WO2025110403A1 - Air purification device and functional module for use therein - Google Patents

Abstract

An air purification device according to an embodiment may comprise: a main body including at least one filter unit which includes a filter, a blower unit which includes a blower, a main control unit which is configured to control the operation of the blower unit, a power supply unit which is configured to supply power to the main control unit, and an output terminal which is configure to output power, delivered from the power supply unit, to the outside; and at least one functional module detachably assembled to the main body and including a functional unit which includes a circuit configured to perform a function of assisting the main body or a function different from the main body, an auxiliary control unit which is configured to control the operation of the functional unit, a connection terminal which can be electrically connected to the output terminal, and a second power supply unit which is configured to be supplied with separate power from power of the power supply unit.

Description

Air purifying device and functional module used therein

The present disclosure relates to an air purifying device and a functional module used therein.

An air purifier is a device used to remove pollutants from the air. An air purifier can remove bacteria, viruses, mold, fine dust, and other chemicals that cause bad odors from the inhaled air.

In addition to the air purification function of purifying indoor air, these air purifiers may be required to perform various functions. For example, depending on the needs of consumers, the air purifier may be required to have a booster fan function that rapidly disperses purified air. For example, depending on the needs of consumers, the air purifier may be required to have a function of controlling the humidity of indoor air.

An air purifying device according to one embodiment may include a main body module including at least one filter, a blower for inducing airflow to pass through the filter, a main control unit including a circuit for controlling operation of the blower, a power supply unit configured to supply power to the main control unit, and an output terminal configured to output power received from the power supply unit to the outside.

An air purifying device according to one embodiment may include at least one functional module including a functional unit that is detachably assembled to the main body module and configured to perform a function that assists the main body module or a function different from that of the main body module, an auxiliary control unit that controls the operation of the functional unit, a connection terminal that is provided to be electrically connectable to the output terminal, and a second power supply unit that is configured to receive power separate from that of the power supply unit.

A functional module detachably assembled to a main body module of an air purifying device according to one embodiment may include: a functional unit configured to perform a function assisting the main body module or a function different from that of the main body module; a connection terminal configured to be electrically connected to an output terminal configured to output power from the main body module to the outside; and a second power supply unit configured to receive power separate from the power supplied to the power supply unit of the main body module.

FIG. 1 is a perspective view of an exemplary air purifying device according to various embodiments.

FIG. 2 is a block diagram schematically illustrating an exemplary configuration of an air purifying device according to various embodiments.

Figure 3 is an exploded perspective view of an air purifier according to various embodiments.

FIG. 4 is a perspective view schematically illustrating an example of a functional module according to various embodiments.

FIG. 5a is a drawing for explaining the arrangement of functional modules in an air purifying device according to various embodiments. FIG. 5b is a drawing for explaining the arrangement of functional modules in an air purifying device according to various embodiments.

FIG. 6 is a drawing for explaining an example of a configuration in which a function module and a main body module of an air purifying device according to various embodiments are assembled so as to be separable.

FIG. 7 is a drawing showing an example of the first and second connection units of the air purifying device of FIG. 6 according to various embodiments.

FIG. 8 is a diagram illustrating a portion of the first and second connection units of FIG. 7 in isolation according to various embodiments.

FIG. 9a is a drawing showing the first connection unit of FIG. 8 in isolation according to various embodiments, and FIG. 9b is a drawing showing the second connection unit of FIG. 8 in isolation according to various embodiments.

FIG. 10 is a cross-sectional view for explaining the operation of the first and second connecting units of FIGS. 8 to 9b according to various embodiments. FIG. 11 is a cross-sectional view for explaining the operation of the first and second connecting units of FIGS. 8 to 9b according to various embodiments.

FIG. 12 is a drawing showing an example of the first and second connection units of the air purifying device of FIG. 6 according to various embodiments.

FIG. 13 is an exploded perspective view showing an example of the first and second connection units of the air purifier of FIG. 12 according to various embodiments.

FIG. 14 is a cross-sectional view for explaining the operation of the first and second connecting units of FIG. 12 according to various embodiments.

FIG. 15 is a drawing showing an example of the first and second connection units of the air purifying device of FIG. 6 according to various embodiments.

FIG. 16 is an exploded perspective view showing an example of the first and second connection units of the air purifier of FIG. 15 according to various embodiments.

FIG. 17 is a cross-sectional view for explaining the operation of the first and second connecting units of FIG. 15 according to various embodiments.

FIG. 18 is a drawing showing an example of the first and second connection units of the air purifying device of FIG. 6 according to various embodiments.

FIG. 19 is a drawing for explaining the operation of the first and second connection units of FIG. 18 according to various embodiments.

FIG. 20 is a schematic drawing showing an example of a structure for electrical connection between a function module and a main body module of an air purifying device according to various embodiments.

FIG. 21 is a schematic drawing showing an example of a structure for electrical connection between a function module and a main body module of an air purifying device according to various embodiments.

FIG. 22 is a drawing schematically illustrating a connection process using a structure for electrical connection between a function module and a main body module of an air purifier according to various embodiments.

FIG. 23 is a drawing for explaining the operation of an air purifier when the main body module and the function module are separated according to various embodiments.

FIG. 24 is a drawing for explaining the operation of an air purifier when a function module according to various embodiments is assembled from a main body module.

FIG. 25a is a drawing for explaining an example of use when a main body module and a function module are assembled according to various embodiments.

FIG. 25b is a drawing for explaining an example of use in which the main body module and the function module are separated according to various embodiments.

FIG. 26 is a block diagram showing exemplary configurations of a main body module and a functional module of an air purifying device according to various embodiments.

FIG. 27 is a drawing showing an example in which the functional module of an air purifying device according to various embodiments is a humidifying module.

FIG. 28 is a drawing for explaining an example of the configuration of the function module of FIG. 27 according to various embodiments.

FIG. 29 is a drawing showing an example in which the functional module of an air purifying device according to various embodiments is a charging module.

FIG. 30 is a drawing for explaining an example of the configuration of the functional module of FIG. 29 according to various embodiments.

Fig. 31 is a drawing for explaining the operation of an air purifying device according to various embodiments.

There may be a plurality of first connection units (300) and second connection units (400). The second connection unit (400) may be configured to be fixed to the first connection unit (300) without rotational movement of the function module (200).

The first connection unit (300) of the main body module (100) and the second connection unit (400) of the function module (200) can be designed in consideration of the upper structure of the main body module (100) and the assembly process of the main body module (100) and the function module (200).

For example, in the main body module (100), an exhaust port (102) for exhausting air may be provided in the upper central portion of the main body housing (101). In the function module (200), a second intake port (205) into which air exhausted from the exhaust port (102) is introduced may be provided in the lower central portion of the sub-housing (201). The second connection unit (400) of the function module (200) and the first connection unit (300) of the main body module (100) may be arranged so as not to interfere with the air movement path.

