KR20240057085A - Ventilation apparatus - Google Patents

Abstract

The ventilation device according to an embodiment of the present invention has a communication hole formed in the flow separation wall that separates the supply air discharge area where the evaporator is placed and the exhaust discharge area where the exhaust fan is placed, and the communication hole is selectively opened and closed by a dry damper module. By doing so, when the evaporator needs to be dried, the indoor air sucked in through the outdoor air outlet sequentially passes through the evaporator, the communication hole, and the exhaust discharge area and is then discharged to the outdoors through the internal air outlet.

Description

Ventilation apparatus {Ventilation apparatus}

The present invention relates to ventilation devices.

A ventilation device is a device for discharging indoor air to the outside and supplying fresh outdoor air to the inside, and its main component is a heating element that allows only heat exchange without mixing between the discharged indoor air and the incoming outdoor air.

Recently, complex ventilation devices that can additionally perform a cooling function in addition to a ventilation function through total heat exchange have emerged.

In the prior art below, a complex ventilation device is disclosed in which a refrigeration system that forms a cooling cycle using a refrigerant is mounted inside the ventilator.

The ventilation device disclosed in the above prior art is configured for cooling and heating, that is, a compressor, a condenser (second heat exchanger), and an evaporator (first heat exchanger) are installed inside the ventilation device, and the discharged indoor air is used as a heating element. A damper (defined as a second damper) is provided for rapid cooling that flows back into the room after passing through the evaporator.

The complex ventilation air conditioning system described above can be said to be a system capable of not only a ventilation function using an electric heating element but also a cooling operation using an evaporator.

In a conventional complex ventilation device having such a structure, heat exchange occurs between the heating element and the evaporator, and in the process, dew is inevitably formed on the surface of the evaporator due to the temperature difference. As dew condensation on the surface of the evaporator continues for a long time, a problem arises in preventing various harmful bacteria, including mold, from multiplying and entering the room.

As a result, even though the ventilation operation is performed, there is a disadvantage in that it causes discomfort to the occupants and further causes problems that harm the occupants' health.

Prior art: Registered Patent No. 2124364 (June 18, 2020)

The present invention is proposed to improve the above problems.

The ventilation device according to an embodiment of the present invention for achieving the above object is a main case in which an external air inlet and an external air outlet are formed on one side, and an internal air inlet and an external air outlet are formed on the other side facing the one side. and a case including a lower case coupled to the lower side of the main case; an air purification module accommodated inside the case and including an electric heating element; an evaporator disposed between the air purification module and the outdoor air outlet; a suction fan module disposed inside the case and having an outlet connected to the external air outlet; an exhaust fan module disposed inside the case and having an outlet connected to the air outlet; a housing that accommodates the case and has an open bottom; and a shield cover covering the open bottom of the housing, wherein the main case includes: an air purification module mounting area where the air purification module is placed; a supply air inlet area defined between the outside air inlet and the air purification module mounting area; a supply air discharge area defined between the outside air discharge port and the air purification module mounting area, where the evaporator is placed; an exhaust inlet area defined between the vent inlet and the air purification module mounting area; and an exhaust discharge area defined between the air supply outlet and the air purification module mounting area, the ventilation device comprising: a flow separation wall forming a part of the main case and dividing the supply air discharge area and the exhaust discharge area; a communication hole formed in the flow separation wall; and a dry damper module that selectively opens and closes the communication hole.

To dry the evaporator, when the exhaust fan module operates and the dry damper module operates to open the communication hole, indoor air flows in through the outdoor air outlet, and indoor air flowing into the outdoor air outlet is It is characterized in that it sequentially passes through the evaporator, the communication hole, and the exhaust discharge area and is discharged to the outdoors through the exhaust outlet.

The dry damper module includes a fixed plate that shields a part of the communication hole, a damper rotatably connected to the fixed plate to selectively open and close the remaining part of the communication hole, and a tilting member that tilts the damper.

The tilting member includes a damper motor fixed to the fixing plate, and a link connecting the rotation axis of the damper motor and the damper.

The link includes a first link whose one end is connected to the rotation shaft of the damper motor and rotates, and a second link whose one end is connected to the other end of the first link and the other end is connected to the damper.

A fixing plate insertion groove into which the fixing plate is inserted is formed at an edge of the communication hole.

