KR20220084959A - Hygiene management device for entrance hall - Google Patents

Abstract

The present invention is a sanitary management device for an entrance. In the present invention, the air injector 500 that injects air to the floor of the entrance space is operated within a predetermined angle range in the entrance and exit direction of the occupant, and the air injected from the injection port 518 of the air injector 500 is supplied by an air guide unit ( 550) can be guided. A plurality of vanes 560 and 560' are installed in a row in the air guide unit 550 to control the direction of the air sprayed from the injection hole 518.

Description

Hygiene management device for entrance hall}

The present invention is a sanitary management device for managing hygiene for people entering and leaving an entrance.

There is an entrance for the connection between the exterior and a specific interior space, and a space such as the entrance with this entrance must be passed through to go to a specific interior space. In order for a person to go to an indoor space, they must pass through the entrance, which is an entrance space. When the work of removing pollution outdoors is polluted outdoors, there is a problem of passing on the pollution to the surrounding or surrounding people. Therefore, it is desirable to process the contamination by removing the contamination of the person entering the entrance hall.

There is a simple air curtain to prevent pollutants from being transmitted into the indoor space. This is the degree to which the outside air is blocked, but when a person enters and exits, the outside air can enter the interior space together.

In order to solve this problem, as Prior Document 1, Korean Patent Application Laid-Open No. 10-2009-0040630, an air shower device for a home entrance, has been proposed. In Prior Document 1, it was attempted to remove contamination such as dust on the clothes of the entrants by performing an air shower for the occupants. However, although the discharged air flows from the top to the bottom of the occupant and removes contamination, the air applied to the occupant flows from the top to the bottom. There was a problem that the contamination of shoes and the like could not be properly removed. In addition, there is a problem that contaminants such as dust remain on the floor of the entrance hall because the intake port through which air is sucked in the entrance is on the side of the entrance space, and there is a problem that outdoor pollutants are introduced into the entrance during the entrance and exit of the entrance. .

Prior Document 2, Korean Patent Laid-Open Patent No. 10-2020-0046715, integrated lighting system and control method for access space, integrated lighting fixture and air cleaning device to remove contamination of entry and exit spaces such as entrances. . However, Prior Document 2 also has a problem in that the structure for simply spraying air from the top to the bottom is integrated into the lighting fixture, and the contamination in the entrance space is not properly removed because the suction port is on the side of the entrance space. Here, too, there is a problem in that outdoor pollutants are introduced into the entrance during the entry and exit process of the entrants.

Prior Document 3, Korean Patent Laid-Open Patent No. 10-2019-0055303, integrated front door air shower device, separately installed a shower booth having a predetermined shower space inside, so that visitors can remove contaminants from the shower booth. However, since the shower booth is separately partitioned in the space in the entrance hall, the space occupied by the entire device inside the entrance hall becomes large, so there is a problem that the effectiveness is reduced. there was.

As such, most of the prior documents adopt a structure in which air is simply sprayed from the upper part of the entrance space to the lower part, so there is a problem that the hair style of the entrant is damaged, and the air is not transmitted directly to the lower body of the entrant. There was a problem that the operation performance was relatively poor.

(Prior Document 0001) Korean Patent Laid-Open No. 10-2009-0040630 (Prior Document 0002) Korean Patent Laid-Open No. 10-2020-0046715 (Prior Document 0003) Korean Patent Laid-Open No. 10-2019-0055303

It is an object of the present invention to spray air so that air flows in various directions from the upper part to the lower part of the entrant in the sanitary management device for the entrance.

It is an object of the present invention to be able to adjust the discharge of air within a predetermined angle range in both directions of the entrant in the sanitary management device for the entrance.

It is an object of the present invention to be able to adjust the discharge of air within a predetermined angle range in the entrance/exit direction of the entry/exit in the sanitary management device for the entrance.

An object of the present invention is to make the amount of air discharged from the nozzles of the sanitary management device for entrance and exit uniform.

An object of the present invention is to make the amount of air flowing through the injection hole of the sanitary control device for entrance and exit constant in the entire area of the injection hole.

The sanitary management device for the entrance of the present invention may include an air jet for discharging air in various directions from the top to the bottom in the entrance space.

The present invention is provided with an air guide unit for guiding the air delivered through the duct to the injection port of the air injector, so that air can be discharged from the injection port to both sides of the person in a predetermined angle range.

In the present invention, the air blower provided with the air guide unit may discharge air within a predetermined angle range in the entry/exit direction of the occupant by the first and second lifting mechanisms.

In the sanitary management device for entrances and exits of the present invention, the positions of the vanes of the air guide unit located upstream of the duct and the vanes of the air guide unit located downstream of the duct are different to make the amount of air discharged from each injection port uniform.

In the sanitary management device for entrance and exit of the present invention, a plurality of vanes are arranged in a row in the air guide unit, so that air can be uniformly discharged from the entire area within the injection port.

In the present invention, the air guide unit is a vane frame communicating between the duct and the injection port, a plurality of vanes installed side by side to rotate at a predetermined angle to the vane frame to guide the air, and a vane providing a driving force for driving the vanes It may include a motor.

In the present invention, the air guide unit may further include a vane driving member connected to the plurality of vanes to rotate the vanes at a predetermined angle, and a driving link for operating the vane driving member by the driving force of the vane motor.

In the present invention, a connection between the vane driving member and the driving link may be connected by a connecting pin passing through a moving slot formed in the vane frame.

In the present invention, a rotating roll is installed concentrically and rotatably on the connecting pin to move within the moving slot.

In the present invention, the vane may be composed of an upstream part starting to guide air, a downstream part discharging the guided air, and a connecting curved part connecting the upstream part and the downstream part. The start of the upstream part may protrude further into the duct as it goes downstream of the duct.

In the present invention, the duct may include a first duct extending along the wall of the entrance space and a second duct extending along the ceiling of the entrance space. A first outlet may be formed at a relatively upstream side of the second duct, and a second outlet may be formed at a relatively downstream side of the second duct.

In the present invention, a corrugated pipe may be installed between the first outlet and the vane frame, and between the second outlet and the vane frame.

In the present invention, in the air injector, the injector frame may form a skeleton, and a first elevating mechanism and a second elevating mechanism connected to the ceiling of the duct or entrance space and the other end connected to the injector frame are both sides of the injector frame. It is installed in the operating angle can be set by the first and second lifting mechanism.

In the present invention, a relative rotatable connection link or universal joint may be further provided between the injector frame and the ceiling of the duct or entrance space.

The present invention provides a fan assembly configured to generate a flow of air, a duct that forms a flow passage for air generated by the operation of the fan assembly, and air through a spray port within a predetermined angular range in the entry/exit direction from the entrance space. It may include an air injector configured to have an angle adjusted to spray and provided with an air guide unit for guiding the air sprayed through the injection hole toward the side of the person. In the air guide unit, a plurality of vanes installed in a vane frame that communicates between the duct and the injection port are driven by a vane motor to adjust the angle.

In the present invention, the vane may be installed in a plurality of rows from the upstream to the downstream of the duct at the vane frame at a predetermined interval.

In the present invention, the vane may be composed of an upstream part starting to guide air, a downstream part discharging the guided air, and a connecting curved part connecting the upstream part and the downstream part.

In the present invention, the upstream portion of the vane may extend obliquely from the inside of the duct toward the upstream of the duct, and the downstream portion of the vane may extend obliquely toward the middle portion of the bottom of the entrance space.

In the present invention, the start of the upstream portion may protrude further into the duct toward the downstream of the duct.