For example, the first connection unit (300) of the main body module (100) may be arranged at a periphery of an end facing the function module (200). The first connection unit (300) may be arranged around the discharge port (102) at the top of the main body module (100). The second connection unit (400) of the function module (200) may be arranged at a periphery of an end facing the main body module (100) of the function module (200). The second connection unit (400) may be arranged around the periphery of the second intake port (205) at the top of the function module (200).

The output terminal (150) of the main body module (100) may be arranged in the first connection unit (300). The output terminal (150) may be arranged in a border portion of an end of the main body module (100) facing the function module (200). The connection terminal (220) of the function module (200) may be arranged in the second connection unit (400). The connection terminal (220) may be arranged in a border portion of an end of the function module (200) facing the main body module (100).

FIG. 7 is a diagram showing an example of the first and second connection units (300, 400) of the air purifier (1) of FIG. 6 according to various embodiments. FIG. 8 is a diagram showing a part of the first and second connection units (300, 400) of FIG. 7 according to various embodiments in isolation. FIG. 9a is a diagram showing the first connection unit (300) of FIG. 8 in isolation according to various embodiments, and FIG. 9b is a diagram showing the second connection unit (400) of FIG. 8 in isolation according to various embodiments. FIGS. 10 and 11 are cross-sectional views for explaining the operation of the first and second connection units (300, 400) of FIGS. 8 to 9b according to various embodiments.

Referring to FIGS. 6 to 11, the first connection unit (300) and the second connection unit (400) according to the embodiment may be configured to be assembled without rotational movement of the function module (200). For example, the first connection unit (300) and the second connection unit (400) may be configured to be fixed to each other by at least one of the vertical movement of the second connection unit (400) and the horizontal movement of the second connection unit (400). For example, the first connection unit (300) and the second connection unit (400) may be configured to be detachably fixed to each other by at least one of a push latch method and a lever lock method.

For example, the first connection unit (300) and the second connection unit (400) can be configured to be fixed (or connected) to each other through the up and down movement of the second connection unit (400) and the movement of the lever member (410) of the second connection unit (400). By fixing the first connection unit (300) and the second connection unit (400), the function module (200) and the main body module (100) can be electrically connected.

For example, the first connection unit (300) of the main body module (100) includes a base member (310) and an elevating member (320) that can move up and down with respect to the base member (310). A hook member (321) is arranged at the lower portion of the elevating member (320), and the base member (310) includes a hook engaging member (311) configured to secure the hook member (321) by a push latch method when the elevating member (320) is lowered. By the push latch method, the hook engaging member (311) can release the fixation to the hook member (321) when the elevating member (320) is lowered again.

The lifting member (320) may be elastically pressed in an upward direction. An elastic member (330) (e.g., a spring) for elastically pressing the lifting member (320) upward may be included between the lifting member (320) and the base member (310). An output terminal (150) for electrical connection with the function module (200) may be arranged on the edge of the lifting member (320).

The second connecting unit (400) of the function module (200) may include a lever member (410) and a locking member (420) that is radially and centrifugally movable in conjunction with the lever member (410). The second connecting unit (400) further includes a direction changing member (430) for changing the rotational movement of the lever member (410) into centrifugal movement of the locking member (420).

The direction changing member (430) may include a rotating member (431) that is fixed to the lever member (410) and rotates together with the lever member (410), and a guide member (432) that guides the centrifugal movement of the locking member (420). The locking member (420) may be fixed by a support member (433) by penetrating the rotating member (431) and the guide member (432).

The locking member (420) can move radially or centrifugally in conjunction with the operation of the lever member (410). When the lever member (410) is rotated, the locking member (420) can move centrifugally or radially in a direction opposite to the centrifugal direction by the direction changing member (430) depending on the rotational direction. A connection terminal (220) for electrical connection with the main body module (100) can be arranged on the locking member (420).

The locking member (420) may have a contact position (421) that surrounds and contacts the edge of the lifting member (320) of the first connecting unit (300), and a non-contact position (421) that moves radially from the contact position so as not to contact the edge of the lifting member (320).

When the second connection unit (400) is placed on the first connection unit (300) and the second connection unit (400) is pressed downward, as shown in Fig. 10, the hook member (321) of the first connection unit (300) can be fixed to the hook engagement member (311) of the base member (310). At this time, the locking member (420) can be in a non-contact position (422) that does not come into contact with the edge of the lifting member (320).

By rotating the lever member (410) while the hook member (321) is fixed to the hook coupling member (311), the locking member (420) can be moved to the contact position (421), as shown in FIG. 11. For example, a user can rotate the lever member (410) in the first direction to move the locking member (420) to the contact position. In the process of moving the locking member (420) to the contact position (421), the connection terminal (220) can be electrically connected to the output terminal (150).

As described above, by applying downward pressure to the second connection unit (400) and rotating the lever member (410), the function module (200) and the main body module (100) can be structurally assembled and electrically connected. The structural separation and electrical separation of the function module (200) and the main body module (100) can be performed in the opposite manner to the above-described method. For example, by rotating the lever member (410) in the opposite direction and re-pressuring the second connection unit (400) in the downward direction, the function module (200) and the main body module (100) can be structurally separated and electrically separated.

In the above-described embodiment, the assembly method of the first connection unit (300) and the second connection unit (400) has been described with a focus on examples using the lever lock method and the push latch method. However, the assembly method of the first connection unit (300) and the second connection unit (400) is not limited thereto and may vary.

FIG. 12 is a drawing showing an example of the first and second connection units (300A, 400A) of the air purifying device (1) of FIG. 6 according to various embodiments. FIG. 13 is an exploded perspective view showing an example of the first and second connection units (300A, 400A) of the air purifying device (1) of FIG. 12 according to various embodiments. FIG. 14 is a cross-sectional view for explaining the operation of the first and second connection units (300A, 400A) of FIG. 12 according to various embodiments.

Referring to FIGS. 12 to 14, the first connection unit (300A) and the second connection unit (400A) can be configured to be assembled by vertical movement. The first connection unit (300A) includes an elevating member (320a) and a base member (310a) provided to fix or release the position of the elevating member (320a) in the vertical direction. The first connection unit (300A) includes a cover member (350) for preventing/suppressing the detachment of the elevating member (320a).

The lifting member (320a) may include a first connecting portion (323) for assembly with a second connecting unit (400A). The second connecting unit (400A) may include a second connecting portion (450) for coupling to the first connecting portion (323).

The first coupling portion (323) and the second coupling portion (450) may be configured to be fitted together. For example, the shape of the outer surface of the first coupling portion (323) may correspond to the shape of the inner surface of the second coupling portion (450). The outer diameter of the first coupling portion (323) and the inner diameter of the second coupling portion (450) may correspond. For example, the outer diameter of the first coupling portion (323) may be the same as or slightly larger than the inner diameter of the second coupling portion (450). Here, the term “slightly larger” may refer to a size at which the first coupling portion (323) is inserted into the interior of the second coupling portion (450) by deformation without damage to the first coupling portion (323) or the second coupling portion (450).

