KR20150134158A - drinking water supplying device - Google Patents

Abstract

The present invention relates to a drinking water supply device and, more specifically, to a drinking water supply device with improved user convenience. According to an embodiment of the present invention, the drinking water supply device includes: a cabinet; a dispenser installed in front of the cabinet and having a space from which the water is discharged; a rotation member installed in the cabinet to be able to rotate from side to side; an expansion cock unit expanded from the rotation member and integrally installed with the rotation member to rotate from side to side; a hinge installed in the expansion cock unit such that the expansion cock unit relatively rotates up and down on the rotation member; and a deflection prevention unit allowing vertical rotation of the expansion cock unit when torque in a predetermined level or in a higher level is applied.

Description

[0001] DRINKING WATER SUPPLY DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drinking water supply apparatus, and more particularly, to a drinking water supply apparatus with improved user convenience.

The drinking water supply device is a device for supplying drinking water to be consumed by a user. This drinking water supply device may be a unique device, or it may be a part of another device.

For example, the water purifier is a device that supplies purified water to the user by filtering the raw water introduced from a water supply such as a water supply or an underground water source, that is, raw water introduced from the outside. In addition, a device for heating or cooling purified water and supplying it to cold water or hot water may also be referred to as a water purifier. The water purifier may be a device independent of other appliances.

On the other hand, such a drinking water supply device may form part of a household appliance such as a refrigerator. That is, water purified from the inside of the refrigerator through the water purification device can be supplied to the outside through the drinking water supply device. Of course, water purified in the refrigerator may be cooled or frozen so that cold water or ice may be supplied to the outside through the drinking water supply device.

In addition, the drinking water supply device may be a device that supplies the purified water itself, excluding the filter that generates the purified water. In the case of a common cold / hot water heater, purified water is supplied to the cold / hot water heater, and the purified water is supplied to the user after being heated or cooled. Therefore, such a cold / hot water machine is also an example of a drinking water supply device.

Of course, even in the case of a device such as a refrigerator, purified water may be supplied from the outside, and the purified water may be cooled or converted to ice to be provided to the user. Therefore, the refrigerator in this case is also an example of the drinking water supply device.

Accordingly, the drinking water supply device may be a device provided for the user to receive the drinking water from the outside regardless of whether or not it is independent of other devices. In other words, it is a device having a dispenser that is a space for receiving drinking water.

Fig. 1 shows an example of a conventional water purifier. Hereinafter, a conventional water purifier will be described with reference to Fig.

The water purifier 10 includes a cabinet 11 and a dispenser 12 which form an external shape. Here, the dispenser 12 means a space where a user is supplied with drinking water. Therefore, generally, the dispenser 12 is formed in front of the cabinet 11. Of course, such a dispenser 12 can be formed in the form of a recessed or recessed space in front of the cabinet 11. In some cases, it may be formed in a protruding shape in front of the cabinet 110. Therefore, a part of the cabinet 11 can form the dispenser 12.

The dispenser 12 is provided with a cock 15 through which drinking water is discharged, and a lever 16 for operating drinking water may be provided. That is, when the user operates the lever 16, the drinking water can be discharged from the cock 15. Here, the operation of the lever 16 may be in the form of pushing or pulling the lever. Of course, the lever 16 may be replaced with a button pressed by the user.

Specifically, the user lifts the cup 1 so that the upper portion of the cup 1 is positioned below the cock 15, and the cup 1 can be pushed while the cup 1 is in contact with the lever 16. According to the operation of the lever 16, the drinking water can be discharged from the cock 15 and stored in the cup 1.

The user can drink the water stored in the cup 1 and throw the remaining water into the tray 13. [ Of course, a small amount of residue falling from the cock 15 can also be stored in the tray 13. [ Therefore, generally, the tray 13 is positioned directly below the cock 15. That is, below the dispenser 12. Accordingly, the space between the upper portion of the tray 13 and the cock 15 may be referred to as a dispenser 12.

As described above, the drinking water may be either purified water, cold water or hot water. Of course, it may be various forms of beverage. Accordingly, a user interface 14 for selecting the drinking water to be discharged can be provided.

For example, the user may select cold water through the user interface 14. [ Then, after the cup 1 is positioned below the cock 15, the lever 16 can be pushed. By this operation, the cold water is discharged from the cock 15 and the cup 1 is filled.

As described above, the general drinking water supply device is provided such that drinking water is supplied by a user's operation such as the operation of the lever 16. [ That is, it can be widely used for the purpose of supplying a small amount of drinking water to a container such as the cup 1.

However, there is a problem in that it is inconvenient for a general drinking water supply apparatus to directly supply drinking water to a water bottle or a cookware having various shapes and sizes. This is because the position of the cock 12 is fixed and the expansion of the space of the dispenser 12 is substantially difficult.

For example, when a cooking utensil such as a pot is supplied with a large amount of purified water, the user must take the inconvenience of operating the lever 16 by directly holding the pot. It would be obvious that it would be very uncomfortable to receive a pot of water if both the weight of the utensil and the weight of a large number of integers were to be weighed.

Of course, the purified water may be supplied to the container such as the cup 1, and the operation of emptying the container into the cooking device may be repeated several times to fill a large amount of purified water into the cooking device or the like. However, this is also very uncomfortable.

This inconvenience is more likely to occur more frequently in the case of household water purifiers. This is because, in many cases, water is used for cooking or cooking in the home, and a cooking device such as a relatively large pot is filled with water.

The present invention basically aims at solving the problem of a conventional drinking water supply apparatus.

Through the embodiments of the present invention, it is intended to provide a drinking water supply device which can elastically and easily supply purified water to containers having various sizes and shapes.

It is an object of the present invention to provide a drinking water supply device capable of expanding a dispenser space.

It is an object of the present invention to provide a drinking water supply device which can change an outgoing position and is convenient to use.

It is possible to provide an extension cork capable of varying an outgoing position together with an outflow lever and an outflow button, and an outflow button for an extension coke through a conventional coke structure, a drinking water Supply device.

Through the embodiments of the present invention, it is intended to provide a drinking water supply device which can take out a large amount of water and is convenient to use.

It is an object of the present invention to provide a drinking water supply device capable of stably supplying a large positive integer through an extension cock portion capable of vertically varying an outgoing position.

It is an object of the present invention to provide a water purifier having an extension cork portion that can minimize interference with the outside during normal use or non-use, and allows the user to easily change the outgoing position. Further, it is desirable to provide a water purifier having an extension cork portion which can protrude as far as the front of the cabinet at the time of use and is convenient to use. That is, it is desirable to provide a drinking water supply device that can effectively use the space in front of the dispenser when the extension cock portion is not used.

It is an object of the present invention to provide a drinking water supply device capable of preventing an excessive rotation angle of the extension cork portion from becoming excessively large and preventing the extension cork portion from being damaged when an excessive force is applied to the extension cork portion.

It is an object of the present invention to provide a drinking water supply device capable of preventing sudden upward and downward rotation of the extension cork portion and preventing extension cork portion from being sagged.

An object of the present invention is to provide a drinking water supply device capable of preventing sagging due to its own weight at a specific position of an extended cock portion and maintaining the specific position.

It is an object of the present invention to provide a drinking water supply device which is capable of being rotated left and right and up and down by means of a simple structure and configuration and which can be easily manufactured and reduced in production cost.

