
a second condensate valve for regulating the flow rate of condensed water supplied from the condensate pump to the condensate tank by opening/closing control; and
and a water level controller controlling water levels of the steam heat exchanger and the condensate heat exchanger by controlling the second condensate valve according to the water level measurement value of the water level meter. The method according to claim 1,
a first condensate valve for recirculating a portion of the condensed water supplied to the condensate tank by the condensate pump by opening/closing control to the condensate heat exchanger; and
and a current controller controlling the first condensate valve according to the load of the condensate pump to adjust water levels of the steam heat exchanger and the condensate heat exchanger and to maintain a minimum flow rate of the condensate pump. The method according to claim 1,
a steam valve for regulating the flow rate of steam supplied to the steam heat exchanger by opening/closing control;
a temperature measuring device for measuring a temperature of a high-temperature heat transfer medium supplied from the steam heat exchanger to a customer; and
The steam heat exchanger operating system further comprising a temperature controller controlling the steam valve according to the temperature measurement value of the temperature measuring device to adjust the flow rate of steam supplied to the steam heat exchanger. 4. The method according to claim 3,
Further comprising a second heating medium line which bypasses a part or all of the low-temperature heat transfer medium supplied to the steam heat exchanger and joins the flow of the high-temperature heat transfer medium supplied from the steam heat exchanger to a demanding place,
A steam heat exchanger operating system for controlling the temperature of the heat transfer medium supplied to the demand. 4. The method according to claim 3,
The demand is a vaporizer for regasification of liquefied gas, a steam heat exchanger operating system. The method according to claim 1,
A second condensate valve for controlling the opening and closing according to the water level measurement value of the condensate heat exchanger measured by the water level meter and adjusting the flow rate of the condensed water supplied to the condensate tank by the condensate pump further comprising:
A steam heat exchanger operating system for maintaining a constant water level in the condensate heat exchanger. The method according to claim 1,
Further comprising a first heat medium line for branching some or all of the low-temperature heat transfer medium supplied to the steam heat exchanger and supplying it as a refrigerant of the condensate heat exchanger,
The low-temperature heat transfer medium heated while being used as a refrigerant of the condensate heat exchanger is supplied to the steam heat exchanger or bypassed the steam heat exchanger and supplied to a consumer. Heating the low-temperature heat-transfer medium by heat-exchanging steam and low-temperature heat-transfer medium in a steam heat exchanger;
Cooling the condensed water condensed while heating the low-temperature heat transfer medium in a condensed water heat exchanger,
Discharging the cooled condensate from the condensate heat exchanger using a pump,
A steam heat exchanger operating method for controlling the flow rate of the condensed water discharged from the condensate heat exchanger by measuring the water level of the steam heat exchanger and the condensate heat exchanger. 9. The method of claim 8,
According to the load of the pump, a portion of the condensed water discharged from the condensate heat exchanger by the pump is recirculated to the condensate heat exchanger to secure a minimum flow rate of the pump. 9. The method of claim 8,
A steam heat exchanger operating method for controlling a flow rate of steam supplied to the steam heat exchanger by measuring a temperature of a heat transfer medium heated in the steam heat exchanger and supplied to a consumer.

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