In the process of moving the function module (200) up and down relative to the main body module (100), the second coupling part (450) can be fitted into the first coupling part (323). In this state, the second coupling part (450) can press the first coupling part (323) up and down.

The base member (310a) includes a receiving portion defining a receiving space for receiving a portion of the elevating member (320a) when the elevating member (320a) is lowered. The inner surface of the receiving portion includes a plurality of guide grooves (312) for guiding the elevating of the elevating member (320a) when the elevating member (320a) is raised and a stopper (3123) for restricting the up-and-down movement of the elevating member (320a). The plurality of guide grooves (312) may extend in the up-and-down direction.

The lifting member (320a) includes a vertical moving member (325) that moves up and down along the base member (310a), and a rotation inducing member (324) that induces rotation of the vertical moving member (325).

The outer surface of the up-and-down moving member (325) may include a plurality of guide protrusions (326a) that move along the guide groove (312). The plurality of guide protrusions (326a) include first and second guide protrusions (3261, 3262) that have different protrusion heights in the radial direction. The protrusion height of the first guide protrusion (3261) is higher than that of the second guide protrusion (3262). The first guide protrusion (3261) and the second guide protrusion (3262) may be arranged alternately on the outer surface of the lifting member (320a).

The plurality of guide grooves (312) may include a first guide groove (3121) that guides the up-and-down movement of the first guide protrusion (3261) and a second guide groove (3122) that guides the up-and-down movement of the second guide protrusion (3262). The stopper (3123) of the base member (310a) may limit the up-and-down movement of the first guide protrusion (3261) and allow the up-and-down movement of the second guide protrusion (3262). For example, the stopper (3123) may be provided in the second guide groove (3122).

The rotation induction part (324) may be arranged on the upper part of the up-and-down moving part (325). The edge of the rotation induction part (324) includes at least one rotation induction protrusion (3241). The rotation induction protrusion (3241) may be arranged on the upper part of the guide protrusion (326a). An inclined surface that induces rotation of the guide protrusion (326a) may be arranged on the lower part of the rotation induction protrusion (3241).

When the lifting member (320a) descends, the first guide protrusion (3261) descends along the first guide groove (3121), and the second guide protrusion (3262) descends along the second guide groove (3122). When the guide protrusion (326a) of the vertical moving unit (325) descends out of the guide groove (312), the vertical moving unit (325) is in a state where it can rotate in the circumferential direction. The guide protrusion (326a) of the vertical moving unit (325) is pressed by the rotation inducing protrusion (3241) of the rotation inducing unit (324) and can rotate. The guide protrusion (326a) rotates, so that the first guide protrusion (3261) can be arranged at the lower portion of the second guide groove (3122), and the second guide protrusion (3262) can be arranged at the lower portion of the first guide groove (3121).

Even if an elastic force is applied in the upward direction by the elastic member (330), the movement of the first guide protrusion (3261) in the upward direction is restricted by the stopper (3123) of the second guide groove (3122). Thus, the lifting member (320a) can be fixed in position in the vertical direction while inserted into the base member (310a).

When force is applied again in the up-down direction to the lifting member (320a), the guide protrusion (326a) of the up-and-down moving member (325) can be additionally rotated by the rotation induction member (324). The first guide protrusion (3261) can be positioned at the bottom of the first guide groove (3121), and the second guide protrusion (3262) can be positioned at the bottom of the second guide groove (3122). Since the lifting member (320a) is subjected to an upward elastic force by the elastic member (330), the first guide protrusion (3261) rises along the first guide groove (3121), and the second guide protrusion (3262) rises along the second guide groove (3122). Thus, the lifting member (320a) moves upward.

The structure for raising and lowering the above-described lifting member (320a) is an example of a structure for a push latch method, and is not necessarily limited thereto, and can be modified in various ways if it is a structure for assembly in the up-down direction.

FIG. 15 is a drawing showing an example of the first and second connection units (300B, 400A) of the air purifying device (1) of FIG. 6 according to various embodiments. FIG. 16 is an exploded perspective view showing an example of the first and second connection units (300B, 400A) of the air purifying device (1) of FIG. 15 according to various embodiments. FIG. 17 is a drawing for explaining an exemplary operation of the first and second connection units (300B, 400A) of FIG. 15 according to various embodiments.

For example, referring to FIGS. 15 to 17, the first connection unit (300B) and the second connection unit (400A) can be configured to be assembled by vertical movement. The first connection unit (300B) includes an elevating member (320b) and a base member (310b) provided to fix or release the position of the elevating member (320b) in the vertical direction. The first connection unit (300B) includes a cover member (350) for preventing/blocking the detachment of the elevating member (320b).

The first coupling portion (323) and the second coupling portion (450) may be configured to be fitted together. For example, the shape of the outer surface of the first coupling portion (323) may correspond to the shape of the inner surface of the second coupling portion (450). The outer diameter of the first coupling portion (323) and the inner diameter of the second coupling portion (450) may correspond. For example, the outer diameter of the first coupling portion (323) may be the same as or slightly larger than the inner diameter of the second coupling portion (450). Here, the term “slightly larger” may refer to a size at which the first coupling portion (323) is inserted into the interior of the second coupling portion (450) by deformation without damage to the first coupling portion (323) or the second coupling portion (450).

In the process of moving the function module (200) up and down relative to the main body module (100), the second coupling part (450) can be fitted into the first coupling part (323). In this state, the second coupling part (450) can press the first coupling part (323) up and down.

The base member (310b) includes a receiving portion that defines a receiving space for receiving a portion of the elevating member (320b) when the elevating member (320b) is lowered. On the inner surface of the receiving portion, a plurality of guide rails (313) are included that guide the elevating and rotating of the elevating member (320) when the elevating member (320b) is raised and lowered. The plurality of guide rails (313) may extend so as to be inclined in the up-down direction. A stopper (not shown) may be provided at an end of the guide rail (313) to maintain the position of the guide protrusion (326b).

The elevating member (320b) is inserted into the guide rail (313) and may include a guide projection (326b) that moves along the guide rail (313). When the elevating member (320b) descends, the guide projection (326b) moves along the guide rail (313), and the elevating member (320b) descends while rotating counterclockwise. When the elevating member (320b) rises, the guide projection (326b) moves along the guide rail (313), and the elevating member (320b) rises while rotating clockwise.

FIG. 18 is a drawing showing an example of the first and second connection units (300C, 400C) of the air purifying device (1) of FIG. 6 according to various embodiments. FIG. 19 is a drawing for explaining the operation of the first and second connection units (300C, 400C) of FIG. 18 according to various embodiments.