It is an object of the present invention to provide a drinking water supply device having a channel configuration that improves reliability to an extension cock that is easy to assemble and has a variable position.

To achieve the above object, according to an embodiment of the present invention, there is provided a cabinet comprising: a cabinet; A dispenser provided in front of the cabinet to form a space in which water is to be dispensed; A rotatable member provided to the cabinet so as to be rotatable in the left and right direction; An extension cork portion extending from the rotation member and configured to rotate left and right integrally with the rotation member; And a hinge provided on the extension cock portion so that the extension cork portion is rotated up and down relative to the rotation member.

The drinking water supply device may include a sag preventing part provided to allow the extension cork part to rotate up and down when a predetermined torque is applied.

The extension cork portion will sag downward due to its own weight. Therefore, the slack prevention part should be supported so that the extension cork part does not rotate up and down regardless of the person. That is, when the torque greater than the torque generated by the self weight is applied, the extension cork portion is preferably rotated up and down. In other words, it is preferable that the slack preventing portion is provided so that the extension cork portion rotates up and down when a predetermined torque greater than a torque generated by its own weight is applied.

However, the force applied by the user to the extended cork portion in order to generate the predetermined torque varies depending on the rotational direction.

The user may apply a force downwardly of the extension cork portion to rotate the extension cork portion downward. That is, the self weight of the extension cork portion and the direction of the force applied by the user are the same. Therefore, the magnitude of the force applied by the user to generate the torque of the same magnitude becomes relatively small.

Conversely, a force can be applied upwardly of the extension cork portion to rotate the extension cork portion upward. That is, the self weight of the extension cork portion and the direction of the force applied by the user are opposite. Therefore, the magnitude of the force applied by the user in order to generate the torque of the same size should be larger than the self weight of the extended cock portion. In this case, the magnitude of the force applied by the user becomes relatively large.

As a result, the magnitude of the user's force required to rotate in accordance with the rotation direction of the extension cork portion varies, but the magnitude of the torque required for rotation is the same regardless of the rotation direction of the extension cork portion.

The drinking water supply device may include a filter for purifying raw water. One example of such a drinking water supply device is a water purifier.

A through hole is formed in the rotating member, and the extending cork portion can extend from the inside of the rotating member to the outside through the through hole. Through this extended cork portion, a continuous flow path can be formed from the interior of the cabinet or from the inside of the rotary member to the extended cork portion.

The extension cork portion includes a cork handle; An extension cock provided at one side of the cock handle to perform water outflow; And a connecting portion connected to the rotating member on the other side of the cork handle.

The connecting portion may include a connecting passage for communicating with the extending cock.

The cock handle may include an outflow button operable to allow outflow through the cooking cock, and the connection portion may include a wire passage portion to which a wire connected to the outflow button is fixed outside the connection portion flow passage. Therefore, the wire can be stably fixed through the wire passing portion.

One end of the connecting portion is inserted into the cork handle to be connected to the cork handle, and the connecting portion is formed with the cork handle so as to prevent the twisting between the cork handle and the connecting portion. That is, even if the user grips the cork handle and twists the cork handle with respect to the longitudinal axis of the cork handle, the cork handle and the mold part of the connecting part are engaged with each other, so that the connection of both can be firmly maintained.

Preferably, the hinge is formed in the connecting portion, and a hinge seating portion in which the hinge is rotatably seated is formed in the rotating member.

The hinge may be a vertical center of rotation of the coke extended portion. That is, it can be called a vertical axis. Therefore, the predetermined torque may be based on the rotation axis.

And a fixing member for fixing at least one of the hinge and the deflection preventing portion to the rotary member within the rotary member. For example, the fixing member may be provided to simultaneously fix the hinge and the sag prevention unit.

Preferably, the extension cork portion, the rotary member, the hinge, the sag prevention portion, and the fixing member are integrally rotated left and right.

The deflection preventing portion includes: a gear formed on the connecting portion; And a rotation damper which is engaged with the gear to rotate when a predetermined torque or more is applied. That is, when the rotary damper rotates, the connecting portion can be rotated up and down around the hinge through the gear.

Of course, it can be said that the torque is generated by the sum of the self weight of the extension cork portion and the force applied by the user or the force that the user overcomes the self weight. In other words, in any case (irrespective of the rotational direction) or only by the self-weight of the extension cork portion, the extension cork portion does not rotate up and down. If the user applies a predetermined force to the extension cork portion, .

And a damper seating portion on which the rotary damper is seated is formed in the rotary member.

And an internal flow path of a flexible material for extending the inside of the cabinet to communicate with the connection portion inside the rotary member and allowing the connection portion to rotate up and down and left and right. Accordingly, the shape and position of the internal flow path can be varied substantially in the vertical rotation and the left-right rotation of the extended cock portion, and the overall flow path can be smoothly formed due to the characteristics of the material.

And a main cock which is separately provided from the extended cock portion and is provided so that at least the front and rear spacing distances are fixed with respect to the cabinet and the outgoing is performed.

And a rotary member fixing part for supporting the rotary member such that the rotary member is rotatable with respect to the cabinet. The rotary member fixing portion is configured to be fixed to the cabinet, and the rotary member may be configured to be rotatable with respect to the rotary member fixing portion.

The rotating member fixing portion may include a lower fixing portion that supports the rotating member at a lower portion of the rotating member and fixes the main cock to the cabinet.

The rotating member fixing unit may include an upper fixing unit that supports the rotating member at an upper portion of the rotating member and covers the upper portion of the rotating member.

And a user interface located on the upper fixing part may be provided. And an LED (light emitting diode) provided in the upper fixing part and inserted into the user interface. Therefore, the upper fixing part may be provided to support the rotary knob at the lower part of the user interface, especially the rotary knob. In addition, the LED may flow into the rotary knob from the rear of the rotary knob, and the light from the LED may be exposed to the outside in front of the rotary knob.

To achieve the above object, according to an embodiment of the present invention, there is provided a cabinet comprising: a cabinet; A dispenser provided in front of the cabinet to form a space in which water is to be dispensed; A rotary member having a through hole formed therein and rotatable in the cabinet; An extension cock extending from the inside to the outside through the through hole and configured to rotate left and right integrally with the rotary member; A hinge provided on the extension cork portion so that the extension cork portion is vertically rotated relative to the rotary member; And an angle restricting portion provided in the through hole to limit a maximum rotation angle of the extension cork portion in the up and down direction.

And an inner flow path of a flexible material extending in the cabinet to communicate with the extension cork portion inside the rotary member and allowing the extension cork portion to rotate up and down and left and right.

The drinking water supply device may include a sag preventing part which is provided to allow the extension cork part to rotate up and down when a predetermined torque is applied and to provide a damping force to prevent the extension cork part from swinging up and down.

Wherein the extension cork portion comprises: a cork handle adapted to urge the user in contact; An extension cock provided at one side of the cock handle to perform water outflow; And a connecting portion connected to the rotating member at the other side of the cork handle and having the hinge formed therein.

The coke handle comprises a coke handle housing; An outflow button provided on the cock handle housing; And a cork handle channel connected to the extension cock within the cock handle housing.

Wherein the connecting portion includes a rear portion that further extends rearward from the hinge, and the angle restricting portion includes an upper angle limiting surface that is in contact with an upper surface of the rear portion when the rear portion is rotated so as to maximally rise, And a lower angle restricting surface to be in contact with a lower surface of the rear portion when the lower surface is restrained.