A damper seating protrusion is formed on the edge of the communication hole, excluding the portion where the fixing plate insertion groove is formed, to which the edge of the damper comes into close contact.

The ventilation device according to the present invention further includes a sealing member provided on the damper seating protrusion.

The ventilation device according to the embodiment of the present invention configured as described above has the following advantages and effects.

First, since only the evaporator among the cooling cycle components is provided inside the ventilation device, the volume and weight of the ventilation device are reduced, making installation easy, and the risk of falling due to gravity is reduced.

Second, since the condenser is not installed inside the ventilation device, the exhaust fan does not need to be driven in the rapid cooling mode in which indoor air is bypassed, passed through the evaporator, and then discharged into the room, which has the advantage of reducing power consumption. there is.

Third, since a bypass flow path is provided inside the ventilation device to allow indoor air to be discharged directly to the outdoors without passing through the heating element, there is an advantage in that contamination of the heating element is minimized and the lifespan of the heating element is extended.

Fourth, since indoor air can be discharged through the bypass passage, incoming outdoor air can be supplied indoors without recovering waste heat contained in the indoor air, which has the advantage of improving ventilation performance and user satisfaction.

Fifth, since outdoor air passes through various filters before being introduced into the heating element, foreign substances and harmful bacteria are filtered out in advance, which has the advantage of extending the lifespan of the heating element.

Sixth, since the air purification means including the heating elements and filters are provided in the form of a single module, there is an advantage in that they are easy to install and repair.

Seventh, since the compressor and condenser are installed outside the ventilation device, the size of the evaporator can be increased, which has the advantage of increasing cooling capacity.

Eighth, by forming a communication hole that is selectively opened and closed by a dry damper in the flow separation wall dividing the supply air discharge area and the exhaust discharge area, there is an advantage that a dry mode can be executed to remove moisture formed on the surface of the evaporator. In addition, by enabling the dry mode to be executed, there is an effect of preventing the growth of mold and other harmful bacteria on the surface of the evaporator.

1 is a bottom perspective view of a ventilation device according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of the ventilation device.
Figure 3 is a bottom view showing the internal configuration of the ventilation device.
Figure 4 is a cross-sectional perspective view of the ventilation device taken along line 4-4 in Figure 1;
Figure 5 is a bottom perspective view of the main case constituting a ventilation device according to an embodiment of the present invention.
Figure 6 is an enlarged perspective view of a flow separation wall provided with a communication hole on which a dry damper module is mounted.
Figure 7 is a perspective view of a dry damper module according to an embodiment of the present invention.

Hereinafter, a ventilation device according to an embodiment of the present invention will be described in detail with reference to the drawings.

Figure 1 is a bottom perspective view of a ventilation device according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the ventilation device, Figure 3 is a bottom view showing the internal configuration of the ventilation device, and Figure 4 is a 4-4 of Figure 1. This is a cross-sectional perspective view of the ventilation device cut along 4.

Referring to Figures 1 to 4, the ventilation device 10 according to an embodiment of the present invention is mainly installed on the ceiling, so the user mainly recognizes the bottom of the ventilation device 10.

Also, as shown in FIG. 1, the user can open the cover provided on the bottom of the ventilation device 10 to separate or replace the air purification module.

In detail, the ventilation device 10 according to an embodiment of the present invention includes a housing 11 in the shape of a hexahedron with an open bottom, a shield cover 16 covering the open bottom of the housing 11, and , and includes a plurality of duct flanges respectively mounted on two opposing sides of the housing 11.

An outdoor air inlet 101 and an indoor air outlet 104 are formed at both ends of one side of the housing 11, respectively. In addition, an indoor air inlet 103 and an outdoor air outlet 102 are formed at both ends of the other side of the housing 11 facing one side.

In addition, the outside air inlet 101 is formed at a position facing the inside air inlet 103, and the inside air outlet 104 is formed at a position facing the outside air discharge port 102.

In addition, the outdoor air flowing into the outdoor air inlet 101 is discharged indoors through the outdoor air outlet 102 located diagonally, and the indoor air flowing into the indoor air inlet 103 is discharged through the indoor air outlet located diagonally. It is discharged outdoors through (104). This is because outdoor air and indoor air flow in directions that intersect each other when passing through an air purification module, which will be described later, among components accommodated inside the housing 11.