Referring to FIGS. 18 and 19, the first and second connection units (300C, 400C) according to the embodiment can be assembled by horizontal movement. For example, with the function module (200) placed on top of the main body module (100), the function module (200) can be moved horizontally and fixed to the main body module (100).

For example, the first connecting unit (300C) may include a protruding portion (340) protruding upward. The edge of the protruding portion (340) may include a locking protrusion (341) protruding in a horizontal direction.

The second connection unit (400C) may include a locking groove (440) that accommodates the first connection unit (300C). The locking groove (440) includes a first receiving portion (441) that accommodates a protruding portion (340) and a locking projection (341), and a second receiving portion (442) that is connected to the first receiving portion (441) and has a smaller size than the first receiving portion (441) to correspond to the protruding portion (340). After the function module (200) is positioned on the main body module (100) so that the first connection unit (300C) is inserted into the first receiving portion (441), the function module (200) may be moved horizontally as a whole so that the first connection unit (300C) may be positioned in the second receiving portion (442). The second receiving portion (442) can limit the up-and-down movement of the first connecting unit (300C) and the second connecting unit (400C) by limiting the up-and-down movement of the locking projection (341).

Although not shown, the first connection unit (300A, 300B, 300C) may be provided with an output terminal (150), and the second connection unit (400A, 400C) may be provided with a connection terminal (220). During the horizontal or vertical movement of the first connection unit (300) and the second connection unit (400), the output terminal (150) and the connection terminal (220) may be electrically connected. In this way, during the vertical or horizontal movement of the function module (200), the function module (200) and the main body module (100) may be electrically connected and structurally connected at the same time.

FIG. 20 is a drawing schematically illustrating an example of a structure for electrical connection between a function module (200) and a main body module (100) of an air purifying device (1) according to various embodiments. FIG. 21 is a drawing schematically illustrating an example of a structure for electrical connection between a function module (200) and a main body module (100) of an air purifying device (1) according to various embodiments. FIG. 22 is a drawing schematically illustrating an exemplary connection process using a structure for electrical connection between a function module (200) and a main body module (100) of an air purifying device (1) according to various embodiments.

Referring to FIGS. 20 to 22, output terminals (150a, 150b, 150c) and connection terminals (220a, 220b, 220c) for electrical connection can be configured to be connected by moving in the up-and-down direction or the horizontal direction.

For example, either one of the output terminals (150a, 150b, 150c) and the connection terminals (220a, 220b, 220c) may have a protruding structure. For example, either one of the connection terminals (220a, 220b, 220c) may have a protruding structure. For example, either one of the output terminals (150a, 150b, 150c) and the connection terminals (220a, 220b, 220c) may have a protruding structure. For example, as shown in FIG. 20, the output terminal (150a) may have a concave structure, and the connection terminals (220a, 220b, 220c) may have a protruding structure configured to be insertable into the concave structure. At least one of the output terminal (150a) and the connection terminal (220a) can move in the vertical direction so that the output terminal (150a) and the connection terminal (220a) can be connected to each other.

At least one of the output terminal (150b) and the connection terminal (220b) may have a structure that is elastically deformable in the vertical direction for connection stability. For example, at least one of the output terminal (150b) and the connection terminal (220b) may further include an elastic member (221) (e.g., a spring) that provides elastic force in the vertical direction. For example, the elastic member (221) may be arranged in a protruding structure. For example, as shown in FIG. 21, the elastic member (221) may be arranged inside the connection terminal (220b). Depending on the elasticity of the elastic member (221), the protruding length of the connection terminal (220b) may change. However, the arrangement of the elastic member (221) is not limited thereto and may vary. For example, although not illustrated, the elastic member (221) may be arranged in a concave structure. The output terminal (150b) may have a flat structure that can come into contact with the connection terminal (220b).

However, the structures of the output terminals (150a, 150b, 150c) and the connection terminals (220a, 220b, 220c) are not limited thereto and may vary. For example, although not illustrated, the output terminals (150a, 150b, 150c) may have a protruding structure, and the connection terminals (220a, 220b, 220c) may have a concave structure configured such that the protruding structure can be inserted.

The connection method of the output terminals (150a, 150b, 150c) and the connection terminals (220a, 220b, 220c) may vary in addition to the vertical direction. For example, at least one of the output terminals (150a, 150b, 150c) and the connection terminals (220a, 220b, 220c) may move in the horizontal direction and be electrically connected. For example, as shown in FIG. 22, when the connection terminal (220c) moves in the horizontal direction, the output terminal (150c) and the connection terminal (220c) may be electrically connected.

The main body module (100) and the function module (200) can be configured to operate in an assembled state as well as in a separated state. The function module (200) can be configured to operate in a separated state from the main body module (100).

FIG. 23 is a drawing for explaining an exemplary operation of an air purifying device (1) when a main body module (100) and a function module (200) according to various embodiments are separated, and FIG. 24 is a drawing for explaining an operation of an air purifying device (1) when a function module (200) according to various embodiments is assembled to a main body module (100). FIG. 25a is a drawing for explaining an example of use when a main body module (100) and a function module (200, 200A) according to various embodiments are assembled, and FIG. 25b is a drawing for explaining an example of use when a main body module (100) and a function module (200, 200A) according to various embodiments are separated. FIG. 26 is a block diagram showing an exemplary configuration of a main body module (100) and a function module (200) of an air purifying device (1) according to various embodiments.

Referring to FIGS. 23 and 24, the air purifying device (1) according to the embodiment can be configured to operate in a state where the function module (200) is assembled to the main body module (100) and in a state where it is separated from the main body module (100).

For example, the function module (200) may include a second power supply unit (230) configured to receive power separate from the power supplied to the power supply unit (140) of the main body module (100). The function module (200) may operate through power received through the second power supply unit (230) even when separated from the main body module (100).

The second power supply unit (230) may include a power adapter (232) configured to supply power to the function module (200). For example, the second power supply unit (230) may include a power adapter (232) that is detachably provided to the function module (200) and an input terminal (231) that is configured to be electrically connected to the power adapter (232). The second power supply unit (230) may be configured to receive alternating current (AC) power. The power adapter (232) may be configured to receive alternating current (AC) power. However, the power supplied to the second power supply unit (230) is not necessarily limited to alternating current power and may be direct current power.

The second power supply unit (230) of the function module (200) may further include a battery (not shown). The battery may be a rechargeable secondary battery. However, since the battery is an optional component of the function module (200), it may be omitted as needed. The second power supply unit (230) may also include a battery instead of a power adapter (232).

The function module (200) may include a switch (240) configured to selectively receive power from either the connection terminal (220) or the second power supply (230).

The switch (240) can change the path of power supplied to the function unit (210) depending on whether the second power supply unit (230) is connected to the function module (200). For example, the switch (240) can change the path of power supplied to the function unit (210) depending on whether the power adapter (232) of the second power supply unit (230) is mounted on the function module (200).