Therefore, it is possible to make surface contact of the connecting portion through the angle restricting portion, so that the rotation angle can be more stably restricted.

And a rotation damper including a gear formed at a distal end of the rear portion and adapted to be rotated when a predetermined torque or more is applied to the gear within the rotation member.

And a fixing member for fixing the rotary damper within the rotary member, and the upper angle limiting surface may be formed on the fixing member.

The lower angle limiting surface may extend from the through hole to the inside of the rotary member. Of course, at least one of the upper angle limiting surface and the lower angle limiting surface may be formed to extend into the rotating member.

Wherein the through hole has a predetermined vertical length and the vertical length is longer than the left and right lengths so that the contact between the cork handle and the upper and lower sides of the through hole is excluded when the cork handle is rotated to the maximum and the lowest, It is preferable that it is formed as a long slot. Therefore, it is possible to prevent the cork handle or the connecting portion from coming into contact with the through-hole, thereby preventing damage to the cork handle or the connecting portion and preventing damage to the through-hole.

To achieve the above object, according to an embodiment of the present invention, there is provided a cabinet comprising: a cabinet; A dispenser provided in front of the cabinet to form a space in which water is to be dispensed; A rotary member having a through hole formed therein and rotatable in the cabinet; A cork handle provided to extend out of the through hole and to be rotated leftward and rightward in unison with the rotary member by a user's operation, An inner passage extending from the inside of the cabinet to the inside of the rotary member; And a connection portion having a connection portion for connecting the extension cock to the internal flow path and a rotation portion for rotating up and down by a user's operation.

A cock handle channel is provided in the cock handle, and the extension cock and the connection channel can be connected through the cock handle channel.

The cock handle may include an outflow button operable to allow outflow through the cooking cock, and the connection portion may include a wire passage portion to which a wire connected to the outflow button is fixed outside the connection portion flow passage.

It will be appreciated that the features of the above-described embodiments may be implemented in combination in other embodiments as long as they do not conflict with one another.

Through the embodiments of the present invention, it is possible to provide a drinking water supply device which can elastically and easily supply purified water to containers having various sizes and shapes.

Through the embodiments of the present invention, it is possible to provide a drinking water supply device capable of expanding the dispenser space.

According to the embodiment of the present invention, it is possible to provide a drinking water supply device which can change an outgoing position and is convenient to use.

It is possible to provide an extension cork capable of varying an outgoing position together with an outflow lever and an outflow button, and an outflow button for an extension coke through a conventional coke structure, a drinking water Supply device can be provided.

Through the embodiment of the present invention, it is possible to provide a drinking water supply device which can take out a large amount of water and is convenient to use.

It is possible to provide a drinking water supply device capable of stably supplying a large positive integer through an extension cock portion capable of vertically varying an outgoing position through the embodiment of the present invention.

It is an object of the present invention to provide a water purifier having an extension cork portion that can minimize interference with the outside during normal use or non-use, and allows the user to easily change the outgoing position. Further, it is desirable to provide a water purifier having an extension cork portion which can protrude as far as the front of the cabinet at the time of use and is convenient to use. That is, it is possible to provide a drinking water supply device which can effectively use the space in front of the dispenser when the extension cock portion is not used.

The embodiment of the present invention can provide a drinking water supply device capable of preventing an excessive rotation angle of the extension cork portion from becoming excessively large and preventing the extension cork portion from being damaged when an excessive force is applied to the extension cork portion .

According to the embodiment of the present invention, it is possible to provide a drinking water supply device capable of preventing sudden upward and downward rotation of the extension cork portion and preventing extension cork portion sagging.

It is possible to provide a drinking water supply device capable of preventing sagging due to its own weight at a specific position of the extension cork portion and maintaining the specific position through the embodiment of the present invention.

The embodiments of the present invention can provide a drinking water supply device which can be easily manufactured and reduced in production cost by allowing left and right rotation and up and down rotation of the extension cock portion through a simple structure and configuration.

The embodiment of the present invention can provide a drinking water supply device having a channel configuration that improves reliability to an extension cock that is easy to assemble and has a variable position.

1 is a perspective view of a conventional water purifier;
2 is a perspective view of a water purifier according to an embodiment of the present invention;
3 is a piping construction view showing an example of piping structure of the water purifier shown in Fig. 2;
Fig. 4 is an enlarged perspective view of the main cock and the extension cork shown in Fig. 2; Fig.
FIG. 5 is an enlarged perspective view of the connecting portion of the rotating member and the extended cork portion shown in FIG. 2; FIG.
FIG. 6 is a plan view showing a left and right rotation region of the extension cork portion shown in FIG. 2; FIG.
Figure 7 is a perspective view of the rotating member and the extended cork portion shown in Figure 2;
8 is an exploded perspective view of the extension cork portion;
9 is an exploded perspective view of the components connected to the extension cork portion;
10 is a perspective view of a rotating member;
11 is a cross-sectional view of the configurations connected to the extension cork portion;
12 is a sectional view of a connecting portion and a rotating member of the extended cork portion in a state in which the extended cork portion is maximally raised; And
13 is a cross-sectional view of a connecting portion and a rotating member of the extending cork portion in a state in which the extending cork portion is fully lowered.

Hereinafter, a drinking water supply apparatus, particularly, a water purifier according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Basically, the drinking water supply device according to the present embodiment can provide a drinking water supply device capable of generating an integer from raw water through a filter and allowing the generated purified water to flow out through a cock. However, a drinking water supply device that provides an externally supplied integer without generating an integer by itself can also be included in this embodiment.

Hereinafter, for convenience of explanation, the drinking water supply device may be referred to as a water purifier. Further, in the description of the piping structure, the rear end and the front end may refer to a downstream side and an upstream side, respectively, with respect to the forward flow direction of the fluid.

2 shows a water purifier according to an embodiment of the present invention.

As shown in the drawing, a cabinet 110 for forming an external shape of the water purifier is provided, and a dispenser 120 for performing water outflow in front of the cabinet 110 may be formed. The dispenser 120 may be formed in front of the front surface 111 of the cabinet 110. That is, a part of the front surface 111 of the cabinet 110 may form the dispenser 120.

A tray 130 may be provided under the dispenser 120. The space above the tray 130, that is, the space vertically upward from the tray 130, may be referred to as a dispenser 120. Accordingly, the tray 130 may be provided in front of the front surface 111 of the cabinet 110.

Of course, the tray 130 may be located inside the cabinet 110, in which case the dispenser 120 may also be formed within the cabinet 110. Accordingly, it is also possible that the dispenser 120 is formed to be recessed from the front of the cabinet 110 rearward.

The water purifier 100 may include a user interface 140. The user interface 140 may include a configuration for displaying a user operation and a configuration for displaying operation results. By operating this user interface 140, the outgoing mode can be selected and the selected outgoing mode can be displayed. Here, the outgoing mode may include an integer type of outgoing water, for example, hot water, cold water, and room temperature constants. Since both the hot water and the cold water are generated by heating or cooling the purified water at room temperature, they may also be constants.

For example, the user interface 140 may include a rotary knob 141. The user will be able to select the outgoing mode while rotating the rotary knob 141.

