KR20240070136A - Stand type drying apparatus - Google Patents

Abstract

The present invention is a stand-type drying device. The drying apparatus of the present invention has a base 10, and a housing 20 can be installed on the base 10. Inside the housing 20, there is a blowing unit 30 that causes air to flow. On one side of the housing 20, there is a discharge column 40 having an air duct 420 through which the airflow formed by the blowing unit 30 flows. The discharge column 40 may extend long upward from the housing 20. The discharge column 40 is shaped like a rod, and a discharge port 418 is formed on its front in the vertical direction, and the air flowed by the blowing unit 30 is sprayed to dry the user's body. The discharge column 40 is further provided with an upper discharge column 50 to spray air to the user. The discharge column 40 and the upper discharge column 50 can be coupled to be relatively rotatable by a joint mechanism 80.

Description

Stand type drying apparatus}

The present invention is a stand-type drying device that can be used while standing on the floor.

People encounter various types of pollution during their lives. For example, if you are exposed to a dusty environment, your skin may become contaminated with dust. While cooking in the kitchen, oil vapor can come into contact with people's skin. Alternatively, human skin can be contaminated by sweat, sebum, etc. generated from the human body. To remove such contamination, people wash parts of their body or take a shower. Although it varies from person to person, it is generally common to shower every day. In particular, after exercising, you must shower or bathe to remove sweat from your body.

After showering, you must remove moisture from your body. Typically, a towel is used to remove moisture from the body. If the moisture in the body is not removed, there is a problem that it creates an environment where bacteria and mold can grow. Even though you generally use a towel to remove moisture remaining on the body, for example, moisture between the toes often remains without being removed, and moisture remains in areas such as the back that cannot be reached by human hands. There are a lot. And in the case of people with long hair, moisture cannot be removed properly even if thoroughly wiped with a towel, so a hair dryer must be used.

To solve this problem, a drying device was proposed that sprays air to remove moisture remaining on a person's body after a shower. Prior document 1, Korean Patent Publication No. 10-1996-0000145, discloses a drying device installed on one side of a shower room. This drying device has a platform for the user to stand on and is designed to spray air onto the user's head. In particular, there are multiple outlets on the front of the drying device so that air can be sprayed onto the user's body. Therefore, the size of the drying device is large and heavy, so once installed, it has no choice but to be left in place and used, and since the outlet is fixed, there are areas far from the outlet, especially areas in the width direction of the user's body, where air is not transmitted. There is a problem that arises.

Prior document 2, Korean Patent Publication No. 10-2009-0092640, also discloses a drying device fixed to a wall. However, since there are devices such as a fan at the top of the body, the center of gravity is high, so it cannot be placed on the floor and has no choice but to be fixed to the wall. Therefore, the drying device of Prior Literature 2 has the inconvenience of being immovable and having to be used only in specific locations. In addition, the drying device in Prior Literature 2 has a problem in that the discharge port is located at a position corresponding to the width of the user's body in order to spray air across the entire width of the user's body, which increases the overall width of the drying device.

Prior Document 3, Korean Patent Publication No. 10-2009-0109364, also discloses a drying device similar to Prior Document 2. However, Prior Document 3 also has a high center of gravity, so it cannot be moved and used in a standing form, and there is a problem in that the left and right width increases due to a problem with the placement of the discharge port.

Prior document 4, Japanese Patent Publication No. 1995-0008412, discloses a drying device in which a discharge unit that sprays air moves up and down. However, in Prior Literature 4, drying is performed only by the discharge unit, so it takes a relatively long drying time, and air is discharged from the discharge unit whose width corresponds to the width of the user's body, so the width of the drying device is at least the same as the width of the user's body. There is a problem that needs to be addressed.

Meanwhile, Korean Patent No. 10-1353571, which is prior document 5, discloses a movable body dryer. The body dryer in Prior Literature 5 is designed to spray air toward the upper part of the user's body starting from the feet when the user stands up. However, since the air sprayed from the body dryer is directed from the lower part of the user's body to the upper part, there is a problem in that the upper part of the user's body is not properly dried.

Korean Patent No. 10-2420364, which is prior document 6, discloses a hair dryer that can be fixed vertically. Here, a hair dryer is installed on the top of a support bar that stands upright on a support panel supported on the ground to dry the user's hair. However, Prior Document 6 has a problem in that it cannot dry the user's entire body but only the hair, and the structure for adjusting the angle of the hair dryer with respect to the support bar is complicated.

(Prior document 001) Korean Patent Publication No. 10-1996-0000145 (Prior document 002) Korean Patent Publication No. 10-2009-0092640 (Prior document 003) Korean Patent Publication No. 10-2009-0109364 (Prior document 004) Japanese Patent Publication No. 1995-0008412 (Prior document 005) Korean Patent No. 10-1353571 (Prior document 006) Korean Patent No. 10-2420364

The present invention is intended to solve the conventional problems described above, and the purpose of the present invention is to provide a stand-type drying device that can be placed on the floor while simultaneously spraying air from the front on the user's entire body.

The purpose of the present invention is to ensure that the discharge port that sprays air to the user extends vertically to correspond to the user's entire body.

The purpose of the present invention is to allow a discharge column with a discharge port that sprays air to the user to be rotated at a predetermined angle in the width direction of the user.

The purpose of the present invention is to place an upper discharge column above the discharge column.

The purpose of the present invention is to enable the upper discharge column located at the top of the discharge column to rotate at a predetermined angle in the vertical direction.

The purpose of the present invention is to enable the air around the discharge column to be sprayed in addition to the air provided from the blowing unit.

The purpose of the present invention is to ensure that air is uniformly sprayed through the discharge port regardless of the position of the discharge column.

The purpose of the present invention is to enable the air around the upper discharge column to be sprayed together by the airflow formed by the blowing unit.

The purpose of the present invention is to separate the air flow from the blower unit in proportion to the volume of the air duct's air path.

The purpose of the present invention is to install a spray nozzle at the discharge port of the discharge column or the upper column discharge port of the upper discharge column so that air is sprayed to the user.

The purpose of the present invention is to place an upper discharge column at the top of the discharge column that receives air from the discharge column side and discharges it.

The purpose of the present invention is to automatically adjust the amount of air sprayed from the upper discharge column by adjusting the vertical angle of the upper discharge column at the top of the discharge column.

The purpose of the present invention is to provide a joint mechanism that connects the discharge column and the upper discharge column, and to connect the upper air duct of the upper discharge column and the air duct of the discharge column with a connection duct through the joint mechanism.

The purpose of the present invention is to install an upper discharge column detachably on top of the discharge column using a joint mechanism.

The purpose of the present invention is to ensure that the upper discharge column is accurately rotated relative to the discharge column.

The purpose of the present invention is to enable the upper discharge column to be separated from the discharge column and connected to a power source.

The purpose of the present invention is to precisely rotate the upper discharge column relative to the discharge column.

In order to achieve the above-mentioned object, in the present invention, a discharge column with a long discharge port may be installed extending upward to a housing installed on a base seated on the ground.

In the present invention, the discharge column may be extended upwardly to simultaneously spray air to the user's entire body.

In the present invention, the discharge column can be rotated at a predetermined angle with respect to the base together with the housing installed on the base.

In the present invention, the upper discharge column may be installed on the upper part of the discharge column to be rotatable at a predetermined angle by a joint mechanism.

In the present invention, the upper discharge column can be rotated in the vertical direction with respect to the discharge column.

A column suction port is formed in the discharge column of the present invention, so that surrounding air can be sucked into the discharge column by the air flow inside the discharge column.

In the present invention, as the air flow path formed inside the discharge column moves away from the blowing unit, the flow cross-sectional area becomes narrower, so that the amount of discharged air can be uniform throughout.

In the present invention, an upper column intake port that can suck in surrounding air can be formed in the upper discharge column.

In the present invention, the amount of air separated from the air duct and flowing can be determined in proportion to the volume of the air passage in the direction in which the air flows.

In the present invention, air can be sprayed to the user by installing a spray nozzle at the discharge port of the discharge column or the upper column discharge port of the upper discharge column.

In the present invention, the upper discharge column installed above the discharge column can receive air from the discharge column and discharge it to the outside.

In the connection duct of the present invention, the amount of air flowing inside can be controlled depending on the degree of rotation of the upper discharge column with respect to the discharge column.

In the present invention, the discharge column and the upper discharge column are connected by a joint mechanism, and the upper air duct of the upper discharge column and the air duct of the discharge column can be connected by a connection duct through the joint mechanism.

In the present invention, the upper discharge column can be detachably installed on the upper part of the discharge column by a joint mechanism.

In the present invention, when the upper discharge column is rotated relative to the discharge column, the rotation of the upper discharge column can be guided by the connector of the joint mechanism. Therefore, the upper discharge column can be accurately rotated relative to the discharge column.

In the present invention, the joint mechanism has a first electrode and a second electrode, so that electrical connection can be made between the discharge column and the upper discharge column.

In the present invention, a friction pad is located between the female joint and the male joint of the joint mechanism, so that the degree of rotation of the upper discharge column with respect to the discharge column can be precisely controlled.

The stand-type drying device of the present invention includes a base mounted on the floor, a housing located on the base and having an inlet, a blowing unit located in the housing to allow air to be sucked in and flow through the inlet, and a device coming out of the housing. An air passage through which air flows is located inside, an outlet through which air from the air passage is discharged to the outside extends in a vertical direction, and may include a discharge column extending upward from the housing.

In the present invention, an upper discharge column may be further provided on one side of the discharge column.

In the present invention, the upper discharge column is equipped with an upper blowing unit to suck in external air and allow it to flow through the upper discharge column and be discharged.

In the present invention, the discharge column and the upper discharge column may be connected by a joint mechanism so that the upper discharge column can rotate at a predetermined angle with respect to the discharge column.

In the present invention, the joint mechanism may include a groove-shaped female joint provided at a corresponding position of the discharge column and the upper discharge column and a hemispherical male joint inserted into the female joint.

The blowing unit includes a fan duct installed in the housing to serve as a passage for air to pass through, a motor located inside the fan duct, and a fan located inside the fan duct and rotating by the motor to form an airflow. may include.

An air guide is connected to the fan duct to guide air discharged from the fan duct. The air guide is installed in the housing and can guide air into the discharge column.

An air duct may be installed inside the discharge column, with an air flow path through which the air flow formed by the blowing unit flows, and a flow discharge port may be formed in the longitudinal direction of the air duct to send air to the discharge port. there is.

The base may include a disk-shaped base body and a rotation center that protrudes at the center of the base body and serves as the rotation center of the housing.

A connection curved surface having a predetermined radius of curvature is formed at a portion where the rotation center and the base body are connected to guide air toward the intake port in the housing.