The switch (240) can be operated by the force of mounting the power adapter (232) of the second power supply unit (230). For example, the switch (240) can be pressed by the force of mounting the power adapter (232) to the input terminal (231) to electrically connect the function unit (210) and the second power supply unit (230). The switch (240) can be a switch (240) operated by an external force. For example, the switch (240) can be a micro switch (240), but is not limited thereto, and can be variously modified as long as it can be operated by an external force.

When the power adapter (232) of the function module (200) is assembled to the input terminal (231), the switch (240) can electrically connect the function unit (210) and the power adapter (232). When the power adapter (232) of the function module (200) is separated from the input terminal (231), the switch (240) can disconnect the electrical connection between the function unit (210) and the power adapter (232).

The switch (240) can change the path of power supplied to the function unit (210) or the auxiliary control unit (260) depending on whether the connection terminal (220) of the function module (200) is assembled to the output terminal (150) of the main body module (100). Power supplied to the auxiliary control unit (260) is transmitted to the function unit (210).

For example, when the connection terminal (220) of the function module (200) is assembled to the output terminal (150) of the main body module (100), the switch (240) can electrically connect the auxiliary control unit (260) and the connection terminal (220). For example, when the connection terminal (220) of the function module (200) is separated from the output terminal (150) of the main body module (100), the switch (240) can release the electrical connection between the auxiliary control unit (260) and the connection terminal (220).

The function module (200) may further include a DC power supply (245) arranged between the auxiliary control unit (260) and the switch (240). The DC power supply (245) may convert AC power into DC power. The DC power supply (245) may be a switching mode power supply (SMPS). However, the type of the DC power supply (245) is not limited thereto and may vary.

The main body module (100) may further include a module detection sensor (180) that detects the function module (200). The module detection sensor (180) may be configured to identify whether the function module (200) is assembled to the main body module (100). For example, the module detection sensor (180) may detect whether the function module (200) is assembled or approached. As an example, the module detection sensor (180) may be a magnet sensor. The main control unit (130) may detect a magnet mounted on the function module (200) through the module detection sensor (180) to determine whether the function module (200) is assembled to or approached the main body module (100).

The main control unit (130) of the main body module (100) can control the operation of the main body module (100) based on information detected by the module detection sensor (180). For example, the main control unit (130) can selectively supply power to the output terminal (150) based on information detected by the module detection sensor (180).

For example, the main control unit (130) may electrically connect or disconnect the output terminal (150) and the power supply unit (140) based on information detected by the module detection sensor (180). As an example for this, the main body module (100) may further include a main body switch (131) disposed between the output terminal (150) and the power supply unit (140). The main body module (100) may further include a DC power supply device (135) disposed between the main control unit (130) and the power supply unit (140). The main body switch (131) may be a relay switch, but is not necessarily limited thereto and may vary.

The main control unit (130) can selectively connect the output terminal (150) and the power supply unit (140) by controlling the on/off of the main body switch (131) based on the information detected by the module detection sensor (180). For example, if the module detection sensor (180) determines that the function module (200) and the main body module (100) are assembled, the main control unit (130) can control the main body switch (131) so that the output terminal (150) and the power supply unit (140) are electrically connected. If the module detection sensor (180) determines that the function module (200) and the main body module (100) are separated, the main control unit (130) can control the main body switch (131) so that the electrical connection between the output terminal (150) and the power supply unit (140) is released. The main body module (100) can prevent/suppress current supplied through the power adapter (232) from flowing to the output terminal (150) through the main body switch (131) when the function module (200) is not assembled.

For example, the main control unit (130) can control the operation of the main body module (100) based on information detected by the module detection sensor (180). For example, when the module detection sensor (180) determines that the function module (200) is assembled to the main body module (100), the main control unit (130) can control the operating speed of the main body module (100).

Referring to FIG. 2, FIG. 25A and FIG. 26, the function module (200, 200A) of the air purifier (1) may be a blower module. The function unit (210) may be assembled to the main body module (100). In the process of assembling the function module (200) to the main body module (100), the connection terminal (220) of the function module (200, 200A) and the output terminal (150) of the main body module (100) may be electrically connected. By the force of assembling the function module (200) to the main body module (100), the switch (240) may release the connection between the auxiliary control unit (260) and the second power supply unit (230), and connect the connection terminal (220) and the auxiliary control unit (260). The function module (200) can operate in conjunction with the main body module (100) through power supplied through the connection terminal (220).

The module detection sensor (180) of the main body module (100) can detect whether the function unit (210) is assembled. The main control unit (130) can control the operation of the air purifier (1) based on the information detected by the module detection sensor (180).

Depending on the operation mode set in the air purifier (1), the main control unit (130) can control the function unit (210) of the function module (200). For example, if the operation mode of the air purifier (1) is a mode that requires rapid diffusion of clean air indoors, the main control unit (130) can control the operation of the function module (200) to induce rapid diffusion of clean air. For example, as shown in FIG. 4, if the function unit (210) includes a fan and a blade (203), the main control unit (130) can adjust the rotation speed of the fan and the rotation angle of the blade (203) to rapidly discharge clean air at various angles.

Referring to FIG. 2, FIG. 25b and FIG. 26, the air purifying device (1) can operate in a state where the function module (200) and the main body module (100) are spaced apart from each other. The function module (200) can operate in conjunction with the main body module (100). As an example for this, the function module (200) can further include a communication unit (250) for communicating with an external device.

The communication unit (250) of the function module (200) can receive a signal authorized from the main body module (100). For example, the auxiliary control unit (260) can receive a user command from the main body module (100) through the communication unit (160). The communication unit (250) can communicate with an external device through a wireless communication method such as BT (Bluetooth), BLE (Bluetooth Low Energy), WI-FI (Wireless Fidelity), etc.

For example, when the function module (200) is separated from the main body module (100), the function module (200, 200A) can receive power through the second power supply unit (230) and operate in conjunction with the main body module (100). For example, when the function module (200, 200A) is separated from the main body module (100), a signal can be transmitted between the main body module (100) and the function module (200, 200A) by a wireless communication method.

For example, when the function module (200) is a blower module, the main control unit (130) can control the operation of the function module (200, 200A). For example, as shown in FIG. 25b, when the main body module (100) and the function module (200) are spaced apart in an indoor space, the main control unit (130) can control the blowing direction of the main body module (100) and the blowing direction of the function module (200) differently. For example, the main control unit (130) can control the blowing direction of the main body module (100) and the blowing direction of the function module (200) to face each other, or can control the blowing direction of the main body module (100) and the blowing direction of the function module (200) differently to induce air circulation indoors.

In various embodiments, the description has been made with an example in which the function module (200A) is a blower module that functions as a booster fan. However, the function and structure of the function module (200A) are not limited thereto and may vary.