According to the present embodiment, it is possible to provide a water purifier capable of further expanding the space of the dispenser 120 in front of the water purifier 100. In addition, it is possible to provide a water purifier capable of further expanding or reducing the space of the dispenser 120 to the upper portion of the water purifier 120. In other words, it is possible to provide a water purifier that can change the outgoing position. This means that the outflow position can be further changed forward from the front face 111 of the cabinet 110, and the outflow position can be changed up and down. To this end, an extension cork 200 may be provided for further extending the space of the dispenser 120 forward of the water purifier 120 by varying the outflow position.

The extension cork portion 200 may include an extension cork 210 on which the outflow is performed. Therefore, it is possible to vary the outgoing position by varying the relative position of the extending cork 210 with respect to the cabinet 110. [ In addition, in order to vary the relative position of the extension cork 210, the relative position of the extension cork portion 200 relative to the cabinet 110 may be varied.

The position change of the extension cork part 200 can be performed through the left-right rotation. The left-right rotation may mean that the extension cork 200 is rotated with respect to an axis substantially perpendicular to the paper (hereinafter referred to as 'z' axis for convenience).

For rotating the extension cork 200 in the left-right direction, that is, in the z-axis direction, a rotary member 170 may be provided. The rotary member 170 may be provided to be rotatable in the left-right direction. In addition, the rotatable member 170 may be rotatably mounted to the cabinet 110 directly or through other configurations. For example, the rotatable member 170 is rotatable with respect to the cabinet 110, but is limited in movement or rotation in other directions. That is, the rotary member 170 may be provided to rotate about the z-axis.

The extension cork 200 may be integrally formed with the rotary member 170 so as to be rotatable in the left-right direction. In other words, the left and right rotation of the extension cork part 200 may be switched to the left and right rotation of the rotary member 170, or vice versa. Accordingly, when the user operates the extension cork unit 200 to rotate left and right, the rotation member 170 rotates left and right integrally with the extension cork unit 200.

In addition, the extension cork part 200 may extend from the rotary member 170. The extension cork 210 may be provided at a distal end along the extending direction of the extension cork 200. Thus, the extension length of the extension cork portion 200 can substantially mean the radius of rotation of the extension cork 210. [ That is, the extension cork 210 can rotate to have the same turning radius with respect to the rotating member 170.

The extension length of the extension cork part 200 or the left and right rotation radius of the extension cork 210 may refer to a front area of the dispenser 120 that can be expanded. The extension length of the extension cork part 200 is related to the left and right width of the dispenser 120 or the left and right width of the cabinet 110, thereby improving usability.

For example, the larger the extension length or the left-right rotation radius of the extension cork part 200, the more the area of the dispenser 120 can be expanded forward. In other words, it becomes possible to head out to the container located farther from the front surface 111 of the cabinet 110. The position of the extension cork portion 200 in this state can be said to be in an expanded state for the convenience of explanation. This is because the dispenser space is maximally extended forward. Further, in the extended state, the extended cork 200 may be said to extend in the forward direction of the cabinet (hereinafter referred to as 'y' axis direction for convenience of explanation).

However, the width of the dispenser 120 may be greater than the width of the dispenser 120 or the width of the cabinet 110 as the extension length or the turning radius increases. That is, the distal end of the extended cork portion 200 may be out of the width of the dispenser 120 or the cabinet 110, with the outflow position being closest to the front face 111 of the cabinet 110. The position of the extended cork part 200 in this state can be regarded as an initial state for convenience of explanation. In addition, in the initial state, the extension cork 200 may extend in the left and right direction of the cabinet (hereinafter referred to as' x 'axis direction for convenience' sake).

It is preferable that the extended cork portion 200 is longer than the front and rear width of the tray 130 so as not to deviate from the left or right end of the front surface of the dispenser 120 or the cabinet 110 . Of course, it may be off the left or right end of a certain length. However, it is more preferable that at least the extension cork 210 does not deviate from the left-right width of the tray 130 at least in the initial state of the extension cork portion 200.

As shown in FIG. 2, the water purifier according to the present embodiment may further include a main cock 150.

The main cock 150 may be the same as or similar to the general cock shown in FIG. That is, it can be a cock prepared for heading through a cup, which is a basic use form.

The position of the main cock 150 can be fixed. That is, the outflow position through the main cock 150 can be fixed. Of course, it may be provided that at least the upper and lower heading positions are variable as needed. Therefore, it is preferable that the tray 130 is formed to have a region surrounding the lower portion of the main cock 150. Accordingly, a small amount of residual water generated from the main cock 150 can be discharged to the tray 130 at all times.

(For example, to the cup) can be performed through the main cock 150 and the cooking water out (for example, to the cooking apparatus such as a pan) is performed through the extension cock 210 .

On the other hand, the outflow can be performed in a state in which the position of the extension cock 210 is located at the foremost position with respect to the cabinet 110 or in the vicinity thereof. In addition, a small amount of residual water may be generated in the extension cock 210 after heading. Accordingly, when the outflow is completed, the user can return the extension cork unit 200 to the initial state. As the extension cork 200 returns to its initial position, the extension cork 210 is positioned directly above the tray 130. Accordingly, the residual amount generated in the extension cork 210 can be discharged to the tray 130 as much as possible.

In addition, as described later, when the outflow is finished in the extended state, the user rotates the extension cork unit 200 to the initial state. At this time, the extension cork portion 200 can be rotated upward as described later. That is, the user can rotate the extension cork unit 200 to an initial state in a state in which the extension cork unit 200 is rotated upward.

Therefore, it is possible to prevent the residue generated through the extension cock 210 from being discharged from the tray 130. This makes it possible to prevent contamination of the periphery of the water purifier 100 due to residual water.

On the other hand, when both the extension cock 210 and the main cock 150 are provided, it is preferable that they are individually provided for operation for heading.

In particular, it is preferable that an outflow button 220 is provided separately from the outflow lever 155 for outgoing through the main cock 150 through the extension cock 210. The main cock 150 and the lever 155 may be the same as or similar to those shown in FIG. However, it is preferable that the extension button 220 for dispensing the extension cock 210 is separately provided in the extension cock section 200. For example, the extension cork part 200 preferably includes the outflow button 220.

The position of the main cock 150 and the position of the lever 155 may be fixed with respect to the cabinet 100. The position of the extension cock 210 and the head button 220 may be fixed to the cabinet 100, .

Here, the outflow lever 155 is positioned near the main cock 150 and the outflow button 220 is positioned near the extension cock 210. Thus, the user can intuitively grasp the relationship between them. That is, it can be intuitively grasped that the user exits from the main cock 150 by pressing the outflow lever 155, and exits from the extension cock 210 by pressing the outflow button 220, thereby preventing user confusion.

In addition, since the operating method, operation mechanism, or operation mode of the outflow lever 155 and the outflow button 220 are different, user confusion can be further prevented.

Hereinafter, an example of the piping structure of the purifier according to the above embodiment will be described in detail with reference to FIG.

3, the raw water flowing into the water purifier 100 through the external water supply source 20 can be converted into an integer via the filter 30. [ That is, the filter 30 cleans the raw water. The configuration of the filter 30 may be variously modified, and the filter 30 may be configured by a plurality of single filters. In FIG. 2, three single filters are connected in series to form the filter 30. However, the present invention is not limited thereto.

Specifically, the filter 30 may include a pre-carbon filter 31, a UF filter 32, and a post-carbon filter 33. Of course, other types of filters, such as a sediment filter, may be added in some cases.