The length from the start point of the upstream part to the end point of the downstream part of the vane may be formed to be longer than the vane installed in the upstream of the duct.

In the present invention, the upstream portion and the downstream portion of the vane may have virtual extension surfaces parallel to each other. An imaginary extension surface of the upstream portion and the downstream portion of the vane may form an obtuse angle.

In the present invention, a corrugated pipe is installed between the duct and the vane frame to prevent air leakage.

The sanitary management device for an entrance according to the present invention may have at least one or more of the following effects.

In the hygiene management device of the present invention, the air sprayer sprays air in various directions from the upper part to the lower part of the occupant located in the entrance space to remove foreign substances such as dust on the occupant's clothes. In particular, since the direction in which the injection port of the air jet is directed can be set within a predetermined angle range in the entry/exit direction of the occupant, hygiene management can be performed according to various situations.

In particular, in the present invention, while the angle of the air injector is adjusted, air can be sprayed to the lower part of the entrance space in a predetermined angular range in the entry/exit direction of the occupant, and at the same time, by the air guide unit, over a predetermined angular range in the lateral direction of the entrant. Since air can be sprayed, sanitary management can be performed by spraying air from the top to the bottom in various directions with respect to the occupants.

In the present invention, the position of the upstream portion of the vane located relatively downstream than the vane located relatively upstream of the duct can be made to more protrude into the duct. According to this structure, the amount of air passing through the nozzle on the upstream side of the duct or the injection hole on the downstream side of the duct can be made uniform. Accordingly, the air sprayed to the occupants may be constant in various directions.

In the present invention, when the air delivered through the duct is sprayed through the injection hole, a plurality of vanes for each injection hole can be arranged in a row in order from the upstream to the downstream direction of the duct and dispatched. According to such a structure, the flow of air injected through the injection hole may be constant throughout the injection hole.

In the present invention, the driving link for rotating the vane at a predetermined angle and the main driving member may be connected by a connecting pin. With this structure, a plurality of vanes are rotated simultaneously with the driving force of the vane motor to change the air discharge direction from the entire injection hole. It can be set constant.

In the present invention, the connecting pin is provided with a rotating roll, so that the connecting pin can be moved more smoothly by the rotation of the rotating roll in the moving slot. Accordingly, the operation of adjusting the angle of the vane can be performed more easily.

In the present invention, the vane is composed of an upstream part, a connecting curved part, and a downstream part. The upstream part protrudes obliquely toward the upstream of the duct to smoothly receive the air flowing through the duct, and the downstream part is toward the center of the floor of the entrance space. It is formed to be inclined, so that the injection of air can be made smoothly through the injection port.

In the present invention, between the duct and the vane frame may be connected by a corrugated pipe. Therefore, even if the vane frame is operated together with the injector frame, air leakage through between the duct and the vane frame does not occur, so that air can be more efficiently injected from the air injector.

In the present invention, the operating angle of the air injector can be set by adjusting the height of both edges of the injector frame using the first lifting mechanism and the second lifting mechanism. Accordingly, the direction of the jetted air can be varied while the angle of the air jet is easily adjusted.

When the connecting link or universal joint is used in the present invention, the air blower can be more firmly supported on the ceiling of the entrance space or the bottom of the duct, so that the air blower can be operated stably.

1 is a one-way perspective view showing the configuration of a preferred embodiment of the sanitary management device for the entrance according to the present invention.
Figure 2 is a rear perspective view showing the configuration of the embodiment of the present invention.
3 is a schematic cross-sectional view showing the configuration of an embodiment of the present invention;
Figure 4 is a cross-sectional perspective view showing the configuration of the scaffold constituting the embodiment of the present invention.
Figure 5 is a partial perspective view showing the configuration of the base frame constituting the scaffold of the embodiment of the present invention.
Figure 6 is a schematic cross-sectional view showing the internal configuration of the air management module of the embodiment of the present invention.
7 is a perspective view showing an open state of the air management module of the embodiment of the present invention.
Figure 8 is a cross-sectional perspective view showing the configuration of the second outlet portion of the air injector and the duct of the embodiment of the present invention.
9 is a longitudinal cross-sectional perspective view of the duct showing the configuration of the air injector and the second outlet portion of the duct according to the embodiment of the present invention.
Figure 10 is a perspective view showing that the first and second lifting mechanism is provided in the air injector of the embodiment of the present invention.
11 is a cross-sectional view taken along line D11-D11 of FIG. 10;
12 is a schematic side view showing the configuration of another embodiment of the elevating mechanism of the present invention.
Fig. 13 is a schematic view showing the elevating mechanism shown in Fig. 12 from another direction;
14 is a schematic side view showing the configuration of another embodiment of the elevating mechanism of the present invention.
15 is a perspective view showing the configuration of the air guide unit used in the present invention.
16 (a) is a side view showing the configuration of an important part of the air guide unit on one side, and (b) is a side view showing the configuration of an important part of the air guide unit on the other side.
17 is an operation state diagram showing that the user is positioned on the footrest and the operation is made in the embodiment of the present invention.
18 is an operation state diagram showing a state in which the air injector is inclined toward the outdoor door in the embodiment of the present invention.
19 is an operation state diagram showing a state in which the air injector is inclined toward the interior door in the embodiment of the present invention.
20 is an operation state diagram showing that the first elevating mechanism is operated in the embodiment of the present invention.
Figure 21 is an operation state diagram showing that air is discharged through the injection port by the air guide unit in the embodiment of the present invention.
22 (a) is a state in which air can be sprayed toward the lower center of the entrance space, (b) is an operation state diagram showing a state in which air can be sprayed toward the lower part of the entrance space.

Preferred embodiments of the sanitary management device for the entrance according to the present invention will be described in detail with reference to the accompanying drawings.

The sanitary management device of an embodiment of the present invention may be installed in an entrance space carried into a specific indoor space. When this sanitary management device is used for a residential space, the sanitary management device may be installed in the entrance hall. When this sanitary management device is used for an office space, it may be installed in a space separately partitioned at the entrance of the office space. A space separately partitioned between the entrance and the entrance is called an entrance space 10 , and the entrance space 10 can be seen in FIGS. 18 and 19 .

A footrest 100 may be installed on the floor of the entrance space 10 . The footrest 100 has a predetermined area, and may have an area on which at least one or more people can climb. In the drawing, the footrest 100 has a rectangular plate shape. However, depending on the shape of the floor of the entrance space 10 , the shape of the scaffold 100 may be in various plate shapes. At least one entrant may be positioned on the scaffold 100 .

The footrest 100 may serve to support the entrants. The footrest 100 may suck air in the entrance space 10 by driving the fan assembly 300 to be described below. The base plate 110 may form the skeleton of the scaffold 100 . The base plate 110 may form the bottom of the scaffold 100 . As can be seen in FIG. 5 , the sidewall 112 surrounding the edge of the base plate 110 may be formed to protrude to a predetermined height. The base plate 110 may be integrally formed as a whole. However, the base plate 110 may be formed by being divided into several pieces.

A seating surface 114 may be formed on the upper surface of the base plate 110 . The seating surface 114 may be formed on most of the upper surface of the base plate 110 . A guide rib 116 may be formed on the seating surface 114 to extend in one direction. The guide rib 116 may extend to horizontally cross the entrance space 10 . The guide rib 116 may extend side by side with the outdoor door 12 or the indoor door 14 (refer to FIG. 18 ) of the entrance space 10 . The guide rib 116 may serve to guide the installation position of the support bar 130 to be described below. A plurality of the guide ribs 116 may be formed side by side on the seating surface 114 at a predetermined interval. A support bar 300 may be positioned between the guide ribs 116 .