For example, the functional module (200, 200A) may include at least one of a blower module having the blowing function described above, a humidifying module performing a humidifying function, and a charging module performing a charging function. The functional module (200, 200A, 200B, 200C) may include at least one of a blower module having the blowing function described above, a humidifying module performing a humidifying function, and a charging module performing a charging function.

Fig. 27 is a drawing showing an example in which the functional module (200B) of the air purifying device (1) according to various embodiments is a humidifying module. Fig. 28 is a drawing for explaining an example of the configuration of the functional module (200B) of Fig. 27 according to various embodiments.

Referring to FIGS. 27 and 28, an air purifying device (1) according to an embodiment may include a main body module (100) and a function module (200B). The function module (200B) may be a humidifying module having a humidifying function.

For example, the function module (200B) may include a steam generating unit (210a) (e.g., including a circuit) for generating steam and an auxiliary control unit (260) (e.g., including a circuit) for controlling the steam generating unit (210a).

The steam generating unit (210a) may be configured to generate steam. For example, the steam generating unit (210a) may be a heater for generating steam by a heating method. For another example, the steam generating unit (210a) may be an ultrasonic vibrator for generating steam by an ultrasonic method. For another example, the steam generating unit (210a) may be a fan for generating steam by an vaporization method. The auxiliary control unit (260) may control the operation of the steam generating unit (210a).

The function module (200B) may further include a sensor unit (281) for detecting humidity (for example, including at least one sensor). The sensor unit (281) may detect humidity. The sensor unit (281) may detect at least one of temperature and humidity. For example, the sensor unit (281) may detect both temperature and humidity. The auxiliary control unit (260) may control the operation of the steam generating unit (210a) based on the temperature and humidity detected by the sensor unit (281).

The auxiliary control unit (260) controls the operation of the steam generation unit (210a) by at least one of temperature and humidity detected through the sensor unit (281), and may include various circuits. The auxiliary control unit (260) can increase the amount of humidification by the steam generation unit (210a) when the humidity of the surrounding air is lower than the reference humidity. The auxiliary control unit (260) can decrease the amount of humidification by the steam generation unit (210a) when the humidity of the surrounding air is higher than the reference humidity.

The function module (200B) and the main body module (100) can operate in conjunction with each other. For example, if the sensor unit (281) of the function module (200B) detects information related to at least one of temperature and humidity, and the sensor unit (170) of the main body module (100) detects information related to the degree of contamination of the surrounding air, the main control unit (130) can control the blower unit (120) of the main body module (100) and the steam generating unit (210a) of the function module (200B) based on the information detected through the sensor units (170, 281) of the main body module (100) and the function module (200B), respectively. Through this, the air purifying device (1) can perform an efficient purifying function and a humidifying function.

For example, when it is determined by the sensor unit (170) of the main body module (100) and the sensor unit (281) of the function module (200B) that the cleanliness of the surrounding air is in a bad state that does not satisfy the standard concentration and that the humidity is in an appropriate state that satisfies the standard humidity, the main control unit (130) can rotate the blower unit (120) of the main body module (100) at high speed (or increase the rotation speed) and operate the water vapor generation unit (210a) of the function module (200B) to minimize/reduce the humidification amount.

For example, if it is determined by the sensor unit (170) of the main body module (100) and the sensor unit (281) of the function module (200B) that the cleanliness of the surrounding air is good enough to satisfy the standard concentration, but the humidity is low enough to not satisfy the standard humidity, the main control unit (130) can rotate the blower unit (120) of the main body module (100) at high speed for a certain period of time for rapid humidification and maintain the humidification amount by the vapor generation unit (210a) of the function module (200B) at a high level. If it is determined by the sensor unit (281) of the function module (200B) that the surrounding air has reached an appropriate humidity, the rotation speed of the blower unit (120) of the main body module (100) can be reduced. In this way, by simultaneously controlling the function module (200B) and the main body module (100), the humidity of the surrounding air can be rapidly increased.

The function module (200B) may further include an input/output unit (270) (e.g., including an input/output circuit). The input/output unit (270) may include an input interface for receiving a user command. For example, the input interface may include a plurality of buttons for receiving a user command. The input/output unit (270) may include a display for displaying various screens related to the operation of the humidifying module or the air purifying device (1). For example, the display may be implemented as various displays such as an LCD (Liquid Crystal Display), an OLED (Organic Light Emitting Diodes), etc. However, the input/output unit (270) may be an optional configuration and may be omitted from the function module (200B).

The function module (200B) may further include a communication unit (250). The communication unit (250) may receive a signal applied from the main body module (100). The main control unit (130) may transmit various data to an external device through the communication unit (160) and receive various data from the external device. For example, the auxiliary control unit (260) may receive a user command from the main body module (100) through the communication unit (250). The communication unit (250) may communicate with an external device through a wireless communication method such as BT (Bluetooth), BLE (Bluetooth Low Energy), WI-FI (Wireless Fidelity), etc. The function module (200B) and the main body module (100) may operate in conjunction with each other through the communication units (160, 250) while being spaced apart from each other.

Fig. 29 is a drawing showing an example in which the function module (200C) of the air purifying device (1) according to various embodiments is a charging module. Fig. 30 is a drawing for explaining an example of the configuration of the function module (200C) of Fig. 29 according to various embodiments.

Referring to FIGS. 29 and 30, an air purifying device (1) according to an embodiment may include a main body module (100) and a function module (200C). The function module (200C) may be a charging module having a charging function.

The function module (200C) may include at least one charging unit (210b) (e.g., including a charging circuit) and an auxiliary control unit (260) (e.g., including a circuit) that controls the charging unit (210b).

The charging unit (210b) may include a wireless charging unit capable of wirelessly charging an external device. The charging unit (210b) may further include a wired charging unit capable of charging an external device by being connected to the external device through a connection terminal.

The function module (200C) may include a charge detection unit (282) (e.g., including a detection circuit) that detects a charging state of the battery by the charging unit (210b). The charge detection unit (282) may detect whether charging of the battery is completed. If the charge detection unit (282) detects that charging of the battery is completed, the auxiliary control unit (260) may stop the operation of the charging unit (210b). The charge detection unit (282) may detect whether the battery is charged in the charging unit (210b). For example, the charge detection unit (282) may detect whether the battery of the external device is out of the chargeable range of the charging unit (210b). In other words, the charge detection unit (282) may detect whether a charging error occurs in which the battery of the external device is placed on the charging unit (210b) but charging does not proceed.

The function module (200C) can operate in conjunction with the main body module (100). For example, the function module (200C) can be assembled into the main body module (100) and operate in conjunction with the main body module (100). For example, the main control unit (130) of the main body module (100) can provide the operating status of the function module (200C) to the user through the input/output unit (190) of the main body module (100).

For example, when charging is completed in the function module (200C), the main control unit (130) of the main body module (100) can guide the user that charging is completed through the output interface of the main body module (100). For example, the main control unit (130) can visually guide the user of the charging completion status of the external device on the function module (200C) through the display of the main body module (100). For example, the main control unit (130) can visually and audibly guide the user of the charging completion status of the external device on the function module (200C) through the display and speaker of the main body module (100).