In the present invention, an internal space in which the blowing unit is located may be formed inside the housing, a column installation part where the lower part of the discharge column is located may be formed on one side of the housing, and the rotation center of the base A rotation center hole where the base is located may be provided in the lower part of the housing.

In the present invention, the intake port through which external air is sucked in by the blowing unit may be formed in the housing adjacent to the edge of the rotation center hole.

The stand-type drying apparatus of the present invention includes a base that is seated on the floor and has a protruding rotation center, a housing that has a rotation center hole into which the rotation center is inserted and an inlet is formed adjacent to an edge of the rotation center hole, and the housing includes: A blowing unit located inside and sucking air through the intake port, an air passage installed on one side of the housing through which air flows by the blowing unit are located inside, and the air in the air passage is discharged to the outside. The discharge port is provided to extend in a vertical direction and may include a discharge column extending upward from the housing.

In the present invention, a drive source that provides driving force for rotation of the housing may be installed inside the rotation center of the base.

In the present invention, the driving force of the drive source may be transmitted through a plurality of gears to a housing rotatably installed on the rotation center.

In the present invention, the outer surface of the rotation center table may have a stepped portion for supporting the housing, and the lower portion of the rotation center band may have an outer diameter larger than the upper portion based on the step portion.

In the present invention, a support wall surrounding the suction port formed adjacent to the rotation center hole of the housing is provided, and the blowing unit can be supported on the support wall.

In the present invention, the intake port provided in the housing may be open toward the base, and the base may have a connecting curved surface facing the intake port formed as a curved surface with a predetermined radius of curvature to guide surrounding air to the intake port. can do.

In the present invention, the rotation center may be formed at the center of the base body constituting the base, and a curved surface connecting the rotation center and the base body may be the connection curved surface.

In the present invention, a driving window is formed on the rotation center to transmit power through the plurality of gears.

The stand-type drying device of the present invention includes a base mounted on the floor, a housing located on the base and having an inlet, a fan and a motor to form an airflow, and a blowing unit installed inside the housing, and a blower unit installed inside the housing. It extends upward, is formed in a rod shape, has a long discharge port in the vertical direction, and may include a discharge column configured to spray air through the discharge port between the left and right width areas of the user's body by rotation of the housing.

In the present invention, there may be an air duct inside the discharge column with an air flow path through which the air flow formed by the blowing unit flows, and a flow discharge port may be formed in the longitudinal direction of the air duct to correspond to the discharge port. .

In the present invention, the cross-sectional flow area of the air flow path may become narrower as the distance from the blowing unit increases.

In the present invention, the base may have a driving source, and the driving force of the driving source may be transmitted to a driven gear in the housing through a plurality of gears to rotate the housing.

The stand-type drying device of the present invention includes a base mounted on the floor, a housing located on the base and having an inlet, a blowing unit located in the housing to allow air to be sucked in and flow through the inlet, and a device coming out of the housing. An air duct with an air flow path through which air flows is installed inside, a discharge port through which air discharged through the flow path outlet of the air duct is discharged to the outside is provided extending in the vertical direction, and a discharge column extends upward from the housing. It can be included.

In the present invention, the cross-sectional flow area of the air flow path may become narrower as the distance from the blowing unit increases.

In the present invention, the flow path discharge port of the air duct may be formed to be long in the longitudinal direction of the air duct to correspond to the discharge port of the discharge column.

In the present invention, the discharge port may be formed on the front of the column body constituting the discharge column, and a column intake port through which air around the discharge column is sucked may be formed on the back, so that the column body constituting the discharge column exits the flow path discharge port of the air duct and the discharge port. The air that joins the air flowing through can be inhaled.

In the present invention, when viewed in a cross section of the air duct, the cross-sectional flow area may gradually become narrower toward the flow path outlet of the air duct.

In the present invention, the air duct may be inclined on both sides toward the flow path outlet, so that the front end of the cross section of the air duct may be sharp and the rear end of the cross section of the air duct may be curved.

In the present invention, a filter may be further installed at the column inlet.

In the present invention, a spray nozzle may be further installed at the discharge port of the discharge column.

In the present invention, a spray passage through which air flows and is sprayed may be formed in the spray nozzle, and an expanded portion may be formed at the end of the spray passage to increase the flow cross-sectional area relatively.

The stand-type drying device of the present invention includes a base mounted on the floor, a housing located on the base and having an inlet, a blowing unit located in the housing to allow air to be sucked in and flow through the inlet, and a device coming out of the housing. An air duct with an air flow path through which air is separated by a separation guide is installed inside, and an outlet through which air discharged through the flow path outlet of the air duct is discharged to the outside is provided to extend in the longitudinal direction, and is provided at the upper part of the housing. It may include a discharge column extending to, and the air flowing in the air passage can be divided into the upper and lower parts of the air duct by the separation guide.

In the present invention, the separation guide may divide the air flowing in the air duct into a ratio of the volume of the air duct above the separation guide and the volume of the air duct below the separation guide.

In the present invention, the separation guide has a sharply protruding central portion and is formed as a curved surface on the upper and lower sides to distribute the flow of air. The central portion is located on one side in the height direction of the connection where air enters the air duct by the blowing unit. It can be.

In the present invention, the air that is separated by the separation guide and flows to the lower part of the air duct may be delivered to the lower part of the air flow path of the air duct and sprayed to the user's feet through the discharge port of the discharge column.

In the present invention, the discharge column is provided with a column body having a longitudinally long discharge port on the front, a flow path discharge port installed inside the column body to deliver air to the discharge port, and receiving air from the blowing unit. It may include an air duct having a connection.

In the present invention, the cross-sectional flow area of the air passage inside the air duct may become narrower as the distance from the connection part increases.

In the present invention, the air duct may be inclined on both sides toward the flow path outlet, so that the front end of the cross section of the air duct may be sharp and the rear end of the cross section of the air duct may be curved.

In the present invention, a column suction port through which air surrounding the discharge column is sucked may be further formed on the column body opposite to the discharge port.

In the present invention, the column inlet may be provided with a filter that filters out foreign substances in the air passing through.

In the present invention, the upper discharge column may be provided at the upper part of the discharge column to be rotated at a predetermined angle with respect to the discharge column by a joint mechanism.

In the present invention, the upper discharge column may include an upper column body, an upper blowing unit installed inside the upper column main body, and an upper air duct through which an airflow formed by the upper blowing unit flows.

In the present invention, the cross-sectional flow area of the upper air duct may become narrower as the distance from the upper blowing unit increases.

In the present invention, the upper discharge column can be used separately from the discharge column.

The stand-type drying device of the present invention includes a base mounted on the floor, a housing located on the base and having an inlet, a blower unit located in the housing to suck air and flow through the inlet, and the housing. a discharge column that is installed and extends upward and has a discharge port extending longitudinally on the front; an upper discharge column that is rotatable at a predetermined angle at the top of the discharge column and discharges the air transmitted through the discharge column as it flows; , It may include a joint mechanism connecting the upper discharge column to the discharge column.

In the present invention, the joint mechanism may include a groove-shaped female joint provided at a corresponding position of the discharge column and the upper discharge column, and a hemispherical male joint inserted into the female joint.

In the present invention, a first through hole may be formed in the female joint, a second through hole may be formed in the water joint, and a connection duct may be installed through the first through hole and the second through hole to discharge the discharge. The air duct of the column can be connected to the upper air duct of the upper discharge column.

In the present invention, the first through hole and the second through hole may be formed at different positions so that the communication area varies depending on the relative rotation of the female joint and the male joint.

In the present invention, the connecting duct may be made of a flexible material, and as the communication area between the first through hole and the second through hole is different, the degree of tightening the connecting duct is varied to control the flow of air through the connecting duct. can do.

In the present invention, the discharge column includes a cylindrical column body with an inner column space formed inside and a long discharge port formed on the front in the longitudinal direction, and a flow path outlet installed in the column inner space to deliver air to the discharge port. It may include an air duct that receives air from the blowing unit.

In the present invention, the cross-sectional flow area of the air passage inside the air duct may become narrower as the distance from the blowing unit increases.

In the present invention, the air duct is inclined on both sides toward the flow path outlet, so that the front end of the cross section of the air duct can be sharp and the rear end of the cross section of the air duct can be curved.

In the present invention, a column suction port through which air surrounding the discharge column is sucked may be further formed on the column body opposite to the discharge port.

In the present invention, the column inlet may be provided with a filter that filters out foreign substances in the air passing through.

In the present invention, the upper discharge column includes a cylindrical upper column body with an upper column inner space formed inside and a longitudinal upper column discharge port formed on the front, and a cylindrical upper column body installed in the upper column inner space and the upper column discharge port. It may include an upper air duct that is provided with a flow path discharge port for delivering air to the blower unit and receives air from the blowing unit through a connection duct passing through the air duct of the discharge column and the joint mechanism.

In the present invention, the flow cross-sectional area of the upper air duct may become narrower as the distance from the blowing unit increases.

The stand-type drying device of the present invention includes a base mounted on the floor, a housing located on the base and having an inlet, a blower unit located in the housing to suck air and flow through the inlet, and installed in the housing. a discharge column that extends upward and has a discharge port that discharges air at the front extending longitudinally, and is installed at the top of the discharge column to be rotatable at a predetermined angle so that the air delivered through the discharge column flows through the upper column discharge port. It may include an upper discharge column that is discharged through, and the upper discharge column is rotatable between a state in which the upper discharge column is installed in a straight line with respect to the discharge column and a state in which it is rotated to have a predetermined angle, and the upper discharge column is configured to discharge the discharge column. As the inclination angle with respect to the column increases, the amount of air discharged through the upper column discharge port of the upper discharge column may increase.

In the present invention, air transfer between the discharge column and the upper discharge column can be achieved through a connecting duct made of a flexible material.

In the present invention, a female joint and a male joint may be formed at corresponding positions in the column body of the discharge column and the upper column body of the upper discharge column, a first through hole may be formed in the female joint, and the male A second through hole may be formed in the joint, and the area where the first through hole communicates with the second through hole varies depending on the angle at which the upper discharge column is rotated with respect to the discharge column, thereby controlling the air flow through the connection duct. can do.

In the present invention, the first through hole may be formed toward one side while including the center of the female joint, and the second through hole may be formed toward the other side while including the center of the male joint.

In the present invention, a first stop surface and a second stop surface may be formed on the column body of the discharge column and the upper column body of the upper discharge column, so that a range in which the upper discharge column rotates with respect to the discharge column can be set. there is.

In the present invention, the first stop surface may include a flat portion at an end of the column body orthogonal to the longitudinal direction of the column body and a predetermined inclined inclined portion in the longitudinal direction of the column body, and the second stop surface may include a flat portion at an end of the upper column body perpendicular to the longitudinal direction of the upper column body and a predetermined inclined inclined portion in the longitudinal direction of the column body, and the flat portions are in contact with each other and the inclined portion is The upper discharge column may be operated while the parts are in contact with each other.