A suction area 118 may be formed on a predetermined area of the upper surface of the base plate 110 . The suction area 118 is indicated by a dotted line in FIG. 5 . The suction area 118 may have a relatively low surface compared to the seating surface 114 .

A suction passage 120 may be formed in the suction region 118 . A plurality of the suction passages 120 may be formed side by side. The suction passage 120 may extend to one edge of the base plate 110 past the suction area 118 . The suction passage 120 may have the lowest surface of the base plate 110 . Through the suction passage 120 , the air sucked through between the support members 130 to be described below may be delivered to the air management module 200 to be described below.

A seating end 122 may be formed in the suction region 118 between the suction passages 120 . The seating end 122 may have a surface higher than the surface of the suction passage 120 and a surface lower than the surface of the seating surface 114 . A substrate 124 may be positioned on the seating end 122 . The seating end 122 has a surface of a certain height in the entire suction area 118 in the drawing, but in the middle for solid support of the support bar 130, it is at the same height as the surface of the seating surface 114 in the middle. A protrusion having a surface may be formed. The protrusion may be formed over the entire width of each of the seating ends 122 . The protrusion may be formed in a portion of the width of each of the seating ends 122 .

A light source 126 may be mounted on the substrate 124 . The light source 126 may generate ultraviolet (Far-UV) light for sterilization and disinfection. A plurality of the light sources 126 may be installed on the substrate 124 with a predetermined interval therebetween. The light transmitting member 128 may be used to transmit the ultraviolet light emitted from the light source 126 . The light transmitting member 128 is for transmitting ultraviolet light to the upper portion of the scaffold 100 . In the illustrated embodiment, the light transmission member 128 has a strip shape extending along the seating end 122 and having a relatively high height compared to the width. The light transmitting member 128 may transmit ultraviolet light emitted from a plurality of light sources 126 mounted on the substrate 124 to the upper portion of the scaffold 100 .

A plurality of support bars 130 may be installed on the base plate 110 . A plurality of the support bars 130 may be installed on the base plate 110 adjacent to each other in turn. One surface of the support bar 130 may form an upper surface of the scaffold 100 . The support bar 130 may be seated on the seating surface 114 of the base plate 110 . The support bar 130 may be seated between the guide ribs 116 .

The support bar 130 may have a rectangular cross-section. The support bar 130 may extend long in one direction. A through hole 132 may be formed through the inside of the support bar 130 . That is, the support bar 130 may be elongated in the shape of a hollow quadrangular pole. As such, when the support bar 130 has a hollow shape, it is possible to reduce the weight of the entire scaffold 100 while securing durability against external force.

The support bar 130 may be supported by being seated on the seating surface 114 of the base plate 110 . A portion of the support bar 130 passing through the suction region 118 may be supported by being seated on the protrusion of the seating end 122 or the substrate 124 positioned at the seating end 122 . An inclined surface 134 may be formed along both ends of the upper surface of the support bar 130 in the width direction. As the inclined surface 134 is formed, the ultraviolet light transmitted through the light transmission member 128 may be spread and transmitted to the upper portion of the scaffold 100 . In addition, the side of the inclined surface 134 without the light transmission member 128 may allow the air to be sucked into the suction passage 120 more smoothly.

Each of the support bars 130 may have a length corresponding to, for example, a length between one end of the base plate 110 and the other end. One support bar 130 may be sequentially disposed in a direction in which the guide rib 116 or the suction passage 120 extends to form the surface of the footrest 100 .

At a position corresponding to the suction passage 120 , a suction slot 136 may be formed between adjacent support bars 130 . A gap between the adjacent support bars 130 becomes the suction slot 136 so that air in the entrance space 10 can be sucked by the fan assembly 300 . The suction slot 136 may have a width corresponding to the thickness of the guide rib 116 . Foreign substances larger than the width of the suction slot 136 may be blocked from entering the suction passage 120 . Accordingly, the support bars 130 may serve as a kind of filter to block a relatively large foreign material from entering the suction passage 120 .

There is an air management module 200 to manage the air flowing through the suction passage 120 . The air management module 200 may remove foreign substances mixed in the air sucked through the suction passage 120 and manage the humidity and temperature of the air.

A fixed frame 210 may form the skeleton of the air management module 200 . An inner space 212 may be formed inside the fixing frame 210 . The inner space 212 may pass through the fixed frame 210 in the front-rear direction. An entry/exit frame 216 may be installed in the inner space 212 to be rotated at a predetermined angle with respect to the fixed frame 210 by an entry/exit hinge 214 . One side of the entry/exit hinge 214 may be fixed to both inner surfaces of the inner space 212 of the fixed frame 210 , and the other side may be fixed to both outer surfaces of the entry/exit frame 216 . Accordingly, the entry/exit frame 216 may be rotated at a predetermined angle around the entry/exit hinge 214 to enter and exit the inner space 212 . 7 shows a state in which the entry/exit frame 216 protrudes to the outside.

A communication path 218 may be formed by passing through the entry/exit frame 216 back and forth. The communication path 218 may be a path through which air sucked through the suction path 120 passes. A first slot 220 , a second slot 222 , and a third slot 224 may be formed side by side in the input/exit frame 216 . As shown in FIG. 7 , the first slot 220 , the second slot 222 , and the third slot 224 may be opened to the upper surface of the entry/exit frame 216 .

A first filter 221 may be positioned in the first slot 220 , a second filter 223 may be positioned in the second slot 222 , and a third filter 223 may be positioned in the third slot 224 . 225 may be located. The communication path 218 passes through the entry/exit frame 216 back and forth, and the first slot 220 , the second slot 222 , and the third slot 224 are opened to the upper surface of the entry/exit frame 216 . It can be extended vertically. Accordingly, the first filter 221 , the second filter 223 and the third filter 221 in the first slot 220 , the second slot 222 , and the third slot 224 in the communication path 218 . 225) can be located. The first filter 221 , the second filter 223 , and the third filter 225 may each have a specific function. For example, the first filter 221 may have a function of removing moisture. The second filter 223 may have a function of removing dust and fine dust. The third filter 225 may have an antibacterial function.

At one lower side of the entry/exit frame 216 , there may be, for example, a drip tray 228 in which moisture removed from the air passing through the first filter 221 is collected. The inlet of the drip tray 228 may be located under the first slot 220 . A connection pipe 229 may be positioned on the entry/exit frame 216 to transfer the water collected in the drip tray 228 upward.

A drain container 230 may be disposed at an upper portion of the input/output frame 216 . The drain container 230 is a place for collecting water transferred through the connection pipe 229 . The drain container 230 may be exposed to a user when the input/exit frame 216 protrudes forward of the fixed frame 210 . Therefore, the user can dispose of water by separating the drain container 230 from the input/output frame 216 . Delivery of water from the drip tray 228 to the drain container 230 may use a pump or a capillary phenomenon.

A front cover 232 may be installed on the entry/exit frame 216 . The front cover 232 may form a front exterior of the air management module 200 . The front cover 232 may move together with the entry/exit frame 216 while shielding the entry/exit frame 216 .

A configuration for transferring the air flowing through the suction passage 120 to the communication passage 218 may be provided inside the air management module 200 . A fixed connection duct 234 connected to the suction passage 120 may be positioned below the fixed frame 210 . The suction passage 120 may be connected to the inlet of the fixed connection duct 234 . The fixed connection duct 234 may be positioned to extend left and right on the rear surface of the front cover 232 . The left and right widths of the fixed connection duct 234 may be the same as the length of the corresponding edge of the suction area 118 formed in the footrest 100 .