A constant flow valve (21) may be provided between the external water supply (20) and the front end of the filter (30). The amount of raw water (flow rate) can be supplied to the filter 30 stably even if the hydraulic pressure of the external water supply source 20 is varied through the constant flow valve 21. [

The purified water generated by the raw water can be discharged to the outside through the purified water pipe 40, the purified water supply valve 42 and the main cock 150. For this outflow, the operation of the lever 155 shown in Fig. 2 is required, and the water supply valve 42 is opened due to the operation of the lever 155, so that the outflow can be performed.

Here, the purified water pipe 40 can always be opened when malfunction of the purified water supply valve 42 occurs. That is, when the malfunction of the purified water supply valve 42 occurs due to the pressure of the raw water supplied through the external water supply source 20, the purified water can be continuously flown out through the cock 150. Therefore, in order to ensure the stability of the system, it is preferable that a purified water valve 41 is provided between the rear end of the filter 30 and the front end of the purified water supply valve 42.

The water purifying valve 41 is basically opened to be able to exit through the main cock 150. However, as will be described later, the water purifying valve 41 may not always be opened for the outflow through the main cock 150. This is because cold water or hot water can be dispensed not only at the room temperature but also through the main cock 150, as described later.

As described above, the water purifier can basically be an apparatus for generating and supplying an integer. However, it may be provided to supply cold water or hot water as well as an integer for user satisfaction. Such cold water or hot water can basically be generated using the above constants. That is, the cold water or the hot water may be an integer, and may additionally be an integer which is cooled or heated.

On the other hand, the water purifier may be a device for supplying only cold water or hot water using an integer. In this case, it is possible to omit piping configurations at the downstream end of the branch point C in the purified water pipe 40. [ In other words, it is possible to omit the piping configurations at the downstream end of the branch point C including the purified water supply valve 42. Of course, in this case, the cold water pipe 50 and the hot water pipe 60 to be described later should be provided.

As shown in Fig. 3, according to the embodiment of the present invention, a water purifier capable of supplying cold water can be provided. That is, it is possible to provide a water purifier capable of generating cold water by cooling the purified water and capable of leaving the cold water.

In order to generate cold water through the purified water, a cold water pipe 50 may be provided, and the cold water pipe 50 may be connected to the purified water pipe 40.

The cold water pipe (50) may be branched from the purified water pipe (40). At this time, the cold water pipe 50 may be branched from the branch point B of the purified water pipe 40. That is, purified water bypassed from the purified water pipe 40 can be converted into cold water while flowing through the cold water pipe 50. The cold water pipe 50 may be provided up to a coke valve for discharging cold water. The coke valve may be a cold water supply valve 52 or a coke valve 151 separately provided at a rear end of the cold water supply valve 52.

The purified water bypassed from the purified water pipe 40 can be converted into cold water while passing through the cooling channel 51 in detail. Therefore, the cold water pipe 50 may include the cooling passage 51.

The cooling passage 51 may be provided inside the cold water tank 55. The chiller (not shown) is provided in the cold water tank 55 to cool the inside of the cold water tank, and the cooling passage 51 inside the chilled water tank is cooled by the chiller. Therefore, the constant in the cooling passage 51 is converted to cold water.

On the other hand, in order to prevent freezing of the cooling passage 51 due to abrupt cooling, cooling water may be provided in the cold water tank. Therefore, much of the cooling channel 51 is immersed in the cold water tank filled with the cooling water.

A cooling water pipe 80 for supplying cooling water to the inside of the cold water tank may be provided. Through the cooling water pipe 80, cold water or purified water can be supplied as cooling water to the cold water tank.

The cooling water pipe 80 may be provided with a cooling water valve 81. When cooling water is required, the cooling water valve 81 may be opened to allow the cooling water to flow into the water cooling water tank 55. In order to use the purified water as the cooling water, the cooling water pipe 80 may be branched from the purified water pipe 40. For example, at the branch point C of the purified water pipe 40, the cooling water pipe 80 may be branched. The division point C may be either the front end or the rear end of the division point B.

Meanwhile, the cold water tank 55 may be connected to a drainage passage 87 for limiting the supply of the cooling water and a drainage passage 85 for replacing the cooling water. The cooling water may be periodically drained and periodically filled. Therefore, the drainage passage 85 may be provided with a drain valve 86.

When the user presses the lever to exit the cold water, cold water is discharged from the main cock 150. For this cold water outflow, the water purification valve 41 and the cold water supply valve 52 can be opened, through which cold water is discharged. Accordingly, the cold water supply valve 52 performs a function of selectively opening and closing the cold water pipe 50.

FIG. 3 shows an embodiment in which cold water and purified water are discharged through a main cock 150, which is a single cock. To this end, a main cock valve 151 may be provided at the rear end of the purified water supply valve 42 and the cold water supply valve 52. The main cock valve 151 may be a single coke valve. In this case, the single coke valve performs two functions as an integral coke valve and a cold water coke valve.

The main cock valve 151 may be connected to the distribution pipe 90. The distribution pipe 90 may be connected to the purified water pipe 40 and the cold water pipe 50, respectively. A cold water supply valve (52) and a purified water supply valve (42) may be provided at the front end of the distribution pipe (90). A main cock valve 151 may be provided at a rear end of the distribution pipe 90.

More specifically, the distribution pipe 90 may be connected to at least one of the purified water pipe 40, the cold water pipe 50, and the hot water pipe 60. Water exiting through these pipes can be introduced into the distribution pipe 90.

Accordingly, the distribution pipe 90 may have a plurality of inlet ports and at least one outlet port, and each of the inlet port and the outlet port may be connected to the valve. To this end, the distribution line 90 may comprise a single body assembly having a plurality of inlets and at least one outlet.

Therefore, cold water or purified water can be supplied to the distribution pipe 90. When the main cock 150 is opened through the single main cock valve 151, cold water or purified water can be selectively supplied. For example, when the purified water supply valve 42 is opened and the single main cock valve 151 is opened, the purified water can be supplied through the main cock 150, which is a single cock. Further, when the cold water supply valve 52 is opened and the single main cock valve 151 is opened, cold water can be supplied through the single main cock 150.

Further, in this embodiment, it is possible to provide a water purifier capable of generating hot water using an integer and supplying hot water. A heating device 65 for generating such hot water may be provided.

As shown in FIG. 3, the hot water pipe 60 may be branched at the branch point A of the purified water pipe 40. A hot water valve 61 may be provided at the front end of the heating device 65. The hot water valve 61 may be provided to selectively supply purified water for generating hot water from the purified water pipe 40 to the heating device 65.

The purified water supplied from the purified water pipe 40 flows into the heating device 65 through the inlet of the heating device 65. Then, the water is converted into hot water through the heater 67 provided in the heating device 65. The hot water may flow into the hot water supply valve 62 through the outlet 69 of the heating device 65.

Therefore, the hot water can be taken out to the outside as the hot water supply valve 62 is opened. Of course, if a single main cock 150 is provided, the single main cock 150 may also be opened for hot water outflow.

In this embodiment, it is possible to provide a water purifier capable of selectively leaving purified water, hot water and cold water through a single main cock 150. Accordingly, the distribution pipe 90 may be provided as described above, and the distribution pipe 90 may be connected to the hot water pipe 60 as well. Therefore, any one of the purified water, hot water, and cold water flowing into the distribution pipe 90 can be discharged to the outside due to the opening of the single main cock 150 through the single main cock valve 151.

As described above, only the constants can be supplied through the purifier according to the present embodiment. In addition, a water purifier supplied with only cold water and hot water can be provided. In addition, a water purifier supplied with only cold water and purified water may be provided.