The stand-type drying device of the present invention includes a base mounted on the floor, a housing located on the base and having an inlet, a blower unit located in the housing to suck air and flow through the inlet, and installed in the housing. When extended upward, the discharge port extends longitudinally on the front to discharge air, and the upper discharge column is detachably installed on the discharge column and generates air flow by an upper blower unit installed inside to discharge air. Can include columns.

In the present invention, the upper discharge column is formed by an upper column body having an upper column internal space formed therein and an upper column discharge port in the longitudinal direction on the front, and an upper blowing unit installed in the upper column internal space. It may include an upper air duct in which airflow flows along an upper air flow path formed therein, and the flow path discharge port is formed at a position corresponding to the upper column discharge port.

In the present invention, an upper column inlet may be formed in the upper column body on the opposite side of the upper column discharge port, and air that exits the flow path discharge port and joins the air delivered to the upper column discharge port is sucked in. It can be.

In the present invention, a filter may be installed at the upper column intake port.

In the present invention, the cross-sectional flow area of the upper air passage may become narrower as the distance from the upper blowing unit increases.

In the present invention, the discharge column is provided with a column body having a longitudinally long discharge port on the front, a flow path discharge port installed inside the column body to deliver air to the discharge port, and receiving air from the blowing unit. May include air ducts.

In the present invention, the cross-sectional flow area of the air passage inside the air duct may become narrower as the distance from the blowing unit increases.

In the present invention, the air duct is inclined on both sides toward the flow path outlet, so that the front end of the cross section of the air duct is sharp, the rear end of the cross section of the air duct is curved, and the flow cross-sectional area becomes narrower as the distance from the blowing unit increases. You can lose.

In the present invention, a column suction port through which air surrounding the discharge column is sucked may be further formed on the column body opposite to the discharge port.

In the present invention, the column inlet may be provided with a filter that filters out foreign substances in the air passing through.

In the present invention, a first stop surface and a second stop surface may be formed on the column body of the discharge column and the upper column body of the upper discharge column, so that a range in which the upper discharge column rotates with respect to the discharge column can be set. there is.

In the present invention, the first stop surface may include a flat part orthogonal to the longitudinal direction of the column body at an end of the column body and a predetermined inclined inclined part in the longitudinal direction of the column body, and the second stop surface. may include a flat portion at an end of the upper column body perpendicular to the longitudinal direction of the upper column body and a predetermined inclined inclined portion in the longitudinal direction of the upper column body, and the flat portions are in contact with each other and the inclined portion is The upper discharge column may be operated while the parts are in contact with each other.

The stand-type drying device of the present invention includes a base mounted on the floor, a housing located on the base and having an inlet, a blower unit located in the housing to suck air and flow through the inlet, and installed in the housing. A discharge column that extends upward and has a discharge port extending longitudinally on the front to discharge air, and an upper discharge column that is detachably installed on the discharge column and discharges air by generating air flow by an upper blowing unit installed inside. It may include a column and a joint mechanism that connects the discharge column and the upper discharge column to be relatively rotatable and detachable.

In the present invention, the joint mechanism may include a groove-shaped female joint and a hemispherical male joint provided at corresponding positions of the discharge column and the upper discharge column.

In the present invention, a first connection through hole may be formed through the female joint, and a second connection through hole may be formed through the male joint at a position corresponding to the first connection through hole, and the first and The connector installed in the female joint through the second connector hole can be hung on the male joint.

In the present invention, the connector includes a connector body, a button provided on one side of the connector body and exposed to one side of the discharge column, and a button provided on the other side of the connector body and hung on one side of the water joint and connected to the upper discharge column. It may include a hanging jaw that becomes the center of rotation.

In the present invention, the button of the connector may be supported by an elastic member supported on one side by the female joint.

A portion of the outer surface of the hanging ledge may have a guide curved surface, and a guide curved surface through which the guide curved surface of the hanging ledge is guided may be formed at a hanging guide end formed on one inner side of the water joint.

In the present invention, a friction pad may be provided between the inner surface of the female joint and the outer surface of the male joint to provide frictional force during relative rotation between the female joint and the male joint.

In the present invention, a first electrode may be installed in the female joint, and a second electrode electrically connected to the first electrode may be positioned in the electrode slot formed in the male joint.

In the present invention, the electrode slot is formed to extend long in the water joint so that the arc-shaped second electrode can be positioned, and the first electrode has a protrusion shape that contacts while moving relative to the second electrode. It can be.

The stand-type drying apparatus according to the present invention can have at least one of the following effects.

The stand-type drying device of the present invention has a housing on a base that is seated on the ground, and a rod-shaped discharge column extends upward from the housing. Therefore, when placed in a desired location, moisture can be removed by spraying air onto the user's entire body through the discharge column.

In the present invention, the discharge column has a height corresponding to the user's height, and long discharge openings are formed in the vertical direction of the discharge column, so that moisture can be removed by simultaneously spraying air over the entire user's body.

In the present invention, the housing where the discharge column is installed can rotate by a predetermined angle with respect to the base seated on the ground. Therefore, the discharge column can spray air while drawing a circumferential trajectory with a predetermined radius of curvature according to the rotation of the housing, so that drying can be performed smoothly over the entire width direction of the user's body.

In the present invention, an upper discharge column may be further provided at the top of the discharge column to be rotated vertically at a predetermined angle. As air is discharged from the upper discharge column, it is possible to dry the entire body of a user who is taller than average, and the head of a general user can be dried more reliably.

The upper discharge column can be rotated at a predetermined angle in the vertical direction with respect to the discharge column. When air is sprayed from the upper discharge column at a predetermined angle, the upper part of the user's head located below it is dried more reliably. can do.

In the present invention, when the airflow formed by the blowing unit flows and is sprayed from the air duct, the flow of the sprayed air causes air flow along the outer surface of the air duct, and the air around the discharge duct is sucked in and sprayed from the air duct. It can be combined with the air and discharged through the discharge port of the discharge column. Therefore, the volume of air discharged through the discharge port of the discharge column can be relatively increased.

In the present invention, the internal flow cross-sectional area of the air duct inside the discharge column becomes narrower as the distance from the blowing unit increases. Accordingly, the amount of air discharged through the flow path discharge port of the air duct can be made uniform throughout the entire flow path discharge port. This has the effect of allowing air to be discharged uniformly from the entire discharge port area of the discharge column.

In the present invention, when the airflow formed by the upper blowing unit is sprayed from the upper air duct even in the upper discharge column connected to the upper part of the discharge column, the flow of this sprayed air generates air flow along the outer surface of the upper air duct, thereby forming the upper airflow. The air around the discharge duct is sucked in, combined with the air sprayed from the upper air duct, and can be sprayed from the upper column discharge port of the upper discharge column. Therefore, the volume of air discharged through the upper column discharge port of the upper discharge column can be relatively increased.

In the present invention, a spray nozzle can be installed at the discharge port of the discharge column or the upper column discharge port of the upper discharge column. The spray nozzle allows the air sprayed from the discharge port or the upper column discharge port to travel farther and at the same time prevents external air from mixing with the air sprayed from the spray nozzle.

In the present invention, an upper discharge column may be further placed above the discharge column. At this time, the upper discharge column can receive air through the discharge column and spray it. That is, there is no driving source for air flow inside the upper discharge column, and only the blowing unit in the housing can be used to allow air to flow. Therefore, there is an effect that air can be sprayed to more areas and no additional driving source is used.

In the present invention, there may be a connecting duct made of a flexible material between the discharge column and the upper discharge column. The connecting duct transmits air between the discharge column and the upper discharge column, and the amount of air transmitted can be adjusted depending on the rotational position of the upper discharge column with respect to the discharge column. Therefore, drying can be performed by varying the amount of air sprayed while adjusting the installation angle of the upper discharge column.

In the present invention, the discharge column and the upper discharge column can be connected to be relatively rotatable using a joint mechanism. The joint mechanism includes a female joint in which a first through hole is formed and a male joint in which a second through hole is formed, and a connection duct may be installed simultaneously penetrating the first through hole and the second through hole. The connection duct may be pressed by the female joint and the male joint differently depending on the area where the first through hole communicates with the second through hole, thereby changing the amount of air flow flowing through the inside.

In the present invention, the upper discharge column is detachably installed on the discharge column by a joint mechanism. The female joint and the water joint at the corresponding positions of the discharge column and the upper discharge column are combined, and at the same time, the hook of the connector on the female joint side is hung on one side of the water joint, making the upper discharge column more secure to the discharge column. Can be installed.

In the present invention, a connector can be further used to combine the female joint and the male joint. The hanging jaw in the connector is hung on the side of the water joint, and since the guide curve of the hanging jaw is guided to the guide curve of the hanging jaw guide end on the water joint side, rotation of the water joint side can occur more smoothly and accurately.

In the present invention, the female joint and the male joint have a first electrode and a second electrode, and the second electrode may be moved relative to the first electrode and always be in contact with each other. Therefore, when the female joint and the male joint are combined, power is connected through the first electrode and the second electrode, and power can be smoothly supplied to the upper discharge column.

In the present invention, a friction pad may be installed between the female joint and the male joint that constitute the joint mechanism. Frictional force is generated during relative movement between the female joint and the male joint by the friction pad. Accordingly, the relative movement between the female joint and the male joint does not occur arbitrarily, but occurs by a force exceeding a certain level, and relative rotation can be performed more precisely.