There may be a rotational connection duct 236 at the exit side of the fixed connection duct 234 . The rotation connection duct 236 is installed in the fixed connection duct 234, and may be rotated by a predetermined angle. The rotation connection duct 236 may be made separately from the fixed connection duct 234 , and may be assembled to the fixed connection duct 234 to be rotatable by a predetermined angle.

A moving duct 238 may be provided on the rear surface of the front cover 232 or the entry/exit frame 216 . The moving duct 238 may operate together with the front cover 232 or the entry/exit frame 216 . The rotation connection duct 236 may be positioned at an inlet formed at a lower portion of the moving duct 238 . The outlet of the moving duct 238 may be opened toward the communication path 218 of the entry/exit frame 216 . Accordingly, the air flowing into the fixed connection duct 234 may be moved to the moving duct 238 through the rotating connecting duct 236 , and flows from the moving duct 238 to the communication path 218 . can be The outlet of the moving duct 238 always faces the communication path 218, and the moving duct 238 moves together with the entry/exit frame 216 in which the communication path 218 is formed, so that in the moving duct 238, The discharged air may be stably moved to the communication path 218 .

A heat exchanger 240 may be provided at the rear end of the fixed frame 210 . The heat exchanger 240 may be installed to face the third filter 225 . The heat exchanger 250 may be installed inside the heat exchanger case 242 . Air may flow through the heat exchanger case 242 back and forth. The outlet of the heat exchanger case 242 may communicate with the housing inlet 312 of the fan assembly 300 to be described below. The heat exchanger 250 may exchange heat with the air that has passed through the communication path 218 . There may be components of a heat exchange cycle for operation of the heat exchanger. Reference numeral 244 denotes a compressor.

The heat exchanger 240 is for setting the temperature of the air passing through the air management module 200 . Accordingly, a heater may be used instead of the heat exchanger 240 .

The fan assembly 300 may be installed on the rear surface of the air management module 200 , that is, at an outlet through which air is discharged from the air management module 200 . The fan assembly 300 may provide a driving force through which air flows in the device of the present invention. 6 shows the configuration of the fan assembly 300 in a cross-sectional view. The cross-section of the fan assembly 300 is different from the cross-sectional positions of other parts of FIG. 6, but shows a cross-section at the corresponding position for convenience. The fan housing 310 may form the exterior of the fan assembly 300 . A housing inlet 312 may be formed at one side of the fan housing 310 . The housing inlet 312 may be opened toward the air management module 200 . A predetermined housing inner space 314 may be formed inside the fan housing 310 . A housing outlet 316 may be formed at the other side of the fan housing 310 . The housing inlet 312 may communicate with an outlet of the heat exchanger case 242 , and the housing outlet 316 may communicate with a duct 400 to be described below.

A fan 318 may be installed inside the fan housing 310 . The fan 318 is driven by a driving source (not shown) to suck air through the housing inlet 312 on the front side of the fan housing 310 , and a housing outlet 316 on the outer surface of one side of the fan housing 310 . ) through which air can be expelled. When a centrifugal fan is used as the fan 318 , the housing outlet 316 may be opened in a centrifugal direction of the fan 318 .

A function module 350 may be installed at a position corresponding to the upper portion of the air management module 200 . An example of the function module 350 may be a clothes management device. When clothes are placed inside the clothes management device, dust from clothes can be removed or sterilized. The clothes manager may also perform a function such as straightening wrinkles of clothes. As another example of the functional module 350, there may be various things such as a shoe manager, an umbrella manager, a belongings manager, a shoe storage, an umbrella storage, and a belongings storage. For reference, these functional modules 350 are not alone, but several may be combined. The function module 350 may communicate directly with the room. That is, the inside of the functional module 350 may be formed to be openable into the room.

The duct 400 may serve to move the airflow formed in the fan assembly 300 to a relatively upper portion of the entrance space. The duct 400 may include a first duct 410 and a second duct 420 . The first duct 410 may extend along a side wall of the entrance space. The first inlet 412 of the first duct 410 may be connected to the housing outlet 316 of the fan assembly 300 . The flow cross-sectional area of the first inlet 412 may be relatively small compared to other portions of the first duct 410 . The first duct 410 may include a branch flow path (not shown) for supplying air to the function module 350 . A separate damper may be provided inside the branch flow path and the first duct 410 to control the flow of air.

The second duct 420 may be located on the ceiling side of the entrance space (10). The second duct 420 is a portion through which the air passing through the first duct 410 flows. The second duct 420 may supply air to the air injector 500 to be described below. To this end, the second duct 420 may have a first outlet 422 and a second outlet 424 . The first outlet 422 may be at a relatively upstream portion of the second duct 420 , and the second outlet 424 may be located in a relative position of the second duct 420 than the first outlet 422 . may be located downstream. The first outlet 422 is closer to the first duct 410 than the second outlet 424 .

According to FIGS. 8 to 11 , an air injector 500 may be installed on the ceiling of the second duct 420 or the entrance space 10 . The air injector 500 may inject the air delivered through the duct 400 to the user in the entrance space 10 . The air injector 500 may inject the air delivered through the first outlet 422 and the second outlet 424 in various directions. In particular, the air injector 500 may be operated by a predetermined angle range so that the air injector 500 is directed in the direction in which an occupant enters and exits the entrance space 10 .

The injection frame 510 may form the skeleton of the air injector 500 . As shown in FIG. 10 , the mounting plate 512 may form at least a portion of the upper surface of the spray frame 510 . A through portion 514 may be provided in a portion of the mounting plate 512 . The through portions 514 may be respectively formed on both sides of the mounting plate 512 . The through portion 514 may be formed at a position corresponding to the first outlet 422 and the second outlet 424 of the second duct 420 in this embodiment. The penetrating portion 514 may pass through the injector frame 510 and be opened to the bottom surface of the air injector 500 .

A plurality of louvers 516 may be installed at a predetermined interval on the bottom of the injector frame 510 . The louver 516 may be installed on the entire bottom surface of the injector frame 510 . Of course, the louver 516 may be installed only at a position corresponding to the through portion 514 . Air may be injected through between the louvers 516 . The through portion 514 in which the louver 516 is installed may be the injection hole 518 . Accordingly, two injection holes 518 may be provided on the bottom surface of the air injector 500 .

Although the louver 516 is not operated and is fixed in the illustrated drawings, the direction of the air injected through the injection hole 518 may be further adjusted while rotating at a predetermined angle based on both ends of the louver 516. .

As shown in FIG. 10 , the air injector 500 may include first and second lifting mechanisms 520 and 520 ′. The first and second lifting mechanisms 520 and 520 ′ are for adjusting the operating angle of the air injector 500 . The first lifting mechanism 520 and the second lifting mechanism 520 ′ may be installed on opposite edges of the air injector 500 to adjust the direction in which the bottom surface of the air injector 500 faces. The first and second lifting mechanisms 520 and 520 ′ may be installed near both edges of the upper surface of the air injector 500 . In other words, the first lifting mechanism 520 may be installed at a position adjacent to the inner door 14 in the air injector 500 , and the second lifting mechanism 520 ′ is the outer door 12 in the air injector 500 . ) can be installed adjacent to

Some of the components of the first and second lifting mechanisms 520 and 520 ′ may be installed on the ceiling of the duct 400 or the entrance space 10 , and the rest may be installed on the sprayer frame 510 . The direction in which the bottom surface of the air injector 500 faces may be adjusted by lifting a specific portion of the injector frame 510 by the lifting mechanisms 520 and 520 ′.