However, as shown in FIG. 3, it is most preferable to provide a water purifier capable of selectively supplying cold water, hot water, and purified water through the water purifier according to the present embodiment. This is because it can meet various user demands.

On the other hand, as described above, various forms of heading can be performed through the single main cock 150. That is, at least one of hot water, cold water and normal temperature water can be taken out through one coke. Further, depending on the temperature of the outgoing water, more various types of water may be introduced. For example, longevity constants and the like can also be made. This heading mode, i.e., heading mode, can be performed through the operation of the user interface 140 described above.

For example, the user may select the cold water mode via the user interface 140 and press the lever 155. In this case, cold water can be discharged through the main cock 150. That is, an integer of a selected type may be output through the main cock 150 according to the mode selected through the user interface 140. [

The selection of this heading mode can be equally applied to the extension cock 210 as well as the main cock 150. That is, the outbound mode is selected through the user interface 140 and the outbound button 220 is pressed, the selected integer can be extracted.

For example, the user may select the hot water mode via the user interface 140 and press the outbound button 220. In this case, hot water can be taken out through the extension cock 210. That is, an integer of a selected type may be output through the extension cork 210 according to the selected outgoing mode through the user interface 140. [

Accordingly, the outgoing mode selected through the user interface 140 can be commonly applied to the main cock 150 and the extension cock 210. [ Because of this feature, various kinds of purified water can be easily supplied to various types of containers.

For this purpose, it is preferable that at least two of the purified water supply valve 42, the cold water supply valve 52 and the hot water supply valve 62 are provided. For example, two purified water supply valves 42 may be provided, one connected to the main cock 150 and the other connected to the extension cock 210. In other words, through the main cock 150, the same structures as the outflow structures should be provided in the extension cock 210 as well.

However, in this case, the internal structure of the water purifier may become very complicated. And, there is a fear that the control of the water purifier becomes very complicated. In addition, when a large amount of water is taken out, it is often an integer of room temperature. Therefore, it is more preferable that only the purified water at room temperature is taken out through the extension cock 210.

FIG. 3 shows an example in which only constant temperatures can be supplied through the extension cock 210. Herein, the integer at room temperature is an integer generated from the raw water, and may be a constant without heating or cooling through a separate apparatus. Therefore, the purified water can be discharged to the extension cock 210 through the branched purified water pipe 40b branched from the purified water pipe 40. [ Of course, another branch purified water pipe 40a may be provided so as to enable the outflow of water through the main cock 150. Accordingly, the purified water flowing through the purified water pipe 40 can be discharged to the extension cock 210 or to the main cock 150 according to the user's selection.

As described above, it is preferable that the lever 155 for going out to the main cock 150 and the outflow button 220 for going out to the extension cock 210 are formed at different positions separately. In addition, it is desirable that the mechanism to be taken out and the amount of water to be dispensed are different from each other.

For example, it is preferable that the main cock 150 is controlled so that the lever 155 is lifted only while being pressed. For example, in the integer mode, it is possible to control the water to be discharged through the main cock 150 only while the user depresses the lever 155. This can be realized by controlling the unillustrated controller so that the purified water supply valve 42 is opened while the operation of the lever 155 is maintained.

In addition, through the extension cock 210, when the operation of the head-release button 220 is generated, it is possible to control the constant amount of water to flow out through the extension cock 210. To this end, the branch water purification pipe 40b may be provided with a flow meter, a flow rate sensor 43 and a purified water supply valve 44. The rear end of the purified water supply valve 44 may be connected to the extension cock 210. The control unit can open the purified water supply valve 44 when the operation of the water exit button 220 is performed and this opening can be maintained until the predetermined flow rate signal is received through the flow rate sensor 43. [

Specifically, the predetermined flow rate signal can be set to 1 liter. Therefore, the control unit can confirm that the 1-liter constant is supplied through the flow sensor 43 and close the purified water supply valve 44.

On the other hand, it is possible to dispense with the flow meter 43 and differentiate the outflow mechanism of the extension cock 210 from the outflow mechanism of the main cock 150. Basically, the outflow through the main cock 150 can be made for a small amount of water. Therefore, the outflow can be performed only while the lever 155 is operated. However, the outflow through the extension cock 210 is aimed at leaving a cooking vessel or a large water bottle, so that it is possible to aim at a relatively large amount of water. Accordingly, if the outbound button 220 is pressed, the outbound flow continues, and if the outbound button 220 is pressed again, the outbound flow can be controlled to stop.

Specifically, when the outflow button 220 is pressed, the control unit can open the purified water supply valve 44. When the outflow button 220 is pressed in the state in which the purified water supply valve 44 is open, the control unit can close the purified water supply valve 44. Therefore, it is possible to prevent the user from constantly operating the lever 155 and the head-release button 220. In addition, it becomes possible to actively cope with various amounts of supply to be supplied.

In the foregoing, the present embodiment has been described focusing on the embodiment of the water purifier basically including the main cock 150 and the extension cock 210. [ Of course, the main cock 150 may be omitted and the extension cock 210 may be provided to supply a plurality of kinds of integer. In this case, a plurality of types of integers may be selected through the user interface 140.

In the above description of the piping, the branch may be a branch of the pipe or the flow path itself, and may include a branch through a fitting.

Hereinafter, the extended cork portion 200 shown in FIG. 2 and its rotating structure will be described in detail with reference to FIGS. 4 to 7. FIG.

As shown in the figure, the rotary member 170 may be rotatably installed in the cabinet front 111 or the dispenser 120. The rotating member 170 may be substantially horizontally rotatable.

In addition, the cabinet front face 111 or the dispenser 120 may be provided with an extension cork portion 200 rotatable in the left and right direction. Here, the extension cork part 200 may include a cork handle 230 which can be held by a user and rotated left and right.

Accordingly, the extension cork 200 is connected to the rotary member 170 and rotated left and right through the rotary member. That is, it is preferable that the extension cork portion 200 and the rotary member 170 are integrally rotatable in the left and right direction.

Fixing portions 152 and 180 for fixing the rotary member 170 to the cabinet 110 may be provided. The rotating member 170 may be rotated left and right with respect to the cabinet 110 through the fixing portions 152 and 180. 4 shows an example in which fixing portions are provided on the upper and lower sides of the rotary member 170, respectively.

As shown in FIG. 5, the rotating member 170 is rotatably provided in the fixing portion 180. That is, rotatable about the z-axis center of the upper fixing part 180. For this purpose, a rotation guide 171 is provided on the upper part of the rotary member 170, and the fixing part 180 is provided to surround the rotation guide 171. Of course, the opposite would be possible.

As described above, the fixing portions 152 and 180 for fixing the rotary member 170 include the fixing portion 180 provided at the upper portion of the rotary member 170 and the fixing portion 152 provided at the lower portion can do. Which can be referred to as an upper fixing part 180 and a lower fixing part 152, respectively. And the connection structure of these and the rotary member 170 may be the same.

Accordingly, the rotary member 170 is rotatable about the z-axis center of the upper fixing part 180 and the lower fixing part 152.

Meanwhile, as shown in FIG. 4, the extension cork 200 may be provided on the main cock 150 so as to be laterally slidable. To this end, the extension cork 200 may extend substantially horizontally on the ground in the rotary member 170. This direction may be located on the x-y axis plane. Because the extension cork portion 200 can extend in the x-axis direction or the y-axis direction, it can be varied depending on the left and right rotation angles of the extension cork portion 200.