1 is a perspective view showing the appearance of a preferred embodiment of a stand-type drying apparatus according to the present invention.
Figure 2 is a side view showing the configuration of the upper discharge column in an inclined state in the embodiment shown in Figure 1.
Figure 3 is a cross-sectional view seen from the direction of Figure 2.
Figure 4 is a perspective view showing the lower part of the base, housing, and discharge column constituting an embodiment of the present invention.
Figure 5 is a cross-sectional perspective view showing the internal structure of the base and housing constituting an embodiment of the present invention.
Figure 6 is a cross-sectional perspective view showing a configuration for rotating the housing and discharge column in an embodiment of the present invention.
Figure 7 is a cross-sectional view taken along line 7-7' of Figure 2.
Figure 8 is a perspective view showing the configuration of a base constituting an embodiment of the present invention.
Figure 9 is a cross-sectional perspective view showing a housing constituting an embodiment of the present invention.
Figure 10 is a perspective view showing an air guide constituting an embodiment of the present invention.
Figure 11 is a perspective view showing a discharge column and an upper discharge column constituting an embodiment of the present invention.
Figures 12 (a), (b), and (c) are cross-sectional views taken along lines a-a', b-b', and c-c' of Figure 3, respectively.
Figure 13 is a perspective view of an air flow path installed inside a discharge column constituting an embodiment of the present invention.
Figure 14 is a cross-sectional view showing the relative position between the separation guide and the connection portion of the air passage in an embodiment of the present invention.
Figure 15 (a) is a cross-sectional view showing the inside of the upper discharge column constituting an embodiment of the present invention, and (b) is a perspective view showing the upper air passage and upper blowing unit inside the upper discharge column.
Figure 16 is a perspective view showing a joint mechanism for connection and angle adjustment between the discharge column and the upper discharge column in an embodiment of the present invention.
Figure 17 is a cross-sectional perspective view showing the joint mechanism constituting an embodiment of the present invention and its surrounding structure.
Figure 18 is a cross-sectional view showing that a dispersion nozzle is further installed at the discharge port of the discharge column in an embodiment of the present invention.
Figure 19 is a cross-sectional view showing a joint mechanism and a connection duct connecting a discharge column and an upper discharge column in another embodiment of the present invention.
Figure 20 is an exploded perspective view mainly showing the discharge column side with the joint mechanism constituting the embodiment shown in Figure 19 separated.
Figure 21 is an exploded perspective view mainly showing the upper discharge column side with the joint mechanism constituting the embodiment shown in Figure 19 separated.
Figure 22 is a perspective view showing the configuration of a connection duct used in the embodiment shown in Figure 19.
Figure 23 is a perspective view showing that in the embodiment shown in Figure 19, the upper discharge column is rotated obliquely with respect to the discharge column and air is transferred from the discharge column side to the upper discharge column side through the connection duct.
Figure 24 is a partial perspective view showing a joint mechanism connecting a discharge column and an upper discharge column in another embodiment of the present invention.
Figure 25 is a cross-sectional perspective view showing the internal structure of the embodiment shown in Figure 24.
Figure 26 is an exploded perspective view showing the configuration of the embodiment shown in Figure 24.
Figure 27 is a front cross-sectional view showing the configuration of the embodiment shown in Figure 24.
Figure 28 is an exploded perspective view mainly showing the female joint in the joint mechanism constituting the embodiment shown in Figure 24.
Figure 29 is an exploded perspective view mainly showing the male joint in the joint mechanism constituting the embodiment shown in Figure 24.
Figure 30 is a cross-sectional perspective view showing the internal structure of the water joint of the example shown in Figure 24.
Figure 31 is a perspective view showing a connector used in the embodiment shown in Figure 24.
Figure 32 is an operating state diagram showing that the direction of air sprayed from the discharge port of the discharge column changes as the housing rotates at a predetermined angle with respect to the base in an embodiment of the present invention.
Figure 33 is an operating state diagram showing air flowing by the operation of the blowing unit in an embodiment of the present invention.
Figure 34 is an operating state diagram showing that the air sucked by the blower unit and the air sucked from the column inlet are combined and discharged from the discharge port in an embodiment of the present invention.
Figure 35 is an operating state diagram showing air being sprayed through a discharge nozzle in an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through illustrative drawings. When adding reference numerals to components in each drawing, it should be noted that identical components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, when describing embodiments of the present invention, if detailed descriptions of related known configurations or functions are judged to impede understanding of the embodiments of the present invention, the detailed descriptions will be omitted.

The configuration of the stand-type drying apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 and 2 show the overall appearance of an embodiment of the present invention. According to this, there is a base 10 to be seated on the floor, and the housing 20 can be installed on the base 10. Inside the housing 20, there may be a blowing unit 30 (see FIG. 3). There is a discharge column 40 coupled to one side of the housing 20 and extending upward from the housing 20. The discharge column 40 may be rod-shaped and have a long discharge port 418 (see FIG. 12) in the longitudinal direction. There may be an additional upper discharge column 50 above the discharge column 40. The upper discharge column 50 may be in the state of FIG. 1, which is in a straight line with respect to the discharge column 40, and the state of FIG. 2, which is at a predetermined angle. For this purpose, there may be a joint mechanism 60 between the discharge column 40 and the upper discharge column 50.

For reference, the upper discharge column 50 is not necessarily present. For example, if the user's head can be sufficiently dried by the air discharged from the discharge column 40, the upper discharge column 50 may be omitted. However, since the upper discharge column 50 can adjust its installation angle, it is relatively convenient to dry the upper part of the user's head.

With reference to FIGS. 5 to 8 , the base 10 and its related configuration will be examined. The base 10 may serve to support the entire device on the ground. The base 10 directly supports the housing 20. Since the discharge column 40 is fixed to the housing 20, the discharge column 40 can be viewed as indirectly supported by the base 10. The blowing unit 30 is located inside the housing 20, and the blowing unit 30 is also indirectly supported by the base 10.

The base body 110 forms the skeleton of the base 10. The base body 110 may be approximately disk-shaped. There may be a rotation center 112 at the center of the base body 110. The rotation center 112 may protrude upward from the upper surface of the base body 110.

The rotation center 112 may be composed of a disk-shaped top plate 114 and a side wall 116 surrounding the edge of the top plate 114 in a ring shape. The rotation center 112 may be the rotation center of the housing 20. The rotation center 112 may have a hollow cylindrical shape. The side wall 116 has a step 118. Due to the step portion 118, the outer diameter of the lower part of the rotation center table 112 becomes larger than the outer diameter of the upper part. The housing 20 may be rotatably supported on the stepped portion 118.

There may be a driving window 120 on one side of the side wall 116. The driving window 120 is designed to transmit the driving force of the driving source 230, which will be described below, to the housing 20. The driving window 120 is formed through the side wall 116. The driving window 120 may be formed on a side of the side wall 116 with a relatively smaller outer diameter.

The interior of the rotation center 112 is a drive source space 122. As shown in FIGS. 4 to 6, the drive source space 122 may have a groove shape when viewed from the bottom of the base 10. A drive source 230 may be installed within the drive source space 122.

The surface connecting the rotation center 112 and the base body 110 is a connection curved surface 124. As can be seen in FIG. 8, the connecting curved surface 124 is a curved surface having a predetermined radius of curvature. The connecting curved surface 124 can guide air entering the intake port 222 of the housing 20, which will be described below.

The housing 20 may be installed to rotate around the rotation center 112 of the base 10. The housing 20 has a cylindrical shape, as shown in FIGS. 5 and 9. The housing 20 has a cylindrical shape and can be rotatably installed on the base 10 in an upright state.

The housing body 210 may form the skeleton of the housing 20. The housing body 210 has a cylindrical shape, has a disk-shaped end plate 212 at the top, and has a cylindrical side wall 214 on its outer surface. Inside the housing body 210, there is an internal space 216. The blowing unit 30 may be installed in the internal space 216.

A column installation portion 218 may be formed on one side of the side wall 214 of the housing body 210. In this embodiment, the column installation portion 218 penetrates the side wall 214. However, the column installation portion 218 may be formed to be recessed into the side wall 214. The discharge column 40 is installed in the column installation part 218. Approximately half of the cross section of the discharge column 40 may be inserted and positioned in the column installation portion 218.

The lower part of the housing body 210 is open. The open portion of the housing body 210 is the rotation center hole 219. The rotation center 112 of the base 10 may be located in the rotation center hole 219. A support wall 220 may be in a ring shape surrounding a position at a predetermined distance from the edge of the rotation center hole 219. The drive unit 30 may be supported on the support wall 220.

There is an intake port 222 at a position adjacent to the edge of the rotation center hole 219, which is inside the support wall 220. The intake port 222 may be a path through which external air is sucked into the blowing unit 30. The intake port 222 may be partitioned by a plurality of partition walls 224. There is a driven gear 226 to connect the partition walls 224. The driven gear 226 is located at the edge of the rotation center hole 219. The driven gear 226 has a ring shape and has gear teeth formed on its inner surface, so it is a type of internal gear. As the partition walls 224 connect the driven gear 226 and the support wall 220, the suction port 222 is formed between the partition walls 224. For reference, as can be seen in FIG. 7, the suction port 222 may be formed adjacent to the rotation center 112 of the base 10. The intake port 222 is made in the shape of a narrow slit. This is to prevent foreign substances from the outside from entering the interior through the intake port 222.

The driving force that causes the housing 20 to rotate with respect to the base 10 may be provided by the driving source 230. The driving source 230 may be within the driving source space 122 of the base 20. In the illustrated embodiment, the drive source 230 is simply located within the drive source space 122. However, the drive source 230 may be fixed to the base 10 by a bracket, etc., not shown.

There may be a driving gear 232 rotated by the driving source 230 and an interlocking gear 234 rotated by the driving gear 232. The driving gear 232 and the interlocking gear 234 may be installed on the base 10. The interlocking gear 234 may be coupled to the driven gear 226 to transmit the driving force of the driving source 230. The driving force of the driving source 230 may be directly transmitted to the driven gear 226 through the driving gear 232 without the interlocking gear 234. Alternatively, instead of the interlocking gear 234, a plurality of gears may be used to reduce speed and transmit the driving force to the housing 20.

Next, the configuration of the blowing unit 30 will be described. The blowing unit 30 draws air from the outside of the housing 20 and forms an airflow to discharge it through the discharge port 418 of the discharge column 40. The blowing unit 30 may be located within the internal space 216 of the housing 20. A fan duct 310 may form the exterior of the blowing unit 30. The fan duct 310 may be installed while being supported on the support wall 220. The fan duct 310 may have a cylindrical shape.

A motor 312 and a fan 314 may be installed inside the fan duct 310. As the fan 314 rotates due to the driving force of the motor 312, an airflow passing through the fan duct 310 may be formed. Although the structure for fixing the motor 312 is not shown in the drawing, the motor 312 may be supported by a separate bracket or a structure formed in the fan duct 310. The fan 314 is rotated by the motor 312 to form an airflow.

There is an air guide 320 to connect the fan duct 310 with the air duct 420 of the discharge column 40, which will be described below. The configuration of the air guide 320 is clearly shown in Figure 10. There is a fan duct connection part 322 on one side of the air guide 320 and a duct connection part 324 on the other side. The fan duct 310 may be connected to the fan duct connection part 322. The connection pipe 434 of the air duct 420, which will be described below, may be connected to the duct connection part 324. A guide passage 326 is formed inside the air guide 320 to guide the flow of air. The flow cross-sectional area of the guide passage 326 may gradually become narrower as it moves from the fan duct 310 side to the air duct 420 side.

The discharge column 40 is coupled to the housing 20 and may extend long upward. The height of the discharge column 40 is about the same as the height of an average user. The discharge column 40 is rod-shaped. By making the discharge column 40 rod-shaped, the width-wise size of the entire device can be greatly reduced. The width of the discharge column 40 is relatively narrow compared to the housing 20. The width of the discharge column 40 is less than approximately 1/4 of the width of the housing 20. Accordingly, the space occupied by the discharge column 40 is much smaller than the space occupied by the housing 20.