The configuration of the first and second lifting mechanisms 520 and 520' may be the same, and only the installation position may be different. Accordingly, the configuration will be described based on the first lifting mechanism 520 . The mounting bracket 522 may be mounted on the ceiling of the duct 400 or the entrance space 10 . Of course, in a state in which the mounting bracket 522 of the first elevating mechanism 520 and the mounting bracket 522 of the second elevating mechanism 520' are all mounted on one plate, the plate is the duct 400 or the entrance space. It can be mounted on the ceiling of (10).

10 and 20 , a driving motor 524 may be installed on the mounting bracket 522 . The driving motor 524 may provide a driving force for the operation of the lifting mechanisms 520 and 520 ′. A driving gear 526 may be installed on the output shaft of the driving motor 524 . A driven gear 528 may be installed in engagement with the driving gear 526 . The driven gear 528 may be rotatably installed on the mounting bracket 522 . A pair of the driven gear 528 may be used. As the driven gear 528 is used as a pair, a pair of components related to the driven gear 538 may also be provided. Below, only one side of these paired configurations will be described. However, when connected to one side driven gear 528 , an additional gear train 528 ′ may be provided to match the ascending/lowering direction of the air injector 500 by the operation of the driving member 536 to be described below.

There may be an interlocking shaft 530 that rotates by receiving the rotational force of the driven gear 528 , and the interlocking shaft 530 may include a first interlocking gear 532 . The first interlocking gear 532 may be rotatably installed in the casing 534 . The first interlocking gear 532 may drive the driving member 536 installed in the casing 534 .

The casing 534 may be formed in an elliptical shape. A cross-section of one side of the casing 534 has a 'C' shape, and the driving member 536 having a caterpillar shape may be installed therein. An example of the driving member 536 may be a timing belt or a chain. When a chain is used as the driving member 536 , sprockets may be used for the first interlocking gear 532 and the second interlocking gear 532 ′. The casing 534 may be formed to have an elliptical long axis relatively longer than a minor axis. The length of the casing 534 may be appropriately set in consideration of the rotation angle of the air injector 500 .

A through slot 534 ′ may be formed in the casing 534 in a lengthwise direction of the casing 534 . The through slot 534 ′ may extend long in the longitudinal direction on the elliptical shape of the casing 534 . In the casing 534 , a second interlocking gear 532 ′ may be installed at an end opposite to which the first interlocking gear 532 is installed. The second interlocking gear 532 ′ may be rotatably installed in the casing 534 .

As shown in FIG. 11 , there is a pinion gear 538 coaxial with the second interlocking gear 532 ′. The pinion gear 538 may rotate together with the rotation of the second interlocking gear 532 ′. The pinion gear 538 may be moved along a rack slot 542 to be described below. The pinion gear 538 may be operated by meshing with the rack gear 543 in the rack slot 542 .

A rack guide 540 is installed on one side of the injector frame 510 in order to elevate a specific position of the injector frame 510 by the operation of the second interlocking gear 532 ′ and the pinion gear 538 . can be A rack slot 542 through which the rack gear 543 is guided may be formed in the rack guide 540 to be elongated in one direction. The rack guide 540 may be installed to extend along the edge of the mounting plate 512 . A rack gear 543 may be formed in the rack slot 542 of the rack guide 540 . The rack gear 543 may be operated in engagement with the pinion gear 538 to allow the pinion gear 538 to relatively move within the rack slot 542 . When the pinion gear 438 moves along the rack slot 542 , the position of the pinion gear 438 is changed within the rack slot 542 , and the second interlocking gear 532 concentric with the pinion gear 438 . '), the installation angle of the casing 534 installed may be different.

Meanwhile, in order to smoothly adjust the angle of the air injector 500 , a separate configuration may be provided without supporting the load of the air injector 500 only with the first and second lifting mechanisms 520 and 520 ′. A universal joint in which one end is connected to the mounting plate 512 and the other end is connected to the ceiling of the duct 400 or the entrance space 10 may be used.

Alternatively, as shown in FIG. 10 , the mounting plate 512 and the duct 400 or the ceiling of the entrance space 10 may be connected using a connection link 545 capable of relative rotation at both ends. A first mounting piece 547 and a second mounting piece 549 may be connected to both ends of the connection link 545 to be relatively rotatable. The first mounting piece 547 may be fixed to the ceiling of the duct 400 or the entrance space 10 , and the second mounting piece 549 may be fixed to the mounting plate 512 . It is preferable that the universal joint or the connecting link 545 be positioned at the geometric center of the air jet 500 .

The first and second lifting mechanisms 520 and 520' described above may be replaced with other components that perform the same function. For example, as shown in FIGS. 12 and 13 , the first and second lifting mechanisms 1520 and 1520 ′ of another embodiment may use a wire 1528 to adjust the angle of the air injector 500 . . In brief, the driving motor 1524 may be mounted on the bottom of the duct 400 or the ceiling of the entrance space 10 by the mounting bracket 1522 .

The bobbin 1526 may be installed on the bottom of the duct 400 or the ceiling of the entrance space 10 so as to be rotated by the output shaft of the driving motor 1524 . A wire 1528 may be wound around the bobbin 1526 . One end of the wire 1528 may be wound while being fixed to the bobbin 1526 , and the other end may be connected to the injector frame 510 of the air injector 500 . At least two or more wires 1528 may be divided and wound on one bobbin 1526 , and each other end may be connected to the injector frame 510 of the air injector 500 .

In this way, the first lifting mechanism 1520 and the second lifting mechanism 1520 ′ using the wire 1528 wind the wire 1528 around the bobbin 1526 and unwind the operating angle of the air injector 500 . Can be adjusted.

14 also discloses first and second elevating mechanisms 2520 and 2520' having different configurations. Here, the actuator 2524 may be used to adjust the operating angle of the air injector 500 . The actuator 2524 may be mounted on the ceiling of the duct 400 or the entrance space 10 . The actuator 2524 may have a piston 2528 that moves inside the cylinder 2526, and the degree of protrusion to the outside of the cylinder 2526 by the movement of the piston 2528 is different. There may be a rod 2530 . The piston 2528 may be moved in the cylinder 2526 by pneumatic or hydraulic pressure. The front end of the driving rod 2530 may be relatively rotatably connected to the connecting piece 2532 installed in the injector frame 510 of the air injector 500 . In the configuration of FIG. 14 , the operating angle of the air injector 400 may be adjusted by varying the degree to which the driving rod 2530 of the actuator 2534 is entered and exited.

Next, the configuration of the air guide unit 550 for delivering air from the first outlet 422 and the second outlet 424 of the duct 400 to the injection ports 518 on both sides of the air injector 500 will be described. do. Between the first outlet 422 of the duct 400 and one injection port 518 of the injector frame 510 and between the second outlet 424 and the other injection port 518 of the injector frame 510 An air guide unit 550 may be installed in each. For convenience of description, the air guide unit 550 at a position corresponding to the second outlet 424 will be described with reference.

The vane frame 552 may form a skeleton of the air guide unit 510 . A shape of the vane frame 552 may correspond to a shape along an edge of the injection hole 518 and a shape along an edge of the second outlet 424 . A kind of flow path is formed inside the vane frame 552 , and may be a flow path connecting the second outlet 424 and the injection hole 518 .