Meanwhile, the duct flange includes an outdoor air inlet flange 171 mounted on the outdoor air inlet 101, and an outdoor air discharge flange 172 mounted on the outdoor air outlet 102. ), and an indoor air inlet flange 173 mounted on the indoor air inlet 103, and an indoor air exhaust flange 174 mounted on the indoor air outlet 104. .

Optionally, a heating device 50 may be installed in the outdoor air outlet 102. When the heating device 50 is mounted on the outside air discharge port 102, the outside air discharge flange 172 may be mounted on the outlet of the heating device 50.

In addition, the ventilation device 10 further includes a case accommodated inside the housing 11, and a lower cover 15 provided between the case and the shield cover 16 to cover the bottom of the case. do. A passage hole 151 through which an air purification module, which will be described later, passes is formed in the lower cover 15.

The case includes a lower case 14, a middle case 13, and an upper case 12, and the combination of the upper case 12 and the middle case 13 can be defined as the main case 100. there is. The lower cover 15 is mounted on the bottom of the lower case 14 and is shielded by the shield cover 16. Additionally, the shield cover 16 is rotatably coupled to the housing 11 to selectively shield the shield cover 16.

The ventilation device 10 further includes an air purification module 40, a cooling module, and a fan module installed inside the case. The cooling module includes components constituting a refrigerant cycle using a refrigerant as a circulating fluid, and includes at least an evaporator 21 through which a low-temperature, low-pressure two-phase refrigerant flows. Additionally, the evaporator 21 may be located on the outlet side of the air purification module 40.

The fan module includes a suction fan module 19 that intakes outdoor air and discharges it indoors, and an exhaust fan module 20 that intakes indoor air and exhausts it outdoors. The fan module includes a fan and a motor that rotates the fan module.

The suction fan module 19 may be disposed at a point where the outside air outlet 102 is formed so that the outlet of the suction fan module 19 and the outside air outlet 102 are connected. In addition, the exhaust fan module 20 may be disposed at a point where the internal air discharge port 104 is formed, so that the discharge port of the exhaust fan module 20 and the internal air outlet 104 are connected.

The air purification module 40 includes a module frame 41 and a heating element 42 accommodated inside the module frame 41. Optionally, the air purification module 40 may further include at least one of a HEPA filter 43, a pre-filter 44, and an optical filter 45. The optical filter 45 refers to a filter that removes harmful bacteria, such as mites, from the outdoor air sucked into the air purification module 40 or the pre-filter 44 using ultraviolet rays emitted from a UV lamp.

The air purification module 40 includes an optical filter 45, a pre-filter 44, a HEPA filter 43, and a heating element 42 arranged in order from the side closest to the outdoor air inlet 101, The outdoor air flowing in through the inlet 101 sequentially passes through the optical filter 45, the pre-filter 44, the HEPA filter, and the heating element 42, and then is supplied indoors through the outdoor air outlet 102. Make it possible.

Optionally, the ventilation device 10 may further include an air cleaning module 30, wherein the air cleaning module 30 is located between the evaporator 21 and the air cleaning module 40. , or may be placed between the evaporator 21 and the suction fan module 19. That is, the air purification module 40, the air purification module 30, and the evaporator 21 may be placed on a flow path through which outdoor air flows, and the placement positions of these components are located in the case, especially the main case 100. ) can be appropriately selected depending on the structure.

The fan module may be a centrifugal fan that sucks air in the axial direction and discharges it in the radial direction, but is not necessarily limited thereto. When the fan module is a centrifugal fan, the outlet of the suction fan module 19 is directly connected to the outside air outlet 102. Accordingly, the central axis of the outside air discharge flange 172 passes through the center of the discharge port of the suction fan module 19. In another aspect, it may be explained that the central axis of the outdoor air discharge flange 172 (or the central axis of the outdoor air outlet) and the fan axis of the suction fan module 19 are orthogonal.

On the other hand, in order to compact the ventilation device 10 or to secure space inside the main case 100 when the specifications of the housing 11 are determined, the fan shaft of the exhaust fan module 20 is It may be arranged parallel to the central axis L1 of the discharge flange 174 (or the central axis of the inner discharge port). That is, the line L2 passing through the center of the discharge port of the exhaust fan module 20 and the central axis L1 of the air discharge flange 174 may be designed to be perpendicular. Additionally, an exhaust air flow transition space 106 is formed between the exhaust fan module 20 and the air outlet 104.