The column body 410 can form the exterior and framework of the discharge column 40. The column body 410 may have an overall cylindrical shape. A column internal space 412 may be formed inside the column body 410. The column internal space 412 may have the same cross-sectional area throughout the entire section of the column body 410.

A column inlet 414 may be formed in the column body 410. The column suction port 414 may be formed in a section corresponding to the discharge port 418, which will be described below. Air around the discharge column 40 can be sucked into the column internal space 412 through the column inlet 414. The column inlet 414 may have a predetermined width. The column inlet 414 is in a position that is not visible when the user stands in front of the discharge column 40. That is, the column suction port 414 may be formed on the rear surface of the discharge column 40. A filter 416 may be installed at the column inlet 414. The filter 416 prevents foreign substances from entering the column internal space 412 through the column inlet 414.

There is a discharge port 418 at the front of the column body 410. The discharge port 418 may be formed to be long in the vertical direction of the column body 410. The air discharged through the discharge port 418 may be delivered to the user's body. The discharge port 418 may have a narrow slit shape. The width of the discharge port 418 may be very narrow compared to the column suction port 414. As a result, air can be discharged through the discharge port 418 at a relatively high speed. Through the discharge port 418, the air delivered through the air duct 420, which will be described below, and the air sucked through the column intake port 414 may be combined and discharged.

An air duct 420 may be installed in the column inner space 412. The air duct 420 is a part through which air delivered through the air guide 320 by the blowing unit 30 flows. Inside the air duct 420, there is an air passage 422. The air flowing through the air passage 422 may be sprayed onto the user's body through the discharge port 418 of the discharge column 40.

The air flow path 422 may have a relatively wide flow cross-sectional area on the side closer to the blowing unit 30, and the flow cross-sectional area may gradually become narrower as it moves away from the blowing unit 30. This is to ensure that the amount of air discharged through the outlet 418 is uniform throughout the entire section of the outlet 418. Figures 12 (a), (b), and (c) show the cross-sectional shape of the discharge column 40 at each position. As can be seen here, the flow cross-sectional area of the air passage 422 becomes narrower toward the upper part of the air duct 420, that is, farther away from the blowing unit 30.

As can be seen in FIG. 13, the air duct 420 has a flow path outlet 424. The flow path outlet 424 is a part of the air duct 420 through which air is discharged. The flow path discharge port 424 may be located in a position corresponding to the discharge port 418. That is, the flow path outlet 424 may be formed in a slit shape long in the longitudinal direction of the air duct 420. Therefore, the air coming out of the flow path outlet 424 can directly enter the outlet 418. As can be seen in FIG. 13, the flow path outlet 424 is formed in most sections of the air duct 420 in the longitudinal direction.

The portion of the air duct 420 where the flow path discharge port 424 is formed is called the tip portion 426. The part opposite to the front end 426, that is, the part of the air duct 420 facing the column inlet 414 of the discharge column 40, is called the rear end 428. When viewed in cross section of the air duct 420, the width of the air duct 420 becomes narrower toward the distal end 426. That is, when the air duct 420 is viewed from the outside, the portion where the flow path outlet 424 is formed is sharp to allow air to be guided more smoothly through the outer surface of the air duct 420. The rear end 428 forms a curved surface. The curved surface of the rear end 428 allows the air sucked through the column inlet 414 to be smoothly distributed to both sides. This configuration can be seen in Figure 12.

When air is discharged from the flow path outlet 424 of the air duct 420 at high speed, the pressure around the tip 426 of the air duct 420 is lowered and the surrounding air can be sucked in. Therefore, air can be sucked in through the column inlet 414. This air may flow to both sides of the air duct 420 along the curved surface of the rear end 428 and may flow to the front end 426 along both outer surfaces of the air duct 420. In this way, the air flowing along the outer surface of the air duct 420 gathers on both sides of the air discharged from the flow path outlet 424 by the Coanda effect to prevent the discharged air from scattering, and these airs are It may be sprayed through the discharge port 418 of the column duct 40 and delivered to the user. For reference, if the amount of air flowing through the air passage 422 of the air duct 420 and discharged through the discharge port 418 is sufficient for drying the user, the air Air may be supplied using only the duct 420.

The air duct 420 may have a separation guide 430. The separation guide 430 may protrude into the air passage 422. The separation guide 430 allows the air delivered to the air duct 420 to separate and flow. The separation guide 430 separates the air flowing into the air passage 422 through the duct connection part 324 of the air guide 320 and allows it to flow. The separation guide 430 protrudes toward the duct connection portion 324 and may have curved surfaces extending in opposite directions to guide air toward the upper and lower portions of the air passage 422. The position of the tip of the separation guide 430 may be at 1/4 of the height direction of the duct connection part 324. That is, in FIG. 14, a:b may have a ratio of 3:1. Approximately 25% of the air flowing by the blower unit 30 and entering the air duct 420 flows into the lower air passage 432 and is discharged through the discharge port 418 at the bottom of the separation guide 430. Approximately 75% of the air may flow toward the top of the air duct 420 and be discharged through the discharge port 418 at the top of the separation guide 430.

The air duct 420 may have a connection pipe 434. The connection pipe 434 is a part connected to the duct connection part 324 of the air guide 320. Accordingly, the airflow formed by the blowing unit 30 may pass through the air guide 320 and flow into the air passage 422 inside the air duct 420.

Meanwhile, the upper discharge column 50 may be located at the top of the discharge column 40. The configuration of the upper discharge column 50 is clearly shown in Figures 15(a) and (b). The upper column body 510 may form the exterior and framework of the upper discharge column 50. The upper column body 510 may have a cylindrical shape. An upper column internal space 512 may be formed inside the upper column body 510.

An upper column inlet 514 may be formed in the upper column body 510. Air around the upper discharge column 50 can be sucked in through the upper column inlet 514. A filter 516 is installed at the upper column inlet 514 to filter out foreign substances in the air.

The upper column body 510 has a discharge port 518. Air may be discharged through the discharge port 518. The air coming out of the discharge port 518 can be sprayed on the user to perform a drying effect. The air coming out of the discharge port 518 may be mainly sprayed onto the user's head. The discharge port 518 may be formed in a long slit shape in the longitudinal direction of the upper column body 510.

An upper air duct 520 may be installed in the upper column internal space 512 of the upper column body 510. The upper air duct 520 may have a similar configuration to the air duct 420. The upper air duct 520 is much shorter in length than the air duct 420. The flow cross-sectional area of the upper air passage 522 inside the upper air duct 520 may gradually become narrower as it moves in one direction. That is, the flow cross-sectional area may become narrower as you move away from the upper blowing unit 530, which will be explained below.

The upper air duct 520 may have a flow path outlet 524 formed long in the longitudinal direction of the upper air duct 520. This is best shown in Figure 15. The external shape of the upper air duct 520 is almost the same as that of the air duct 420. The air discharged through the flow path outlet 524 may be discharged to the outside through the outlet 518 of the upper column body 510.

There may be an upper blowing unit 530 on one side of the upper air duct 520. The upper blowing unit 530 has a fan and a motor inside to suck in external air and cause it to flow into the upper air duct 520. The upper blowing unit 530 is equipped with a battery (not shown) and can be operated using charged power. The battery can be charged by connecting power through the discharge column 40, the upper discharge column 50, and the joint mechanism 60. The drawing does not show a configuration in which air can be sucked in from the outside into the upper blowing unit 530. However, a through hole is formed at one end of the upper column body 510 so that external air can be sucked into the upper blowing unit 530.

The upper discharge column 50 can be attached to or detached from the discharge column 40. For this purpose, the discharge column 40 and the upper discharge column 50 may be connected by a joint mechanism 60. The joint mechanism 60 is best shown in FIGS. 16 and 17.

In the joint mechanism 60, the female joint 610 on the discharge column 40 side and the male joint 620 on the upper discharge column 50 side can be coupled to each other so as to be rotatable relative to each other. The female joint 610 may be formed in a groove shape in the column body 410. The male joint 620 may be inserted into the female joint 610.

The female joint 610 may be composed of a hemispherical groove. There may be a first stop surface 612 surrounding the edge of the female joint 610. The first stop surface 612 may be at the end of the column body 410. The first stop surface 612 may have a flat portion 614 and an inclined portion 616. The flat portion 614 is a portion formed perpendicular to the longitudinal direction of the column body 410, and the inclined portion 616 is a portion formed at a predetermined angle with respect to the longitudinal direction of the column body 410.

The water joint 620 may be configured to protrude in a hemispherical shape. The male joint 620 is inserted into the female joint 610 and is capable of relative rotation. The water joint 620 may have a second stop surface 622. The second stop surface 622 may be formed at the end of the upper column body 510. The second stop surface 622 may have a flat portion 624 and an inclined portion 626. The flat portion 624 is a portion formed perpendicular to the longitudinal direction of the upper column body 510, and the inclined portion 626 is a portion formed at a predetermined slope with respect to the longitudinal direction of the upper column body 510. .

The flat portion 614 of the first stop surface 612 faces the flat portion 624 of the second stop surface 622, and the inclined portion 616 of the first stop surface 612 faces the second stop surface. It can face the inclined portion 626 of 622. When the discharge column 40 and the upper discharge column 50 are arranged in a straight line, the flat portion 614 of the first stop surface 612 and the flat portion 624 of the second stop surface 622 are in contact with each other. There is (see Figure 17).

When the upper discharge column 50 is rotated to the maximum with respect to the discharge column 40, the inclined portion 616 of the first stop surface 612 and the inclined portion 626 of the second stop surface 622 is in contact (see Figure 16).

For reference, in the configuration of the joint mechanism 60, the positions of the female joint 610 and the male joint 620 may be reversed from those in the illustrated embodiment. The female joint 610 and the male joint 620 may have structures such as the first electrode 850, the second electrode 860, and the friction pad 870 of the embodiment described below.

Meanwhile, Figure 18 shows an example in which a spray nozzle 440 is added to the discharge port 418 of the discharge column 40. The spray nozzle 440 allows air passing through the discharge port 418 to be sprayed to the user. There is a spray passage 422 penetrating the inside of the spray nozzle 440. There is an expansion portion 444 at the tip of the injection passage 422. The expanded portion 444 is a portion whose flow cross-sectional area is formed to rapidly increase.

In this way, there is a spray nozzle 440, and the expansion portion 444 is located at the tip of the spray nozzle 440, so that the air around the discharge port 418 of the discharge column 40 flows through the spray nozzle 440. It can be prevented from mixing with the air discharged through it. This is because the expansion portion 444 guides the air around the discharge port 418 of the discharge column 40 to move away from the spray passage 422. By adding and installing the spray nozzle 440, unpurified air is prevented from mixing with the air sprayed through the spray nozzle 440.