A connection neck 552 may be formed by protruding from the vane frame 552 toward the second outlet 424 . The connecting neck 552 may be formed to have a flow cross-sectional area that is relatively smaller than a flow cross-sectional area of the vane frame 552 portion. A corrugated pipe 556 may be installed between the connection neck 552 and the second outlet 424 to prevent air leakage. Since the corrugated pipe 556 is expandable and contractible, even if the vane frame 552 moves with the injector frame 510 with respect to the duct 400 by the operation of the injector frame 510, the connecting neck 552 A connection state between the and the second outlet 424 may be maintained. Accordingly, air leakage may not occur between the second outlet 424 and the vane frame 552 .

A vane rotation center member 558 may be installed on both inner surfaces of the vane frame 552, respectively. A plurality of vanes 560 and 560 ′ may be rotatably installed at a predetermined angle on the vane rotation center member 558 . Both ends of the vanes 560 and 560' may be rotatably installed on the vane rotation center member 558 on both sides, respectively. The vane rotation center member 558 is not provided separately, and a corresponding part of the vane frame 552 may play the same role.

The vanes 560 and 560 ′ may serve to set the direction of the air discharged through the injection hole 518 . As can be seen in FIG. 9 , the vanes 560 and 560 ′ may be connected such that an upstream portion 561 and a downstream portion 561 ′, which are plates of a predetermined shape, have a predetermined angle. The upstream portion 561 and the downstream portion 561 ′ are connected by a connecting curved portion 561 ′ having a predetermined radius of curvature.

The shape of the vanes 560 and 560 ′ is that of the air guide unit 550 used at the position corresponding to the first outlet 422 and that of the air guide unit 550 used at the position corresponding to the second outlet 424 . It may be formed a little differently. In (a) of FIG. 16 , the vanes 560 at positions corresponding to the second outlets 424 are shown, and in FIG. 16(b), the vanes 560 at positions corresponding to the first outlets 422 . ') are shown.

First, looking at the configuration of the vane 560 in FIG. 16A , the virtual extension surfaces extending from the upstream part 561 and the downstream part 561 ′ may meet to form an obtuse angle with each other. A plurality of vanes 560 having such a configuration may be disposed on the vane frame 552 to have a predetermined interval. Here, the start portion of the upstream portion 561 of the vane 560 may be inclined toward the upstream of the second duct 420 . The downstream portion 561 ′ may be inclined toward the middle portion of the scaffold 100 toward the end.

Next, looking at the configuration of the vane 560 ′ in FIG. 16B , the virtual extension surfaces extending from the upstream portion 561 and the downstream portion 561 ′ may be substantially parallel to each other. Here, the start of the upstream portion 561 of the vane 560 ′ may be inclined toward the upstream of the second duct 420 . For reference, the inclination directions of the upstream portion 561 of the vane 560 and the upstream portion 561 of the vane 560 ′ may be substantially the same. Only the upstream portion 561 of the vane 560 ′ protrudes into the inside of the second duct 420 is relatively short. The downstream portion 561 ′ may be inclined toward the middle portion of the scaffold 100 toward the end.

At least a portion of the upstream portion 561 of the vanes 560 and 560 ′ may be located in the second duct 420 . The downstream portion 561 ′ of the vanes 560 and 560 ′ may be mainly located within the vane frame 552 . A larger portion of the upstream portion 561 of the vanes 560 and 560 ′ may be located in the second duct 420 as the air moves in the second duct 420 . In other words, the start portion of the upstream portion 561 of the vanes 560 and 560 ′ may be at a higher position as the air travels in the second duct 420 . This configuration is the same even if the vane 560 in the first outlet 422 and the second outlet 424 are compared. That is, the start of the upstream portion 561 of the vane 560 at the second outlet 424 is longer than the start of the upstream portion 561 of the vane 560 ′ at the first outlet 422 . may be in a high position. Such a configuration can also be seen in FIG. 3 . This is to allow the air flowing in the second duct 420 to flow uniformly through the entire area of each of the first outlet 422 and the second outlet 424 .

In addition, the length from the upstream part 561 to the downstream part 561' of the vanes 560 and 560' is relatively longer when positioned at the first outlet 422 than at the second outlet 424. can This is to allow a lot of air to flow to the injection hole 518 without wasted air going toward the end of the second duct 420 .

The downstream portions 561 ′ of the vanes 560 and 560 ′ may guide air to the lower region of the air injector 500 in a state where it is located in the vane frame 552 . Depending on the state in which the vanes 560 and 560' are rotated with respect to the vane rotation center member 558, the direction in which the downstream part 561' guides air may vary.

There may be a vane driving member 562 to adjust the operating state of the vanes 560 and 560 ′. The vane driving member 562 may be connected to each of the vanes 560 and 560 ′ like the vane rotation center member 558 . The vane driving member 562 may be relatively rotatably connected to the vanes 560 and 560' at a position where the vane rotation center member 558 is moved toward the injection port 518 from the portion connected to the vanes 560 and 560'. . The vane driving member 562 may be mainly connected to the downstream portion 561' of the vanes 560 and 560'. Two vane driving members 562 may be used, one on each side of the vanes 560 and 560'. Alternatively, only one vane driving member 562 may be used.

The vane driving member 562 may be located inside the vane frame 552 . A moving slot 564 may be formed in the vane frame 552 so that a part of the vane driving member 562 is exposed to the outside of the vane frame 552 . The moving slot 564 may be formed to be open to both outer surfaces of the vane frame 552 . A connection pin 566 may be positioned in the moving slot 564 . One end of the connecting pin 566 may be connected to the vane driving member 562 . The other end of the connecting pin 566 may be connected to a driving link 574 to be described below. A roller 568 surrounding a part of the length section of the connecting pin 566 may be positioned. The roller 568 may facilitate the movement of the connecting pin 566 in the moving slot 564 .

A vane motor 570 for driving the vanes 560 and 560' may be installed on the mounting plate 512 . A motor gear 570 ′ may be installed on the rotation shaft of the vane motor 570 . A first driving gear 571 and a second driving gear 572 may be engaged with the motor gear 570 ′. The first driving gear 571 provides a driving force for the operation of the vane 560' installed at the first outlet 422, and the second driving gear 572 is the vane installed at the second outlet 424. 560) may provide a driving force for the operation.

The first driving gear 571 and the second driving gear 572 may each drive a separate driving link 574 . For this, each of the driving links 574 may include a rack portion 576 . A connection part 578 may be provided to extend from one side of the rack part 576 to both sides, and a driving part 580 may extend orthogonally to both sides of the connection part 578 . A connection pin 566 that moves along a movement slot 564 formed in the vane frame 552 may be installed in the driving unit 580 .

Since the driving link 574 is configured by continuously connecting the rack unit 576, the connecting unit 578, and the driving unit 580, deflection may occur. In order to prevent deflection of the driving link 574 , in the present embodiment, a support 582 for supporting the driving unit 580 with respect to the mounting plate 512 may be provided. Two of the supports 582 may be used in one driving link 574 to support the driving units 580 on both sides, respectively. Reference numeral 584 denotes a stopper for setting one end of the movement stroke of the driving link 574 .

For reference, in order to avoid interference between the vane motor 570 and the connection link 545 and the second mounting piece 549 , the length of the rack part 576 of the drive link 574 or the connection position with the connection part 578 . may be different from that shown.

Hereinafter, it will be described in detail that the sanitary management device for the entrance according to the present invention having the configuration as described above is operated.