In other words, the mounting position of the exhaust fan module 20 is designed so that the central axis of the air outlet 104 and the rotation axis of the exhaust fan module 20 are parallel.

Meanwhile, inside the main case 100, an outdoor air passage through which outdoor air flows and an internal air passage through which indoor air flows are formed in a direction that intersects each other. Then, the air purification module 40 is placed at a point where the flows of indoor air and outdoor air intersect. And, among the air flow paths, a first damper unit 22 is installed on the air flow path connecting the air inlet 103 and the air purification module 40. The first damper unit 22 allows indoor air flowing into the ventilation inlet 103 to selectively flow to either the air purification module 40 or the bypass flow path B.

The bypass passage B includes an upper bypass groove 1311 formed on the bottom of the middle case 13 and a lower bypass groove 1411 formed on the upper surface of the lower case 14 (see FIG. 2). It is defined by the combination of .

In addition, a second damper unit 23 that switches the flow path so that the indoor air flowing into the inside air inlet 103 and flowing toward the bypass flow path (B) flows into the outdoor air flow path where the evaporator 21 is installed is installed in the main air flow path. It is installed inside the case 100. That is, the bypass passage B and the external air passage can be selectively connected by the second damper unit 23. Specifically, in a situation where rapid cooling is required, the indoor air introduced into the inside air inlet 103 by the operation of the second damper unit 23 passes through the evaporator 21 and then through the outside air outlet 102. It can be discharged back into the room through .

Meanwhile, the ventilation device 10 further includes a control box 18 that controls the operation of various components accommodated inside the housing 11. The various components may include the fan modules 19 and 20, the damper units 22 and 23, the air cleaning module 30, and the light filter 45. Additionally, the control box 18 may be mounted on the side of the housing 11, specifically on the indoor side.

Figure 5 is a bottom perspective view of the main case constituting a ventilation device according to an embodiment of the present invention.

Referring to FIG. 5, the main case 100 can be understood as a combination of the upper case 12 and the middle case 13, as described above.

Inside the main case 100, an external air flow path and an internal air flow path are formed in directions that intersect each other. An external air inlet 101 and an external air outlet 104 are formed on one side of the main case 110, and an internal air inlet 103 and an external air outlet 102 are formed on the other side. Part of the four air passage holes 101 to 104 are formed on the side of the upper case 12, and the remaining part is formed on the side of the lower case 13. And, when the lower case 13 and the upper case 12 are combined, a completely circular hole is formed.

Inside the main case 100, there is a supply air introducing area 1001, a supply air discharge area 1002, an exhaust air introducing area 1003, and an exhaust air introducing area 1003. an exhaust air exhausting area (1004), an air purification module mounting area (1005), a bypass guide area (1006), an exhaust air entrance area (1007), and an exhaust air entrance area (1007). Flow transition spaces 106 (see FIG. 4) are respectively defined.

The exhaust inlet 103 is formed on one side of the main case 100 defining an edge of the exhaust inlet area 1007, and the exhaust inlet area 1007 corresponds to the opposite side of the exhaust inlet 103. A first damper hole 107 is formed on the side of. Then, the first damper unit 22 is mounted in the first damper hole 107.

In addition, one end of the bypass guide area 1006 is connected to the side of the exhaust inlet area 1007 where the first damper hole 106 is formed or the side orthogonal to the side where the internal air inlet 103 is formed. do.

Additionally, the air purification module mounting area 1005 is formed at a point where the air supply flow path and the exhaust flow path intersect. The air purification module mounting area 1005 is formed with first to fourth sides continuous, corresponding to the shape of the air purification module 40.

The supply air inlet area 1001 is defined between the outside air inlet 101 and the first side of the air purification module mounting area 1005.

The exhaust inlet area 1003 is defined between the exhaust inlet area 1007 and the second side of the air purification module mounting area 1005. Additionally, the exhaust inlet area 1003 and the exhaust inlet area 1007 selectively communicate by operating the first damper unit 22.