Figure 19 shows another embodiment of the present invention. In the embodiment shown here, the upper discharge column 50 located above the discharge column 40 receives the airflow formed in the blowing unit 30 through the air duct 420. Therefore, in this embodiment, there is no need for a separate upper blowing unit 530 in the upper discharge column 50, and power supply is not required.

In this embodiment, the discharge column 40 and the upper discharge column 50 can be connected to each other so that the joint mechanism 70 can rotate relative to them. The joint mechanism 70 has a similar configuration to the joint mechanism 60 described in the above embodiment, but the connection duct 730 extends through the joint mechanism 70 to connect the discharge column 40. The air duct 420 and the upper air duct 520 of the upper discharge column 50 are communicated to allow air flow.

In the joint mechanism 70, the female joint 710 on the discharge column 40 side and the male joint 720 on the upper discharge column 50 side can be coupled to each other so as to be rotatable relative to each other. The female joint 710 may be formed in a groove shape in the column body 410. The male joint 720 may be inserted into the female joint 710.

The female joint 710 may be composed of a hemispherical groove. The female joint 710 may have a first stop surface 712. The first stop surface 712 is the end of the column body 410. The first stop surface 712 may have a flat portion 714 and an inclined portion 716. The flat portion 714 is a portion formed perpendicular to the longitudinal direction of the column body 410, and the inclined portion 716 is a portion formed at a predetermined angle with respect to the longitudinal direction of the column body 410.

A first through hole 718 may be formed on one side of the female joint 710. The first through hole 718 is formed through the female joint 710. Accordingly, the column inner space 412 and the interior of the female joint 710 may be communicated through the first through hole 718. A connection duct 730, which will be described below, can pass through the first through hole 718. The first through hole 718 may be formed to be biased to one side including the center of the female joint 710. This is to allow the communication area with the second through hole 728, which will be explained below, to be varied depending on the degree to which the upper discharge column 50 is rotated with respect to the discharge column 40.

The water joint 720 may protrude in a hemispherical shape. The male joint 720 is inserted into the female joint 710 and can be relatively rotated. The water joint 720 may have a second stop surface 722. The second stop surface 722 is the end of the upper column body 510. The second stop surface 722 may have a flat portion 724 and an inclined portion 726. The flat portion 724 is a portion formed perpendicular to the longitudinal direction of the upper column body 510, and the inclined portion 726 is a portion formed at a predetermined slope with respect to the longitudinal direction of the upper column body 510. .

The flat portion 714 of the first stop surface 712 faces the flat portion 724 of the second stop surface 722, and the inclined portion 716 of the first stop surface 712 faces the second stop surface. It can face the inclined portion 726 of 722. When the discharge column 40 and the upper discharge column 50 are arranged in a straight line, the flat portion 714 of the first stop surface 712 and the flat portion 724 of the second stop surface 722 are in contact with each other. There is (see Figure 19).

When the upper discharge column 50 is rotated to the maximum with respect to the discharge column 40, the inclined portion 716 of the first stop surface 712 and the inclined portion 726 of the second stop surface 722 is in contact (see Figure 23).

A second through hole 728 may be formed on one side of the water joint 720. The upper column inner space 512 and the outside may be communicated through the second through hole 728. The connection duct 30 may extend through the second through hole 728. The location where the second through hole 728 is formed is biased toward the other side, including the center of the water joint 720. That is, when the discharge column 40 and the upper discharge column 50 are arranged in a straight line, the first through hole 718 and the second through hole 728 overlap and the communicating area becomes the narrowest (see Figure 19). ), when the upper discharge column 50 is rotated and disposed inclined with respect to the discharge column 40, the first through hole 718 and the second through hole 728 overlap, so that the communication area can be maximized. (See Figure 23)

As can be seen in FIG. 19, in this embodiment, the air duct 420 and the upper air duct 520 are communicated by a connection duct 730. Accordingly, the air flowing in the air duct 420 may be delivered to the upper air duct 520 through the connecting duct 730. The connection duct 730 may be made of a flexible material. The connection duct 730 can be freely bent, and the internal flow cross-sectional area can be adjusted by being pressed by an external force.

The configuration of the connection duct 730 is well shown in Figure 22, where the connection duct body 732 can form the exterior and framework. The connection duct body 732 is made of a flexible material, and a connection passage 734 is formed penetrating the inside. Air may flow through the connection passage 734. At one end of the connection duct body 732, there is an air duct connection part 736 connected to the air duct 420, and at the other end there is an upper air duct connection part 738 connected to the upper air duct 520. there is. The air duct connection part 736 may have a shape corresponding to the shape of the air duct 420 to be coupled, and the upper air duct connection part 738 may have a shape corresponding to the shape of the upper air duct 520 to be coupled. You can have

As can be seen in FIG. 19, when the connecting area between the first through hole 718 and the second through hole 728 through which the connection duct 730 passes simultaneously is the smallest, the first through hole 718 and the second through hole 718 The connection duct 730 may be pressed by the edge of the through hole 728, thereby narrowing or closing the internal flow cross-sectional area. In this state, no air or a small amount of air may be transmitted to the upper air duct 520 through the connection duct 730. The amount of air flowing through the connection duct 730 may be determined depending on the size of the overlapping area of the first through hole 718 and the second through hole 728.

Meanwhile, as can be seen in FIG. 23, when the communicating area between the first through hole 718 and the second through hole 728 is the largest, no external force acts on the connecting duct 730, and the connecting passage 734 ) can be maintained at its largest cross-sectional flow area. Therefore, the largest amount of air can be delivered to the upper air duct 520 through the connection passage 734. When the inclination of the upper discharge column 50 is adjusted to be in a position between FIGS. 19 and 23 with respect to the discharge column 40, the amount of air discharged through the upper discharge column 50 can be adjusted. there is. When the upper discharge column 50 is rotated the most with respect to the discharge column 40, the amount of air discharged through the upper discharge column 50 increases. Therefore, the user's head and its surroundings can be dried better.

Another embodiment is shown in Figures 24 to 31. Here, the upper discharge column 50 is detachably connected to the discharge column 40 by a joint mechanism 80. The joint mechanism 80 can be connected to a power source, so that power can be supplied to the upper blowing unit 530 inside the upper discharge column 50. It is also possible to charge a battery (not shown) in the upper blowing unit 530, and the upper discharge column 50 can be used separately from the discharge column 40. In this case, the upper discharge column 50 can be held by the user's hand and used to dry various parts of the body.

In this embodiment, the upper discharge column 50 is detachable from the discharge column 40. For this purpose, the joint mechanism 80 has a connector 830, and the upper discharge column 50 is connected to the discharge column by pressing the button 834 of the connector 830 to adjust the position of the connector 830. It can be mounted and removed at (40).

In the joint mechanism 80, the female joint 810 (see Fig. 28) on the discharge column 40 side and the water joint 820 (see Fig. 29) on the upper discharge column 50 side are relative to each other. Can be rotatably coupled. The female joint 810 may be formed in a groove shape in the column body 410. The male joint 820 may be inserted into the female joint 810.

The female joint 810 may be composed of a hemispherical groove. The female joint 810 may have a first stop surface 812. The first stop surface 812 is the end of the column body 410. The first stop surface 812 may have a flat portion 814 and an inclined portion 816. The flat portion 814 is a portion formed perpendicular to the longitudinal direction of the column body 410, and the inclined portion 816 is a portion formed at a predetermined angle with respect to the longitudinal direction of the column body 410.

First connection holes 817 may be formed through the female joint 810 on both sides. A button hole 410' is formed at a position of the column body 410 corresponding to the first connection hole 817. The connector 830 may be installed through the first connector hole 817.

There is a support plate 818 within the female joint 810 corresponding to one edge of the first connection hole 817. The support plate 818 is a portion that supports one side of the elastic member 840, which will be described below. The support plate 818 may face the button hole 410'.

The water joint 820 may be configured to protrude in a hemispherical shape. The male joint 820 is inserted into the female joint 810 and is capable of relative rotation. The water joint 820 may have a second stop surface 822. The second stop surface 822 is the end of the upper column body 510. The second stop surface 822 may have a flat portion 824 and an inclined portion 826. The flat portion 824 is a portion formed perpendicular to the longitudinal direction of the upper column body 510, and the inclined portion 826 is a portion formed at a predetermined slope with respect to the longitudinal direction of the upper column body 510. .

The flat part 814 of the first stop surface 812 faces the flat part 824 of the second stop surface 822, and the inclined part 816 of the first stop surface 812 faces the second stop surface 822. It can face the inclined portion 826 of 822. When the discharge column 40 and the upper discharge column 50 are arranged in a straight line, the flat portion 814 of the first stop surface 812 and the flat portion 824 of the second stop surface 822 are in contact with each other. there is.

When the upper discharge column 50 is rotated to the maximum with respect to the discharge column 40, the inclined portion 816 of the first stop surface 812 and the inclined portion 826 of the second stop surface 822 are in contact with each other (see Figure 24).

As clearly shown in FIG. 29, second connection holes 827 are formed to penetrate the water joint 820 on both sides. The second connection hole 827 may be formed at a position corresponding to the first connection hole 817. The second connection hole 827 may be formed to be relatively longer in one direction than the first connection hole 817. This is to prevent the connector 830 and the water joint 820 from interfering when the upper discharge column 50 is rotated relative to the discharge column 40.

Inside the water joint 820, there may be a hook guide end 828. The hanging jaw guide end 828 is well shown in FIGS. 29 and 30. The hanging guide end 828 is a part where the hanging jaw 838 of the connector 830 is hung. A guide curved surface 828' may be formed on the hook guide end 828 to have a predetermined radius of curvature. The outer surface of the hook 838 of the connector 830 is in contact with the guide curved surface 828', and the hook 838 can be the rotation center of the upper discharge column 50.

An electrode slot 829 may be formed along the central position in the width direction of the water joint 820. The electrode slot 829 extends long in the rotation direction of the upper discharge column 50. In this embodiment, two electrode slots 829 are formed side by side. Electrical contact can be made between the first electrode 850 and the second electrode 860, which will be described below, through the electrode slot 829.

The connector 830 allows the upper discharge column 50 to be rotatably mounted with respect to the discharge column 40. The connector 830 rotatably hangs the male joint 820 when installed on the female joint 810 side. The connector body 832 may form the skeleton of the connector 830. There may be a button 834 on one side of the connector body 832. The button 834 may be exposed to the outside of the discharge column 40 through the button hole 410'.

The connector body 832 may have an elastic member support end 836. The elastic member support end 836 may be located on the opposite side of the outer surface of the button 834. The elastic member support end 836 may be configured so that one side of the elastic member 840 can be inserted and supported therein. For example, the elastic member support end 836 may be formed in a cylindrical shape, and there may be a guide pin 837 inside it that guides the elastic deformation of the elastic member 840. The guide pin 837 may be inserted into the elastic member 840.