For example, if a charging error occurs in which charging is not performed on an external device in the function module (200C), the user may be notified through the output interface of the main body module (100) that the charging status needs to be confirmed. For example, the user may be visually notified through the display of the main body module (100) that the charging status needs to be confirmed. For example, the user may be visually and audibly notified through the display and speaker of the main body module (100) that the charging status needs to be confirmed.

The function module (200C) may further include a lighting unit (290) (e.g., including a light source). The lighting unit (290) may include a light source that radiates light around the function module (200C). However, since the lighting unit (290) is an optional component of the function module (200C), it may be omitted as needed.

The function module (200C) may further include a communication unit (250) (e.g., including a communication circuit). The communication unit (250) may receive a signal applied from the main body module (100). The communication unit (250) is a configuration that performs communication with an external device. The main control unit (130) may transmit various data to an external device and receive various data from the external device through the communication unit (160). The auxiliary control unit (260) may receive a user command from the main body module (100) through the communication unit (250). The communication unit (250) may perform communication with an external device through a wireless communication method such as BT (Bluetooth), BLE (Bluetooth Low Energy), WI-FI (Wireless Fidelity), etc. The function module (200C) and the main body module (100) may operate in conjunction with each other while being spaced apart from each other through the communication units (160, 250).

The function module (200C) may further include an input/output unit (270). The input/output unit (270) may include an input interface for receiving a user command. For example, the input interface may include a plurality of buttons for receiving a user command. The input/output unit (270) may include an output interface for displaying various screens related to the operation of the charging module. For example, the output interface may include a display. The display may be implemented as various displays such as an LCD (Liquid Crystal Display), an OLED (Organic Light Emitting Diodes), and the like. For example, the output interface may include a speaker for providing audio information.

Fig. 31 is a drawing for explaining the operation of an air purifying device (1) according to various embodiments.

Referring to FIGS. 1, 2, and 31, the main body module (100) may be configured to operate differently depending on the function modules (200A, 200B, 200C). For example, the module detection sensor (180) of the main body module (100) may be configured to detect the type of the function module (200). For example, the module detection sensor (180) may be an NFC sensor configured to identify an NFC (Near Field Communication) tag mounted on a function module (200A, 200B, 200C). The main control unit (130) may identify the NFC tags mounted on different function modules (200A, 200B, 200C) through the module detection sensor (180), thereby identifying the function modules (200A, 200B, 200C) assembled to the main body module (100). However, the type of sensor is not limited to this, and can be applied in various ways as long as it can identify the access of the function module (200A, 200B, 200C) or the function module (200).

The module detection sensor (180) of the main body module (100) can detect the type of the function module (200A, 200B, 200C). For example, the module detection sensor (180) can detect the type of the function module (200A, 200B, 200C) arranged on the upper part of the main body module (100). For example, the module detection sensor (180) can detect whether the function module (200A, 200B, 200C) arranged on the upper part of the main body module (100) is a blower module, a humidifying module, or a charging module. The module detection sensor (180) can detect whether the function module (200A, 200B, 200C) assembled to the main body module (100) is a blower module, a humidifying module, or a charging module.

The operation of the main body module (100) can be controlled based on the information detected by the module detection sensor (180). The main control unit (130) can control the operation of the main body module (100) differently depending on the type of the detected function module (200A, 200B, 200C).

For example, when the function module (200A) assembled in the main body module (100) is detected as a blower module performing a blower function by the module detection sensor (180), the main control unit (130) can adjust the rotation speed of the blower unit (120) of the main body module (100). For example, the main control unit (130) can adjust the rotation speed of the blower unit (120) of the main body module (100) in consideration of the operation of the function module (200A).

For example, when the function module (200B) assembled in the main body module (100) is detected as a humidifying module performing a humidifying function by the module detection sensor (180), the main control unit (130) can adjust the rotation speed of the blower unit (120) of the main body module (100). For example, when the humidifying amount by the function module (200B) is low, the main control unit (130) can reduce the rotation speed of the blower unit (120) or maintain it in a low state.

For example, when the function module (200C) assembled in the main body module (100) is detected as a charging module performing a charging function by the module detection sensor (180), the main control unit (130) can adjust the rotation speed of the blower unit (120) of the main body module (100). For example, the rotation speed of the blower unit (120) can be adjusted by considering changes in the air flow path due to the arrangement of the function module (200C), changes in the temperature of the surrounding air, etc.

For the purpose of understanding the invention, reference numerals have been used in various embodiments illustrated in the drawings, and specific terms have been used to describe various embodiments; however, the invention is not limited by these specific terms, and the invention may include all components that can be commonly conceived by those skilled in the art.

The various exemplary implementations described in the invention are various exemplary embodiments and are not intended to limit the scope of the invention in any way. For the sake of brevity of the specification, descriptions of conventional electronic configurations, control systems, software, and other functional aspects of the systems may be omitted. In addition, the connections or lack of connections of lines between components illustrated in the drawings are merely exemplary representations of functional connections and/or physical or circuit connections, and may be represented as various functional connections, physical connections, or circuit connections that are replaceable or additional in an actual device. In addition, if there is no specific mention such as “essential,” “important,” etc., it may not be a component that is absolutely necessary for the application of the invention. The expressions “including,” “having,” etc. used herein are used to be understood as terms of the open-ended end of the technology.

The use of the term "above" and similar referential terms in the specification of the invention (especially in the claims) may be in both singular and plural. In addition, when a range is described in the invention, it is included in the invention that applies individual values belonging to the range (unless otherwise stated), and it is the same as describing each individual value constituting the range in the detailed description of the invention. Finally, unless the order of the steps constituting the method according to the present invention is explicitly stated or otherwise stated to the contrary, the steps may be performed in any suitable order. The invention is not necessarily limited by the order in which the steps are described. The use of all examples or exemplary terms (e.g., etc.) in the present invention is merely for the purpose of describing the invention in detail, and the scope of the invention is not limited by the examples or exemplary terms unless otherwise limited by the claims. In addition, it will be apparent to those skilled in the art that various modifications and changes can be easily made without departing from the scope and spirit of the invention.

The air purifier according to the embodiment and the functional module used therein can be used by assembling the functional module that assists the air purification function, which is the original function of the air purifier, or performs a different function, to the main body module of the air purifier according to the needs of the user, or can be used separately from the main body module. In other words, the functional module that can be used as a part of the air purifier can be used not only by combining it with the main body module, but also by being used separately from the main body module.

In addition, the functional modules according to the embodiment may vary in type, and depending on the type of the functional module assembled or connected to the main body module, the air purifier may be capable of various operations.