The bypass guide area 1006 connects the exhaust inlet area 1007 and the inlet of the bypass flow path B, and the outlet of the bypass flow path B is connected to the exhaust discharge area 1004. . The first side and the second side are adjacent to each other.

The supply air discharge area 1002 is defined between the supply air outlet 102 and the third side of the air purification module mounting area 1005. The second damper hole 108 is formed at the boundary between the air supply discharge area 1002 and the bypass guide area 1006. By operating the second damper unit 23, the bypass guide area 1006 and the air supply discharge area 1002 selectively communicate. The third side is located opposite the first side.

Additionally, the exhaust discharge area 1004 extends from the fourth side of the air purification module mounting area 1005 to the exhaust flow diversion space 106. Additionally, an exhaust fan mounting hole 105 is formed at the boundary dividing the exhaust discharge area 1004 and the air purification module mounting area 1005, and the discharge port of the exhaust fan module 20 is formed through the exhaust fan mounting hole. Connected to (105).

The exhaust fan mounting hole 105 and the air outlet 104 are formed on vertical planes that intersect each other, so that the indoor air flowing along the exhaust discharge area 1004 changes its flow direction in the exhaust flow conversion space 106. After that, it is discharged through the bet outlet (104).

The exhaust discharge area 1004 and the supply air discharge area 1002 are partitioned by a flow separation wall (P), thereby preventing mixing of the exhausted indoor air and the incoming outdoor air. Here, the air supply discharge area 1002 is defined as including a space in which the evaporator 30 is accommodated.

The exhaust fan module 20 is disposed in the exhaust discharge area 1004, and the suction fan module 19 is disposed in the supply air discharge area 1002.

The flow separation wall (P) is defined as a wall extending from the outlet end of the bypass passage (B) toward the center of the main case (100). In detail, the bypass passage B includes an outer wall extending and bending along the outer edge of the main case 100, and is spaced a predetermined distance from the outer wall in the center direction of the main case 100, It can be described as being formed between the inner wall extending parallel to the wall. And, the flow separation wall (P) can be described as extending from the end of the inner wall portion.

In addition, the flow separation wall (P) includes a lower flow separation wall 134 extending from the end of the inner wall formed in the middle case 13, and an upper flow separation wall extending from the bottom of the upper case 12. Includes wall 124. The lower end of the upper flow separation wall 124 is seated on the upper end of the lower flow separation wall 134.

A communication hole (P1) is formed in the flow separation wall (P), and a dry damper module 60 is mounted in the communication hole (P1). Additionally, the communication hole P1 is selectively opened and closed by the operation of the dry damper module 60. Specifically, when an operation mode command for drying the evaporator is input, the drying damper module 60 operates and the communication hole P1 is opened. And, when the exhaust fan module 20 operates, the inside of the main case 100 becomes a negative pressure state, and indoor air flows into the supply air discharge area 1002 through the outside air discharge port 102. In addition, the indoor air flowing into the supply air discharge area 1002 passes through the evaporator 30 and evaporates moisture on the surface of the evaporator 30. Air containing moisture on the surface of the evaporator 30 passes through the communication hole P1 and flows into the exhaust discharge area 1004.

The air flowing into the exhaust discharge area 1004 is discharged outdoors through the exhaust discharge port 104.

Optionally, in the evaporator drying mode, the second damper 23 may be opened to allow indoor air to flow in through the air inlet 103. Indoor air flowing in through the air inlet 103 passes through the second damper hole 108 and flows into the air supply discharge area 1002. Then, in the supply air discharge area 1002, it passes through the communication hole P1 in a mixed state with indoor air sucked through the outside air discharge port 102.

Figure 6 is an enlarged perspective view of a flow separation wall provided with a communication hole on which a dry damper module is mounted.

Referring to FIG. 6, a fixing plate seating groove (P11) (or a fixing plate seating slot) and a damper seating protrusion (P12) may be formed at the edge of the communication hole (P1), respectively.

In detail, the fixing plate seating groove P11 may be defined as a groove into which the left and right and lower edges of the fixing plate of the dry damper module 60, which will be described later, are inserted. In addition, the damper seating protrusion P12 may be defined as a portion where the rear edge of the damper of the dry damper module, which will be described later, comes into close contact. To maintain airtightness, a sealing member may be attached to the damper seating area (P12).

Figure 7 is a perspective view of a dry damper module according to an embodiment of the present invention.