An operation of the hygiene management device will be described with reference to FIGS. 17 to 22 . In order for a person to enter the entrance space 10 in which the hygiene management device of the present invention is installed, the outdoor door 12 is opened. Sensing that the outdoor door 12 is opened, the air sprayer 500 may spray air toward the outdoor door 12 so that air does not enter the entrance space 10 from the outdoors. To this end, as shown in FIG. 18 , the bottom surface of the air injector 500 is inclined toward the outdoor door 12 .

That is, the portion of the injector frame 510 on the side of the first elevating mechanism 520 is made to be relatively low, and the portion of the injector frame 510 on the side of the second lifting mechanism 520' is made to be relatively high. To this end, the driving motor 524 is driven, and the driving force is transmitted to the driving member 536 through the driving gear 526 , the driven gear 538 , and the first interlocking gear 532 . As the second interlocking gear 532 ′ rotates by the operation of the driving member 536 , the pinion gear 538 integrally rotated with the second interlocking gear 532 ′ is the rack of the rack guide 540 . It may be rotated in engagement with the gear 543 to move along the rack slot 542 . As the pinion gear 538 moves along the rack slot 542 , the second interlocking gear 532 ′ also moves, so that the angle of the casing 534 may be changed.

When the casing 534 is positioned parallel to the injector frame 510 (FIG. 20 (a)), the injector frame 510 at that position is relatively close to the duct 400. Conversely, when the angle between the casing 534 and the injector frame 510 increases (FIG. 20 (b)), the injector frame 510 at the corresponding position moves away from the duct 400. That is, the height of the corresponding portion of the injector frame 510 is lowered.

In the state of FIG. 18, the height of the injector frame 510 on the side where the first lifting mechanism 520 is located is lowered, and the height of the injector frame 510 on the side where the second lifting mechanism 520' is relatively lowered. it will be elevated In this way, the air sprayer 500 can spray the air downward toward the outdoor door 12 at an angle.

Conversely, as in FIG. 19 , the height of the injector frame 510 on the side where the first lifting mechanism 520 is located is relatively high, and the height of the injector frame 510 on the side where the second lifting mechanism 520 ′ is located. When the height is relatively low, the air injector 500 can inject the air downward toward the interior door 14 at an angle.

12 and 14, the height of the injector frame 510 is adjusted in the same manner as described above even when the lifting mechanisms 1520, 1520'. (2520, 2520') are used. can be That is, the inclination of the injector frame 510 may be adjusted by the wire 1528 being wound around the bobbin 1526 and unwinding, and the lifting rod 2520 entering and exiting the cylinder 2526 .

On the other hand, when the entrant opens the outdoor door 12, enters the entrance space 10, closes the outdoor door 12, and is positioned on the scaffold 100 as shown in FIG. 17, the fan assembly While the 300 is operated, first, suction of air may occur through the scaffold 100 .

In the scaffold 100 , air may be sucked through the suction area 118 . Air may be sucked into the suction passage 120 of the suction area 118 covered by the support member 130 . Air may be sucked into the suction passage 120 through the suction slot 136 formed between the support members 130 .

Since the suction slot 136 formed between the support members 130 has a relatively narrow flow cross-sectional area, it can suck air with a relatively strong suction force to flow into the suction passage 120 .

Since the inside of the support member 130 is empty, it can well support the load of the occupants while being relatively light in weight. At the same time, the suction slot 136 between the support members 130 may serve as a kind of filter to prevent foreign substances of a certain size or more from entering the suction passage 120 .

Meanwhile, the ultraviolet light for sterilization from the light source 126 may be irradiated to the upper portion of the scaffold 100 through the light transmission member 128 positioned between the support members 130 . The ultraviolet light irradiated through the light transmission member 128 can sterilize while being intensively irradiated to the shoes and lower body of the person entering or leaving.

The air delivered to the suction passage 120 may enter the air management module 200 . Air may enter the air management module 200 through a fixed connection duct 234 communicating with the suction passage 120 . Air entering the fixed connection duct 234 may enter the communication path 218 through the rotation connection duct 236 and the moving duct 238 .

As air passes through the communication path 218 , moisture removal, fine dust removal, sterilization, etc. may be performed by the first filter 221 , the second filter 223 , and the third filter 225 . While passing through the heat exchanger 240 or the heater, the temperature of the air may be set to a preset value.

The air passing through the communication path 218 may enter the fan assembly 300 . The air entering the fan assembly 300 may flow by the fan 318 and enter the duct 400 . Some of the air entering the duct 400 may be selectively transferred to the function module 350 and used.

The air delivered to the first duct 410 of the duct 400 flows into the second duct 420 and goes to the first outlet 422 and the second outlet 424 of the second duct 420 . can be passed sequentially. The vanes 560 and 560' are positioned at the first outlet 422 and the second outlet 424, so that the flowing air is guided by the vanes 560 and 560' to the first outlet 422 and the second outlet ( 424) can be entered. In addition, since a plurality of vanes 560 and 560 ′ are spaced apart from each other by a predetermined height difference at the first outlet 422 and the second outlet 424 , the air flows through the first outlet 422 and the second outlet 424 . It can be relatively uniformly dispersed and flowed. Such a state is shown in FIG. 21 . In Figure 21, it is shown that the air is discharged obliquely toward the center portion of the footrest through the injection hole 518 while the air is guided by the vanes (560, 560').

For the operation of the vanes 560 and 560 ′, the drive link 574 may make a linear reciprocating motion by the vane motor 570 . As the driving link 574 moves linearly, the vanes 560 and 560 ′ may be rotated at a predetermined angle around the vane rotation center member 558 while the vane driving member 562 moves. As the direction in which the downstream portions 561 ′ of the vanes 560 and 560 ′ face is adjusted by the predetermined angle rotation of the vanes 560 and 560 ′, the air injection direction through the injection hole 518 may be changed.

The vanes 560 ′ positioned at the first outlet 422 and the vanes 560 ′ positioned at the second outlet 424 are each driven link 572 by one-way rotation of the vane motor 570 . may be pulled in the direction of the vane motor 570 or may be pushed in a direction away from the vane motor 570 .

22( a ) shows a state in which the driving link 572 is pulled in the direction of the vane motor 570 . In this case, the downstream portions 561' of the vanes 560 and 560' are inclined toward the lower center. In this state, air may be guided along the downstream portion 561 ′ of the vane 560 to be injected toward the lower center of the air injector 500 . This is the case for both the injection port 518 corresponding to the first outlet 422 and the injection port 518 corresponding to the second outlet 424 . Therefore, the air injected from the two injection holes 518 may be relatively collected toward the center of the footrest 100 .

In addition, the upstream parts 561 all face relatively upstream of the second duct 420 , and as the downstream of the second duct 420 goes, the upstream parts 561 move further into the second duct 420 . It can be seen that it is protruding.

22( b ) shows a state in which the driving link 572 is moved in a direction away from the vane motor 570 . In this case, the downstream portions 561 ′ of the vanes 560 and 560 ′ are disposed to face relatively downward, so that air may be injected into the lower portion of the air injector 500 . Accordingly, the air injected from the two injection holes 518 may spread toward the entire upper portion of the footrest 100 and be transmitted.

In the above, even though it has been described that all components constituting the embodiment according to the present disclosure operate as one combined or combined, the present disclosure is not necessarily limited to this embodiment. That is, within the scope of the object of the present disclosure, all of the components may operate by selectively combining one or more. In addition, terms such as "comprises", "comprises" or "have" described above mean that the corresponding component may be inherent, unless otherwise specified, excluding other components. Rather, it should be construed as being able to further include other components.