The position of the extension cork part 200 may be determined through a fixing part 152 provided below the rotary member 170. That is, the fixing part 152, for example, the lower fixing part 152 may be positioned below the rotary member 170 in the vertical direction (z-axis direction). Here, the lower fixing part 152 may be configured to fix the main cock 150. Therefore, the lower fixing portion 152 may be referred to as a main cock fixing portion 152. [

The main cock fixing portion 152 includes a cock passage 153 therein and the cock passage 153 communicates with the main cock 150. Therefore, the main cock securing part 152 can perform a function of fixing the main cock 150 and the cock passage 153 to the cabinet 110. [ Of course, as described above, the main cock securing portion 152 can also perform the function of rotatably supporting the rotary member 170 with respect to the cabinet.

As shown in FIG. 4, a coke passage may also be provided in the rotary member 170. This can be referred to as an internal flow path 250. The inner flow path 250 may further extend along the longitudinal direction of the extension cork portion 200. Of course, a flow path may also be formed in the extension cock portion 200, and such flow path may be connected to the internal flow path 250 within the rotation member 170. The details of the relationship between the internal flow path 250 and the extension cork portion 200 will be described later.

Accordingly, the purified water flowing from one side of the extended cork part 200 flows along the inner longitudinal direction of the extended cork part 200, and then the extended cork 210 provided on the other side of the extended cork part 200 .

As described later, the rotary member 170 and the extension cork portion 200 can be rotated to the left and right, and the extension cork portion 200 can be rotated up and down. Accordingly, when the rotation is generated, the position of the internal flow path 250 provided in the rotary member 170 can be changed. Therefore, in order to actively cope with such position change, the internal flow path 250 is preferably formed of a flexible material. That is, even if one side of the inner flow path 250 is fixed and the other side position is variable, the flexible flow can elastically accommodate the inner flow path 250.

The extension cork portion 200 may include a cork handle 230 and a connection portion 240. The connection unit 240 connects the rotating member 170 and the cork handle 230. In addition, the cock handle 230 may be extended from the connection unit 240 to be manipulated by the user.

The extended cork part 200 may be exposed or protruded forward of the cabinet 110 or the dispenser 120 through the connection part 240. More specifically, the cock handle 230 may be exposed or protruded forward of the cabinet 110 or the dispenser 120.

Therefore, the user can easily grip the cork handle 230, thereby easily rotating the extension cork 200 from side to side.

As shown in FIG. 4, the cock handle 230 is preferably provided with an outflow button 220. More specifically, the cock button 230 is preferably provided on the upper surface of the cock handle 230. This is because the outflow button 220 is always exposed to the user's field of view irrespective of the rotation position of the cock handle 230. In addition, the user can simultaneously or sequentially rotate the cock handle 230 and the outflow button 220.

As shown in FIG. 6, it is preferable that the extension cork portion 200 is rotatable in right and left directions at various angles.

For example, the extension cork portion 200 may be located at the A position. This can be regarded as the initial state of the extended cork portion as described above. In this initial state, the extension cork portion may be as close as possible to the cabinet 110 or the cabinet front surface 111 as much as possible. That is, the cock handle may be in parallel with the front surface of the cabinet. Therefore, when the extension cork portion 200 is not used or only the main cock 150 is used, interference with the outside can be minimized. However, even in this initial state, it is preferable that at least the cock handle 230 of the extended cock 200 is positioned so as to protrude forward of the cabinet 110. This is because the user can easily operate the cock handle 230.

On the other hand, the extension cork portion 200 can be moved to the B position by rotating substantially 90 degrees from the A position of the extension cork portion 200. The position B may be a position where the extension cork 210 is spaced apart from the front of the cabinet 110 as much as possible. That is, the cork handle 230 may be positioned substantially perpendicular to the front surface of the cabinet. This can be said to be the extended state of the extension cork portion as described above. Therefore, it is possible to easily go out to a container having a large radius. Of course, it is preferable to be able to go out through the extended cock portion 200 at a position between the A position and the B position.

And the B position may be the maximum rotation position of the extension cork part 200. However, it can be further rotated at the B position. That is, it is preferable that the extended cork portion 200 be rotated to the C position which is substantially 180 degrees apart from the A position. This is because when there is only rotation to the position B, there is a fear that an external force for rotating the extension cork portion in the direction from the position B to the position C is generated. The extension cork portion 200 may be damaged by such external force. Therefore, it is more preferable that the extension cork portion 200 is rotatable in the left-right direction even in the extended state.

The C position extension cork 210 may be in contact with the cabinet 110 or the cabinet front surface 111 as much as possible. Therefore, the position C may be the initial state of the extension cork portion 200.

Hereinafter, the vertical rotation structure of the extension cork portion 200 will be described in detail with reference to FIGS. 5 and 7. FIG. 7 is an oblique perspective view of an upper part of the rotary member 170. FIG.

As described above, the extension cork portion 200 is preferably rotatable in the left-right direction. In addition, it is preferable that the extension cork portion 200 is vertically rotatable. The outflow position through the extension cock 210 can be varied up and down through the vertical rotation of the extension cock 200. This makes it possible to easily cope with the height of various containers.

For this, a through hole 172 may be formed in the rotating member 170. [ The extended cork part 200 may extend outwardly from the inside of the rotary member 170 through the through hole 172. [

More specifically, the extension cork portion may extend outward through the through hole 172 through the connection portion 240 of the extension cork portion 200. That is, one side of the connecting part 240 can be fixed to be vertically movable within the rotary member 170, and the other side can be connected to the cork handle 230.

The connection unit 240 may be connected to the rotary member 170 so as to be rotatable up and down. Therefore, the connecting portion 240 or the cork handle 230 may be moved up and down in the through hole 172. The through holes 172 may be formed to be long in the vertical direction in order to avoid the vertical movement of the connecting portion 240 or the cock handle 230 and the interference between the through holes 172.

A specific portion of the connecting portion 240 or a specific portion of the cork handle 230 corresponding to the through hole 172 may be formed on the other side of the cork handle 230, It is preferable that the outer diameter is smaller than the outer diameter. This is because an increase in the vertical width of the through hole 172 means that the height of the rotary member 170 is unnecessarily increased.

As shown in FIG. 7, the connection portion 240 may be formed with a rotation shaft 260. The rotation shaft 260 may be a hinge. That is, the connecting portion 240 rotates up and down with respect to the rotating shaft 260, and as a result, the extending cork portion 200 rotates up and down. The rotation shaft 260 may be fixed inside the rotary member 170. Therefore, the connecting portion 240 can be rotated up and down with respect to the rotating shaft or the hinge 260, so that the entire extended cork 200 can be rotated up and down with respect to the rotating shaft 260.

For example, the extension cork 200 can be moved to the F state by rotating the extension cork 200 as far as possible downward from the horizontal position D with respect to the ground. In addition, it is possible to move up to the E state in the D state as much as possible.

The vertically rotatable angle of the extended cork part 200 can be determined through the vertical width of the through hole 172. For example, in the state D, the vertically rotatable angle of the extension cork part 200 may vary through a distance between the connection part 240 and the upper part of the through hole 172 and a distance between the lower part of the through hole . As the distance is increased, the distance can be further increased in a direction in which the distance is reduced.