Referring to FIG. 7, the dry damper module 60 according to an embodiment of the present invention includes a fixing plate 61 inserted into the fixing plate insertion groove (P11) and rotatably connected to the top of the fixing plate 61. It includes a damper 62 and a tilting member that tilts the damper 62. The tilting member includes a damper motor 63 fixed to the rear surface of the fixing plate 61 and a connection link 65 connected to the rotation axis of the damper motor 63. The damper motor 63 may be fixed to the rear of the fixing plate 61 by a motor bracket 64.

The fixing plate 61 functions as a support plate for supporting the damper motor 63, and the fixing plate 61, the damper 62, and the tilting member may be provided in the form of one assembly or module, and the fixing plate ( 61) is inserted into the fixing plate insertion groove (P11), thereby completing the fastening of the dry damper module 60.

If the communication hole (P11) is made only in size corresponding to the size of the damper 62, a separate fastening operation must be performed to secure the damper motor 63 to the flow separation wall (P). , the fastening work must be performed within a narrow space of the main case 100, which has the disadvantage of being very inconvenient.

In order to solve this problem, the communication hole (P11) is sized to accommodate both the damper 62 and the fixing plate 61, and is provided as one assembly of the dry damper module 60. By doing so, there is an advantage that the assembly work is significantly simplified.

The connection link 65 is a multi-joint link including a first link connected to the rotation axis of the damper motor 63 and rotating, and a second link connecting the first link and the rear surface of the damper 62. may include.

Also, since the area of the communication hole P1 opened by the damper 62 is located at substantially the same height as the intake port of the exhaust fan module 20, flow resistance can be minimized.

Claims (8)

A case including a main case in which an external air inlet and an external air outlet are formed on one side, an internal air inlet and an external air outlet on the other side opposite the one side, and a lower case coupled to the lower side of the main case;
an air purification module accommodated inside the case and including an electric heating element;
an evaporator disposed between the air purification module and the outdoor air outlet;
a suction fan module disposed inside the case and having an outlet connected to the external air outlet;
an exhaust fan module disposed inside the case and having an outlet connected to the air outlet;
a housing that accommodates the case and has an open bottom; and
It includes a shield cover covering the open bottom surface of the housing,
Inside the main case,
an air purification module mounting area where the air purification module is placed;
a supply air inlet area defined between the outside air inlet and the air purification module mounting area;
a supply air discharge area defined between the outside air discharge port and the air purification module mounting area, where the evaporator is placed;
an exhaust inlet area defined between the vent inlet and the air purification module mounting area; and
In the ventilation device including an exhaust discharge area defined between the air exhaust outlet and the air purification module mounting area,
a flow separation wall that forms a part of the main case and partitions the supply air discharge area and the exhaust discharge area;
a communication hole formed in the flow separation wall; and
A ventilation device including a dry damper module that selectively opens and closes the communication hole.
According to claim 1,
To dry the evaporator, when the exhaust fan module operates and the dry damper module operates to open the communication hole, indoor air flows in through the outdoor air outlet,
A ventilation device, characterized in that indoor air flowing into the outdoor air outlet sequentially passes through the evaporator, the communication hole, and the exhaust discharge area and is discharged outdoors through the indoor air outlet. According to claim 2,
The dry damper module,
A fixing plate that shields a portion of the communication hole,
a damper rotatably connected to the fixing plate to selectively open and close the remaining part of the communication hole;
A ventilation device including a tilting member that tilts the damper. According to claim 3,
The tilting member is,
A damper motor fixed to the fixing plate,
A ventilation device including a link connecting the rotation shaft of the damper motor and the damper. According to claim 4,
The link above is,
A first link, one end of which is connected to the rotation axis of the damper motor and rotates,
A ventilation device comprising a second link, one end of which is connected to the other end of the first link, and the other end of which is connected to the damper. According to clause 3,
A ventilation device, characterized in that a fixing plate insertion groove into which the fixing plate is inserted is formed at an edge of the communication hole. According to claim 6,
A ventilation device, characterized in that a damper seating protrusion is formed on an edge of the communication hole excluding a portion where the fixing plate insertion groove is formed, with the edge of the damper in close contact. According to claim 7,
A ventilation device further comprising a sealing member provided on the damper seating protrusion.

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