In the illustrated embodiments, the first lifting mechanism (520, 1520, 2520) and the second lifting mechanism (520', 1520', 2520') are located on both edges of the injector frame 510 so that the air injector 500 is The angle was adjusted. However, the angle of the air injector 500 may be adjusted by using a plurality of lifting mechanisms 520 , 1520 , 2520 , and 520 ′, 1520 ′, and 2520 ′ having the same configuration. For example, the lifting mechanisms may be placed at positions adjacent to the four corners of the injector frame 510 .

100: footrest 110: base plate
112: side wall 114: seating surface
116: guide rib 118: suction area
120: suction flow path 122: seating end
124: substrate 126: light source
128: light transmission member 130: support bar
132: through hole 134: inclined surface
136: suction slot
200: air management module 210: fixed frame
212: interior space 214: entry and exit hinge
216: entry and exit frame 218: communication path
220: first slot 221: first filter
222: second slot 223: second filter
224: third slot 225: third filter
228: drip tray 229: connecting pipe
230: drain container 232: front cover
234: fixed connection duct 236: connection rotation duct
238: moving duct 240: heat exchanger
242: heat exchanger cover 244: compressor
300: fan assembly 310: fan housing
312: housing inlet 314: housing inner space
316: housing outlet 318: fan
350: function module
400: duct 410: first duct
412: first entrance 420: second duct
422: first exit 424: second exit
500: air injector 510: injector frame
512: mounting plate 514: penetration
516: louver 518: nozzle
520: first elevating mechanism 520': second elevating mechanism
522: mounting bracket 524: drive motor
526: drive gear 528: driven gear
528': gear train 530: interlocking shaft
532: first interlocking gear 532': second interlocking gear
534: casing 534': through slot
536: driving member 538: pinion gear
540: rack guide 542: rack slot
543: rack gear 545: connecting link
547: first mounting piece 549: second mounting piece
550: air guide unit 552: vane frame
554: connecting neck 556: corrugated pipe
558: vane rotation center member 560, 560': guide vanes
561: upstream part 561': downstream part
561” connecting curved part 562: vane driving member
564: moving slot 566: connecting pin
568: rotating roll 570: vane motor
570': motor gear 571: first drive gear
572: second drive gear 574: drive link
576: rack part 578: connection part
580: driving unit 582: support
584: stopper

Claims (22)

Footrest located on the floor of the entrance space and sucking air through the surface;
An air management module configured to pass air sucked through the footrest and managing the quality of the passing air;
a fan assembly configured to generate the flow of air;
a duct forming a flow passage for air generated by the operation of the fan assembly;
The air flowing through the duct is sprayed within a predetermined angle range in the entry/exit direction toward the surface of the footrest through the injection port, and an air guide unit is provided to guide the injection within a predetermined angle range toward the side of the person. including,
The air guide unit,
a vane frame communicating between the duct and the injection port;
A plurality of vanes installed side by side to rotate at a predetermined angle on the vane frame to guide air;
A sanitary management device for an entrance including a vane motor that provides a driving force for driving the vane.
The doorway of claim 1, wherein the air guide unit further comprises a vane driving member connected to a plurality of the vanes to rotate the vanes at a predetermined angle, and a driving link for operating the vane driving member by the driving force of the vane motor. sanitary control device.
According to claim 2, wherein the vane driving member and the drive link between the drive link is connected by a connecting pin that passes through a moving slot formed in the vane frame, the sanitary control device for the entrance to which power is transmitted.
[Claim 4] The sanitary management device for entrance and exit according to claim 3, wherein a rotating roll is installed on the connecting pin to be rotatably concentric and move within the moving slot.
According to claim 1, wherein the vane is composed of an upstream portion that starts to guide the air, a downstream portion for discharging the guided air, and a connecting curved portion connecting the upstream portion and the downstream portion, and the start of the upstream portion is downstream of the duct. A sanitary control device for entrances and exits that protrudes further into the duct.
According to claim 5, wherein the upstream portion of the vane extends obliquely from the inside of the duct toward the upstream of the duct, the downstream portion of the vane inclined toward the middle portion of the footrest sanitary management device for entrance.
[Claim 7] The sanitary management device for entrance and exit according to claim 6, wherein the length from the start point of the upstream part to the end point of the downstream part of the vane is longer than that of the vane installed upstream of the duct.
[Claim 8] The sanitary management device for entrance and exit according to claim 7, wherein the imaginary extension surfaces of the upstream portion and the downstream portion of the vane are parallel.
[Claim 8] The sanitary management device for entrance and exit according to claim 7, wherein an imaginary extension surface of the upstream portion and the downstream portion of the vane forms an obtuse angle.
The method of claim 1, wherein the duct includes a first duct extending along a wall surface of the entrance space and a second duct extending along a ceiling of the entrance space, and a first outlet is formed relatively upstream of the second duct. and a sanitary management device for entrance and exit in which a second outlet is formed at a relatively downstream side of the second duct.
[Claim 11] The sanitary management device for entrance and exit according to claim 10, wherein a corrugated pipe is installed between the first outlet and the vane frame and between the second outlet and the vane frame to prevent air leakage.
According to claim 1, In the air injector, the injector frame forms a skeleton, one side is connected to the ceiling of the duct or entrance space, and the other side is connected to the injector frame, the first elevating mechanism and the second elevating mechanism of the injector frame Sanitary management device for entrance and exit installed on both sides of the operating angle is set by the first and second lifting mechanism.
The sanitary management device for entrance and exit according to claim 12, wherein a relatively rotatable connection link or universal joint is further provided between the sprayer frame and the ceiling of the duct or entrance space.
a fan assembly configured to generate a flow of air;
a duct forming a flow passage for air generated by the operation of the fan assembly;
Including an air injector provided with an air guide unit configured to control an angle to inject air through the spray hole within a predetermined angle range in the entrance and exit direction from the entrance space and guide the air injected through the injection hole toward the side of the person do,
In the air guide unit, a plurality of vanes installed on a vane frame communicating between the duct and the injection port are driven by a vane motor to adjust the angle.
[Claim 15] The sanitary management device for entrance and exit according to claim 14, wherein a plurality of the vanes are arranged in a row from the upstream to the downstream of the duct in the vane frame at a predetermined interval.
[Claim 15] The sanitary management device for entrances and exits according to claim 14, wherein the vane includes an upstream portion for guiding air, a downstream portion for discharging the guided air, and a connecting curved portion connecting the upstream portion and the downstream portion.
The sanitary management device for an entrance according to claim 16, wherein an upstream portion of the vane extends obliquely from the inside of the duct toward an upstream portion of the duct, and a downstream portion of the vane slopes toward a bottom middle portion of the entrance space.
[Claim 17] The sanitary management device for entrance and exit according to claim 16, wherein the start of the upstream portion protrudes further into the duct as it goes downstream of the duct.
The sanitary management device for entrance and exit according to claim 18, wherein the length from the start point of the upstream part to the end point of the downstream part of the vane is longer than that of the vane installed upstream of the duct.
[Claim 17] The sanitary management device for entrance and exit according to claim 16, wherein the imaginary extension surfaces of the upstream portion and the downstream portion of the vane are parallel.
[Claim 17] The sanitary management device for entrance and exit according to claim 16, wherein an imaginary extension surface of the upstream portion and the downstream portion of the vane forms an obtuse angle.
[Claim 15] The sanitary management device for entrance and exit according to claim 14, wherein a corrugated pipe is installed between the duct and the vane frame to prevent air leakage.

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