There may be a hook 838 on the other side of the connector body 832. The hook 838 is formed on the other side of the connector body 832 at a predetermined distance from the position where the button 834 is formed. A portion of the hook 838 may have a disk shape. A guide curved surface 838' is formed on a portion of the outer surface of the hanging ledge 838. The guide curved surface 838' is a portion guided by the guide curved surface 828' of the hanging jaw guide end 828.

Two connectors 830 having this configuration can be used as a pair. The buttons 834 of each of the connectors 830 may be located within button holes 410' opened on both sides of the column body 410 of the discharge column 40. When the connector 830 is installed in the female joint 820, it receives the elastic force of the elastic member 840. The elastic force of the elastic member 840 causes the button 834 to tend to protrude out of the button hole 410'. The elastic member 840 uses a cylindrical coil spring, and one end is inserted and supported within the elastic member support end 836 of the connector 830. The other end of the elastic member 840 may be supported on the support plate 818 of the female joint 810. Accordingly, when the user presses the button 834, the connector 830 moves while compressing the elastic member 840, allowing the button 834 to move a predetermined distance inside the button hole 410'.

The elastic member 840 may provide elastic force to the connector 830. The connector 830 may be installed in the female joint 810 while being supported by the elastic member 840, and the connector 830 may be connected to the hanging jaw guide end 828 on the male joint 810 side. By hanging, the upper discharge column 50 can be maintained in a rotatably hung state on the discharge column 40. When the user presses the button 834 of the connector 830, the button 834 enters the inside of the button hole 410', and the hook 838 comes out of the hook guide 828. do. In this state, the upper discharge column 50 can be separated from the discharge column 40 side.

A first electrode 850 may be installed in the female joint 810. The first electrode 850 can be connected to the power supplied to the drying device of the present invention. The first electrode 850 has a protrusion shape and can contact the second electrode 860 inside the electrode slot 829. A second electrode 860 may be installed in the water joint 820. The second electrode 860 is configured to extend long to correspond to the shape of the electrode slot 829. The second electrode 860 may have an arch shape with a predetermined radius of curvature. The position where the first electrode 850 contacts the second electrode 860 varies depending on the degree to which the upper discharge column 50 is rotated. When the upper discharge column 50 rotates with respect to the discharge column 40, the first electrode 850 is in contact with the second electrode 860 and the contact position with the second electrode 860 is changed. It becomes different. In reality, the first electrode 850 is fixed, and the second electrode 860 can be moved while rotating with the rotation of the water joint 820.

There may be a friction pad 870 between the inner surface of the female joint 810 and the outer surface of the male joint 820. The friction pad 870 may provide friction to prevent arbitrary relative movement between the male joint 820 and the female joint 810. The friction pad 870 is fixed to the female joint 810 or male joint 820 and provides friction to the male joint 820 or female joint 810, which is the counterpart.

Hereinafter, the operation of the stand-type drying apparatus according to an embodiment of the present invention having the above-described configuration will be described in detail.

As can be seen in FIGS. 1 to 3, the stand-type drying apparatus of the present invention has a blowing unit 30 located in a housing 20 rotatably supported on a base 10, and a blower unit 30 is located in the housing 20. There is a rod-shaped discharge column 40 extending upward. Air is sprayed to the user through the discharge port 418 of the discharge column 40. As the housing 20 rotates with respect to the base 10, the discharge column 40 is rotated at a predetermined angle, thereby discharging the user's body. Drying is performed by spraying air over a predetermined range in the width direction.

That is, the discharge column 40 rotates left and right with respect to the user and sprays air in the width direction of the user's body to perform drying. The user stands in front of the discharge column 40 and performs the drying process while receiving the sprayed air. After the user stands facing the discharge column 40 and drying of the front of the body is performed, the user can turn around and dry the back of the user's body so that the back of the user's body faces the discharge column 40. . In Figures 32 (a), (b) and (c), the housing 20 is rotated (in the direction of arrow A) with respect to the base 10, and the position of the discharge column 40 is thereby moved. (Arrow B direction) is shown. Alternatively, air is shown being sprayed from the discharge port 418 of the discharge column 40 (arrow C).

At this time, the discharge port 418 formed in the discharge column 40 extends to a position corresponding to the lower part of the housing 20, so that the user's feet can be dried at the same time. In addition, when the upper discharge column 50 is located above the discharge column 40, the air sprayed from the upper discharge column 50 can dry the user's head. In particular, when the upper discharge column 50 is inclined at a predetermined angle with respect to the discharge column 40, air can be sprayed from the top of the user's head, thereby improving drying of the head.

Meanwhile, in the stand-type drying apparatus of the present invention, the housing 20 and the blowing unit 30 are on a base 10 seated on the floor, and the discharge column 40 extending from the housing 20 is relatively small. It extends upward in the shape of a rod with a diameter, so that the overall center of gravity of the device can be located adjacent to the base 10. Therefore, the stand-type drying device of the present invention can be stably placed on the floor, and its overall weight is light, so the user can easily move it and perform drying at a desired location. Although not shown in the drawing, if there is a handle on one side of the base 10 or a handle connected to the base 10 and the housing 20 at the same time, the stand-type drying device of the present invention can be more easily moved. You can do it.

For example, after performing basic drying with a stand-type drying device in a shower room, the stand-type drying device can be moved to perform more detailed drying in a living room, etc. For example, the head can be dried by tilting the upper discharge column 50 while sitting on a chair, and the feet can be dried through the discharge port 418 corresponding to the lower air passage 432. It can be performed with the air coming out.

The flow of air in the stand-type drying apparatus of the present invention will be described with reference to FIG. 33. When the user turns on the drying device, the blowing unit 30 is driven. The motor 312 of the blowing unit 30 operates to rotate the fan 314 to create an airflow flowing within the fan duct 310. As a result, external air is sucked in through the intake port 222. Air around the base 10 is sucked into the intake port 222, and the connecting curved surface 124 can serve to allow air to flow more smoothly into the intake port 222.

The air sucked through the intake port 222 enters the inside of the fan duct 310, passes through the fan duct 310 by driving the fan 314, and enters the guide passage inside the air guide 320. Go to (326). Air flows into the air duct 420 of the discharge column 40 through the connection pipe 434 connected to the duct connection part 324, which is the outlet of the guide passage 326.

When air enters the air duct 420 through the connection pipe 434, the flowing air is divided by the separation guide 430. Some of the air flows into the lower part of the air passage 432 by the separation guide 430, and the remaining air flows into the air passage 422 of the air duct 420 on the upper side of the discharge column 40. do.

The air duct 420 has a flow cross-sectional area that narrows starting from the separation guide 430 and moving away from the separation guide 430. Accordingly, a uniform amount of air can be discharged from the entire section of the discharge port 418.

Meanwhile, in the process of the air flowing inside the air passage 422 exiting the passage discharge port 424 of the air duct 420 and entering the discharge port 418, the air around the air duct 420 is They can be combined by the Wanda effect and discharged through the discharge port 418. Through this operation, air around the discharge column 40 can be sucked in through the column suction port 414 in the column body 410 and sucked into the column internal space 412. In Figure 34, such air flow is indicated by arrows. The air sucked into the column inner space 412 is combined with the air flowing from the flow path outlet 424 to the outlet 418 and is sprayed through the outlet 418 and delivered to the user.

In the air flow shown in FIG. 34, when air is discharged from the discharge port 418 of the column body 410, the air around the discharge port 418 may be combined according to Bernoulli's principle. However, this air is not purified, so if the spray nozzle 440 is used as shown in FIG. 35, mixing of the air around the discharge column 40 can be prevented, and the air sprayed by the spray nozzle 440 can be prevented. can be sent farther.

Air can also be sprayed through the upper discharge column 50 to dry the user's body, face, head, etc. In the embodiment shown in FIG. 3, the air discharged from the upper discharge column 50 is sucked in from the outside by the upper blowing unit 530 and delivered to the upper air passage 522 of the upper air duct 520. . As the upper air duct 520 moves away from the upper blowing unit 530, the cross-sectional flow area of the upper air passage 522 becomes narrower. Accordingly, the air discharged through the discharge port 518 of the upper discharge column 50 can be uniform throughout the entire section of the discharge port 528 of the upper discharge column 50. The air discharged through the discharge port 518 is the air sucked by the upper blowing unit 530 and the air around the upper discharge column 50 sucked through the upper column suction port 514.

The installation angle of the upper discharge column 50 can be adjusted with respect to the discharge column 40. That is, when a user stands in front of the discharge column 40, the upper discharge column 50 may be operated to tilt toward the user. The operation of the upper discharge column 50 may be performed in a predetermined direction with respect to the discharge column 40. That is, the operating direction of the upper discharge column 50 is determined by the first stop surface 612 and the second stop surface 622 of the joint mechanism 60.

Rotation in the direction in which the flat parts 614 and 624 come into contact with each other occurs only until the flat parts 614 and 624 come into contact with each other. Rotation in that direction can no longer occur. When the flat portions 614 and 624 are in contact with each other, as can be seen in FIG. 17, the inclined portion 616 of the first stop surface 612 and the inclined portion 626 of the second stop surface 622 are separated from each other. In this state, the discharge column 40 and the upper discharge column 50 are arranged in a straight line.

When the upper discharge column 50 is rotated to be inclined with respect to the discharge column 40, the flat portions 614 and 624 become distant and the inclined portions 616 and 626 become closer. When the upper discharge column 50 is rotated to its maximum inclination, the inclined portions 616 and 626 come into contact with each other. This state can be seen in Figure 16.

Meanwhile, in the embodiment shown in Figure 16 or Figure 17, the upper discharge column 50 may be separated from the discharge column 40. This can be achieved by the male joint 610 being removed from the female joint 610. In this case, the upper discharge column 50 can be separated from the discharge column 40 and used by the user by holding it by hand. At this time, air may be sprayed from the upper discharge column 50 by driving the upper blowing unit 530. The power source for driving the upper blowing unit 530 may be provided by a battery (not shown) located in the upper discharge column 50, and the battery may be charged using an electrode located in the joint mechanism 60. Power may be supplied by (not shown) (refer to electrodes 850 and 860 shown in FIG. 26).

In the embodiments shown in FIGS. 19 to 23, the air discharged from the discharge port 518 of the upper discharge column 50 is adjusted according to the angle at which the upper discharge column 50 is inclined with respect to the discharge column 40. The amount can be adjusted. As shown in FIG. 19, when the upper discharge column 50 is erected in a straight line with the discharge column 40, the connection duct 730 is connected by the edges of the first through hole 718 and the second through hole 728. As it is pressed, the flow cross-sectional area of the connection passage 734 at the corresponding position is reduced, so air may not flow. In this case, air is not discharged through the upper discharge column (50). However, when the upper discharge column 50 is rotated at a predetermined inclination with respect to the discharge column 40, the flow cross-sectional area of the connection passage 734 increases and air can flow. In Figure 23, there is a state in which the flow cross-sectional area is recovered because the connection passage 734 is not pressed. In this way, a relatively large amount of air can be sprayed through the discharge port 518 of the upper discharge column 50.