An air purifier according to an embodiment may include: a main control unit including at least one filter, a blower for inducing airflow to pass through the filter, a circuit for controlling operation of the blower, a main body including a power supply unit configured to supply power to the main control unit, and an output terminal configured to output power received from the power supply unit to the outside; and at least one functional module including a functional unit detachably assembled to the main body and configured to perform a function assisting the main body or a function different from that of the main body, an auxiliary control unit including a circuit for controlling operation of the functional unit, a connection terminal provided to be electrically connectable to the output terminal, and a second power supply unit configured to receive power separate from power from the power supply unit.

The above function module may further include a switch configured to selectively receive power from either the connection terminal or the second power supply.

The second power supply unit includes a power adapter that is detachably provided to supply power to the function module, and an input terminal that is electrically connectable to the power adapter, and the switch can electrically connect the input terminal and the auxiliary control unit based on connection to the input terminal of the power adapter, and electrically connect the connection terminal and the auxiliary control unit based on separation from the input terminal of the power adapter.

The above main body further includes a module detection sensor that detects the function module, and the main control unit can be configured to control the operation of the main body based on information detected by the module detection sensor.

The above main control unit may be configured to selectively supply power to the output terminal based on information detected by the module detection sensor.

The above module detection sensor detects the type of the functional module assembled into the main body, and the main control unit can be configured to control the operation of the blower unit differently depending on the type of the detected functional module.

The above function module may include at least one of a blowing module configured to perform a blowing function, a humidifying module configured to perform a humidifying function, and a charging module including a circuit configured to perform a charging function.

The above main body and the above function module can be assembled to overlap in the vertical direction, and the above connection terminal can be placed on the edge portion of the end of the above function module facing the main body.

The above body includes a first connecting unit including a terminal arranged to face the above function module, the above function module includes a second connecting unit including a terminal arranged to face the first connecting unit and to be detachably fixed to the first connecting unit, and the first connecting unit and the second connecting unit can be configured to be detachably fixed to each other by at least one of a push latch method and a lever lock method.

The above power supply unit and the second power supply unit can be configured to receive AC power.

A functional module including a circuit detachably assembled into a main body of an air purifying device according to one embodiment may include a functional unit including a circuit configured to perform a function assisting the main body or a function different from that of the main body; a connection terminal electrically connectable to an output terminal configured to output power externally from the main body; and a second power supply unit configured to receive power separate from power of a power supply unit configured to supply power to the main body.

The function module may further include a switch configured to selectively receive power from either the connection terminal or the second power supply.

The above functional module may be at least one of a blower module including a blower configured to perform a blowing function, a humidifying module including a humidifier configured to perform a humidifying function, and a charging module including a charging circuit configured to perform a charging function.

The above main body and the above function module can be assembled to overlap in the vertical direction, and the above connection terminal can be placed on the edge portion of the end of the above function module facing the main body.

While the present disclosure has been illustrated and described with reference to various exemplary embodiments, it will be understood that the various exemplary embodiments are intended to be illustrative and not limiting. It will be further understood by those skilled in the art that various changes in form and detail may be made therein without departing from the true spirit and full scope of the present disclosure, including the appended claims and their equivalents. It will also be understood that any embodiment(s) described herein can be used with any other embodiment(s) described herein.

Claims (15)

A main body (100) including at least one filter unit (110) including a filter, a blower unit (120) including a blower for inducing air flow to pass through the filter unit, a main control unit (130) including a circuit for controlling the operation of the blower unit, a power supply unit (140) configured to supply power to the main control unit, and an output terminal (150) configured to output power received from the power supply unit to the outside; and An air purifier device comprising: a functional unit (210) that is detachably assembled to the main body and includes a circuit configured to perform a function that assists the main body or a function different from that of the main body; an auxiliary control unit (260) that includes a circuit that controls the operation of the functional unit; a connection terminal (220) that is electrically connectable to the output terminal; and at least one functional module (200) that includes a second power supply unit (230) that is configured to receive power separate from the power supplied to the power supply unit. In the first paragraph, An air purifier, wherein the above function module further includes a switch (240) configured to selectively receive power from either the connection terminal or the second power supply. In the second paragraph, The above second power supply unit, A power adapter (232) that is detachably provided to supply power to the above function module, It includes an input terminal (231) that can be electrically connected to the above power adapter, The above switch is, Based on the connection with the input terminal of the above power adapter, the input terminal and the auxiliary control unit are electrically connected, An air purifier device, which electrically connects the connection terminal and the auxiliary control unit based on separation from the input terminal of the power adapter. In any one of claims 1 to 3, The above body further includes a module detection sensor (180) that detects the above function module, An air purifying device in which the main control unit controls the operation of the main body based on information detected by the module detection sensor. In paragraph 4, An air purifier device in which the main control unit selectively supplies power to the output terminal based on information detected by the module detection sensor. In clause 4 or 5, The above module detection sensor detects the type of the functional module assembled into the main body, An air purifier, wherein the main control unit controls the operation of the blower unit differently based on the type of the detected function module. In any one of claims 1 to 6, An air purifying device, wherein the above functional module is at least one of a blower module including a blower performing a blowing function, a humidifying module including a humidifier performing a humidifying function, and a charging module including a charging circuit performing a charging function. In any one of claims 1 to 7, The above main body and the above function module can be assembled so as to overlap in the vertical direction, The above connection terminal (220) is an air purifying device arranged on the edge of the end facing the main body from the above function module. In any one of claims 1 to 8, The above body includes a first connecting unit (300) including a connecting body arranged to face the above function module, The above function module comprises a second connecting unit (400) opposite the first connecting unit and including a connecting body arranged to be detachably fixed to the first connecting unit, An air purifying device, wherein the first connection unit and the second connection unit are configured to be detachably fixed to each other by at least one of a push latch method and a lever lock method. In any one of claims 1 to 9, An air purifying device, wherein the power supply unit and the second power supply unit are configured to receive alternating current power. A functional module (200) that is detachably assembled into the main body of the air purifier and includes a circuit configured to assist the air purifier, A functional unit (210) including a circuit configured to perform a function assisting the main body or a function different from that of the main body; A connection terminal (220) provided so as to be electrically connected to an output terminal configured to output power externally from the above main body; and A functional module of an air purifier, comprising a second power supply unit (230) configured to receive power separate from the power supplied to the power supply unit of the main body. In Article 11, A functional module of an air purifier further comprising a switch (240) configured to selectively receive power from either the connecting terminal or the second power supply. In clause 11 or 12, The above functional module is at least one of a blower module including a blower performing a blowing function, a humidifying module including a humidifier performing a humidifying function, and a charging module including a charging circuit performing a charging function. In any one of Articles 11 to 13, The above main body and the above function module can be assembled so as to overlap in the vertical direction, The above connection terminal is a functional module of an air purifier device, which is arranged on the edge of the end facing the main body from the functional module. In any one of Articles 11 to 14, A functional module of an air purifier, wherein the second power supply unit is configured to receive AC power.

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