Next, the operation of the embodiment shown in FIG. 31 from FIG. 24 will be described. In this embodiment, the flow of air through the discharge column 40 is the same as in the previously described embodiment. However, the upper discharge column 50 does not receive air from the discharge column 40 side. The upper discharge column 50 can discharge air by driving the upper blowing unit 530 therein.

Additionally, the upper discharge column 50 can be more firmly mounted on the discharge column 40. This is because the connector 830 is used. The connector 830 is supported and installed on the column body 410 of the discharge column 40 by an elastic member 840, so that the upper discharge column 40 can be more easily attached to and detached from the discharge column 40. and the installed state can be maintained firmly. Also, when the upper discharge column 50 rotates with respect to the discharge column 40, it can rotate around the hook 838 of the connector 830.

Figure 36 shows a state in which the upper discharge column 50 is mounted on the discharge column 40. In this state, in order to separate the upper discharge column 50 from the discharge column 40, the user presses the button 834 in the direction of arrow A. Accordingly, the connectors 830 each move in the direction of arrow A. Due to this movement, the hook 838 of the connector 830 also moves in the direction of arrow B and deviates from the hook guide end 828 of the water joint 820. In this way, the upper discharge column 50 can be moved in the direction of arrow C and removed from the discharge column 40.

When the upper discharge column 50 is pulled out from the discharge column 40, the connector 830 moves to its original position by the restoring force of the elastic member 840. In this state, in order for the user to couple the upper discharge column 50 to the discharge column 40 again, the male joint 820 can be inserted into the female joint 810. That is, when the upper discharge column 50 is moved in the direction opposite to arrow C in FIG. 36, the hook guide end 828 is guided to the inclined surface of the top of the hook 838 of the connector 830, and the elastic member While elastically deforming (840), the connector (830) is moved in the direction of arrow A.

When the guide curved surface 838' of the hanging jaw 838 is seated on the guiding curved surface 828' of the hanging jaw guide end 828, the connector 830 moves as an arrow due to the restoring force of the elastic member 840. It moves in the opposite direction to A and returns to its original state. In this case, the upper discharge column 50 is mounted on the discharge column 40.

In this embodiment, when the upper discharge column 50 is mounted on the discharge column 40, the first electrode 850 and the second electrode 860 come into contact. Therefore, when the power is connected, it can be supplied to the upper blowing unit 530 in the upper discharge column 50, and the battery can be charged.

In the above, even though all the components constituting the embodiment according to the present invention have been described as being combined or operated in combination, the present invention is not necessarily limited to this embodiment. That is, as long as it is within the scope of the purpose of the present invention, all of the components may be operated by selectively combining one or more of them. In addition, terms such as “include,” “comprise,” or “have” described above mean that the corresponding component may be present, unless specifically stated to the contrary, and therefore do not exclude other components. Rather, it should be interpreted as being able to include other components. All terms, including technical or scientific terms, unless otherwise defined, have the same meaning as generally understood by a person of ordinary skill in the technical field to which the present invention pertains. Commonly used terms, such as terms defined in a dictionary, should be interpreted as consistent with the contextual meaning of the related technology, and should not be interpreted in an idealized or overly formal sense unless explicitly defined in the present invention.

For reference, in the illustrated embodiment, the female joints 610, 710, and 810 are located on the discharge column 40 side, and the male joints 620, 720, and 820 are located on the upper discharge column 50 side. However, the female joints (610, 710, 810) may be located on the upper discharge column (50) side, and the male joints (620, 720, 820) may be located on the discharge column (40) side.

10: base
110: Base body 112: Rotation center
114: top plate 116: side wall
118: Stepped portion 120: Driving window
122: Drive source space
20: housing
210: Housing body 212: End plate
214: side wall 216: internal space
218: Column installation part 219: Rotation center hole
220: support wall 222: intake port
224: partition wall 226: driven gear
30: Blowing unit
310: fan duct 312: motor
314: fan 320: air guide
322: fan motor connection 324: duct connection
326: Guide Euro
40: Discharge column
410: Column body 412: Column internal space
414: Column inlet 416: Filter
418: discharge port 420: air duct
422: air flow path 424: flow path outlet
426: leading end 428: rear end
430: Separation guide 432: Lower air channel
440: injection nozzle 442: injection passage
444: Expansion part
50: Upper discharge column
510: Upper column body 512: Upper column internal space
514: Upper column inlet 516: Filter
518: upper column discharge port 520: upper air duct
522: upper air flow path 524: flow path outlet
530: Upper blowing unit
60: Joint mechanism
610: female joint 612: first stop surface
614: flat part 616: inclined part
620: water joint 622: second stop surface
624: flat part 626: inclined part
70: Joint mechanism
710: female joint 712: first stop surface
714: flat part 716: inclined part
718: First through hole 720: Water joint
722: Second stop surface 724: Flat part
726: slope 728: second through hole
730: Connecting duct 732: Connecting duct body
734: Connection passage 736: Air duct connection part
738: Upper air duct connection
80: Joint mechanism
810: female joint 812: first stop surface
814: flat part 816: inclined part
817: First connection hole 818: Support plate
820: water joint 822: second stop surface
824: flat part 826: inclined part
827: Second connection hole 828: Hanging jaw guide
828': Guide surface 829: Electrode slot
830: Connector 832: Connector body
834: Button 836: Elastic member support
837: Guide pin 838: Hook chin
838': Guide surface 840: Elastic member
850: first electrode 860: second electrode
870: Friction pad

Claims (21)

A base that sits on the floor,
a housing located on the base and having an inlet;
a blowing unit located within the housing to suck air and flow it through the intake port;
A discharge column that is installed in the housing and extends upward to have a discharge port extending longitudinally on the front to discharge air,
A stand-type drying device including an upper discharge column that is detachably installed on the discharge column and discharges air by generating air flow by an upper blowing unit installed therein.
The method of claim 1, wherein the upper discharge column includes an upper column main body having an upper column internal space formed therein and an upper column discharge port in the longitudinal direction on the front, and is installed in the upper column internal space and connected to the upper blowing unit. A stand-type drying apparatus including an upper air duct in which the airflow formed by the flow flows along an upper air flow path formed therein and a flow path discharge port is formed at a position corresponding to the upper column discharge port.
The method of claim 2, wherein an upper column suction port is formed on the opposite side of the upper column discharge port in the upper column body, and air that exits the flow path discharge port and joins the air delivered to the upper column discharge port is sucked in. Stand type drying device.
The stand-type drying apparatus according to claim 3, wherein a filter is installed at the upper column inlet.
The stand-type drying apparatus according to claim 2, wherein the flow cross-sectional area of the upper air passage becomes narrower as the distance from the upper blowing unit increases.
The method of claim 1, wherein the discharge column has a column body having a longitudinally long discharge port on the front, a flow path discharge port installed inside the column body to deliver air to the discharge port, and blowing air from the blowing unit. A stand-type drying device that includes a receiving air duct.
The stand-type drying apparatus according to claim 6, wherein the flow cross-sectional area of the air passage inside the air duct becomes narrower as the distance from the blowing unit increases.
The method of claim 6, wherein both sides of the air duct are inclined toward the flow path outlet, so that the front end of the cross section of the air duct is sharp, and the rear end of the cross section of the air duct is curved, and the flow cross-sectional area increases as the distance from the blowing unit increases. This narrow stand-type drying device.
The stand-type drying apparatus according to claim 6, wherein the column body further has a column suction port through which air around the discharge column is sucked, on the opposite side of the discharge port.
The stand-type drying device according to claim 9, wherein the column inlet is provided with a filter that filters out foreign substances in the air passing through.
The method of claim 1, wherein a first stop surface and a second stop surface are formed on the column body of the discharge column and the upper column body of the upper discharge column to set a range in which the upper discharge column rotates with respect to the discharge column. Stand type drying device.
The method of claim 11, wherein the first stop surface includes a flat portion at an end of the column body perpendicular to the longitudinal direction of the column body and a predetermined inclined inclined portion in the longitudinal direction of the column body, and the second stop surface It includes a flat part orthogonal to the longitudinal direction of the upper column body at the end of the upper column body and a predetermined inclined inclined part in the longitudinal direction of the upper column body, and the flat parts are in contact with each other and the inclined parts are in contact with each other. A stand-type drying device in which the upper discharge column operates while in contact with each other.
A base that sits on the floor,
a housing located on the base and having an inlet;
a blowing unit located within the housing to suck air and flow it through the intake port;
A discharge column installed in the housing, extending upward, and having a discharge port extending longitudinally on the front to discharge air,
an upper discharge column that is detachably installed in the discharge column and discharges air by generating air flow by an upper blowing unit installed therein;
A stand-type drying device including a joint mechanism that connects the discharge column and the upper discharge column in a relatively rotatable and detachable manner.
The stand-type drying apparatus according to claim 13, wherein the joint mechanism includes a groove-shaped female joint and a hemispherical water joint provided at corresponding positions of the discharge column and the upper discharge column.
The method of claim 14, wherein a first connection hole is formed through the female joint, and a second connection hole is formed through the male joint at a position corresponding to the first connection hole, and the first and second connection holes are formed through the female joint. A stand-type drying device where the connector installed on the female joint through the connector hole is hung on the water joint.
The method of claim 15, wherein the connector includes a connector body, a button provided on one side of the connector body and exposed to one side of the discharge column, and a button provided on the other side of the connector body and hung on one side of the water joint and connected to the upper part. A stand-type drying device that includes a hanging ledge that serves as the rotation center of the discharge column.
The stand-type drying apparatus according to claim 16, wherein the button of the connector is supported by an elastic member on one side supported by the female joint.
The stand-type drying apparatus according to claim 16, wherein a portion of the outer surface of the hanging ledge has a guide curved surface, and a guide curved surface through which the guide curved surface of the hanging ledge is guided is formed at a hanging guide end formed on one inner side of the water joint.
The stand-type drying apparatus according to claim 14, wherein a friction pad is provided between the inner surface of the female joint and the outer surface of the male joint to provide frictional force during relative rotation between the female joint and the male joint.
The stand-type drying apparatus according to claim 14, wherein a first electrode is installed in the female joint, and a second electrode electrically connected to the first electrode is positioned in the electrode slot formed in the male joint.
The method of claim 20, wherein the electrode slot is formed to extend long from the water joint to position the second electrode in an arch shape, and the first electrode has a protrusion shape that contacts the second electrode while moving relative to the second electrode. A stand-type drying device.

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