However, since the upper and lower widths of the through holes 172 are limited, when the upward rotation limit angle is increased, the downward rotation limit angle is inevitably reduced.

Accordingly, in this embodiment, it is preferable that the position and the vertical width of the through hole 172 are determined so that the downward rotation limit angle becomes larger in consideration of the general shape of the cooking utensil.

On the other hand, as will be described later, it may be preferable that the extended cork portion 200 is prevented from being in contact with the through-hole 172 at the maximum rotation state. This is because the portion of the extension cork 200 exposed to the outside of the through hole 172 may be damaged by contact with the through hole. Of course, the through hole 172 may be damaged.

When the external force is removed through an elastic means such as a torsion spring (not shown), the extended cork 200 is preferably returned to the D state or maintained. Such an elastic means may be provided on the rotary shaft 260.

Therefore, even if the user manipulates the cork handle 230 to change the vertical position of the extension cork 210, the extension cork 210 can be returned to the D state when the user releases the cork handle 230 .

Hereinafter, the structure and the flow path structure of the extension cork 200 according to the embodiment of the present invention will be described in detail with reference to FIG. 8 is an exploded perspective view of the extension cork portion 200. Fig.

The extension cork portion 200 may include a cork handle 230, an extension cork 210, and a connection portion 240.

The cork handle 230 may include a cork handle housing 231, 232. The cork handle housing forms the outer shape of the cork handle and can function to protect the inner structure by wrapping it. Specifically, the cork handle housing includes an upper housing 231 and a lower housing 232, both of which can be coupled to each other.

The cock handle 230 may be provided with an outflow button 220. A button assembly 221 for sensing user input through the outflow button 220 may be provided in the inside of the outflow button 220, that is, inside the coke handle housings 231 and 232. The button assembly 221 may include a switch 222. The switch may be a switch that senses a separation or contact. Therefore, the button assembly 221 must be supplied with current.

A wire (not shown) connected to the outflow button 220 or the button assembly 221 needs to extend to the inside of the cock handle 230. Therefore, it is necessary to provide a structure in which such a wire can be extended and fixed. Such a structure may be formed in the connection portion 240 described later.

An extension cork 210 is provided on one side of the cork handle 230. Specifically, the extension cork 210 may be fixed to the outside through the inside of the cork handle 230.

The extension cork 210 may be connected to the coke handle channel 235 within the coke handle 230 or inside the coke handle housings 231 and 232. Accordingly, the coke handle channel 235 may be provided inside the cock handle.

The cork handle 230 may include an end cover 234 for blocking the end or for decorating the end. The end cover 234 may be coupled to the end of the cork handle 230 after the upper housing 231 and the lower housing 232 are coupled. Such a cover may be referred to as a deco cover 234.

On the other hand, in order for the drinking water to flow out from the extending cock 210, it is necessary to form a continuous flow path from the inside of the cabinet to the extending cock. A part of the flow path may be the coke handle channel 235. In addition, a part of the flow path may be an internal flow path 250 extending partly from the inside of the cabinet.

And a connection channel 241 for connecting the cock handle channel 235 and the internal channel 250 may be further provided.

One side of the connection channel 241 may be connected to the cock handle channel 235 and the other side may be connected to the internal channel 250. It is preferable that the former connection is made inside the cock handle 230 and the latter connection is made inside the rotary member 170.

This means that the extension cork part 200 is assembled first and the extension cork part 200 can be connected to the connection flow path 241 and the internal flow path 250 inside the rotary member 170. Therefore, the assembly becomes very easy.

Specifically, as shown in FIG. 8, the connecting passage 241 may be coupled to the coke handle channel 235. The coke handle channel 235 and the extension cork 210 may be combined. The upper housing 231 and the lower housing 232 are coupled to each other so that the cork handle channel 235 and the connection channel 241 can be fixed in the housings 231 and 232 while being connected to each other.

Thereafter, the assembled extension cork part 200 can be connected to the rotary member 170 or to the internal flow path 250 inside the rotary member. Therefore, the assembly becomes very easy.

Meanwhile, it is preferable that the connection channel 241 is formed in the connection part 240. The connection unit 240 may be configured to connect the extension cork unit 200 or the cork handle 230 with the rotary member 170. Accordingly, one side of the connecting part 240 may be connected to the cork handle or the cork handle housing, and the other side may be connected to the rotating member 170. Therefore, it is preferable that one side portion of the connection portion 240 is extended to the inside of the cock handle, and the other side portion is provided in the rotation member 170.

The connecting portion 240 may be configured to vertically rotate the extension cork portion 200. That is, the extension cork portion 200 and the cork handle 230 can be rotated up and down through the vertical rotation of the connection portion 240.

To this end, the connection portion 240 may include a rotation shaft or a hinge 260. The rotary shaft or hinge 260 may be rotatably fixed within the rotary member 170. That is, it can be fixed so as to be able to rotate up and down.

Accordingly, the connection unit 240 may include the rotation shaft 260 and the connection channel 241. In addition, the connection unit 240 may include a wire fixing unit or a wire passing unit 242 through which a wire is extended and fixed to the outside of the connection channel.

The wire may extend through the wire passage 242 to the button assembly 221 inside the cabinet or inside the rotary member 170. Therefore, the wire connection and fixing can be easily performed.

Meanwhile, the connection part 240 may include a structure for preventing the elongated cork part 200 from sagging or restricting the upward and downward rotation angles. These structures may be referred to as deflection preventing portions and angle restricting portions, respectively.

Hereinafter, the connection or coupling relationship between the extension cork portion 200 and other structures will be described in more detail with reference to Figs. 9 and 10. Fig. 9 is an exploded perspective view in which the other components connected to the extension cork portion 200 are separated from each other. And FIG. 10 is a perspective view of the rotating member 170 shown in FIG.

8 shows a state where the extension cork portion 200 and the internal flow path 250 are coupled or a state where the cork handle 230, the connection portion 240 and the internal flow path 250 are connected to each other, .

The extended cork portion 200 extends through the through hole 172 of the rotary member 170 and outwardly from the inside of the rotary member 170.

A hinge seating part 174 on which the hinge or the rotary shaft 160 is seated may be formed inside the rotary member 170. Accordingly, the hinge is fixed at the hinge seating part 174 and then rotated. Through the rotation, the connection part 240 can be rotated up and down.

The internal passage 250 may extend from the lower side of the rotary member 170 to the inside of the rotary member 170 and may be connected to the connection unit 240 inside the rotary member 170.

9, the inner flow path 250 is bent (rear bent portion) so as to vertically rise inside the rotary member 170, extended upward (straight line) to a predetermined height, and then vertically forward (Front bent portion). In addition, the inner flow path 250 is formed of a flexible material. Due to the shape and the material of the inner flow path 250, it is possible to flexibly cope with the left-right rotation and the up-down rotation of the connection portion 240. In other words, it is possible to prevent the inner flow path 250 from twisting or breaking rapidly.

For example, when the extension cork portion 200 rotates to the left or right, it can absorb a warp with a sufficient length in the vertical portion. That is, the left and right rotation can be handled without the flow path being largely deformed. When the extension cork part 200 rotates up and down, it can be deformed such that the bending angle at the rear bent part and / or the front bent part becomes larger. Therefore, the up-and-down rotation can be handled without the flow path being largely deformed.

In other words, it can be said that the shape and material characteristics of the inner channel can sufficiently cope with the deformation due to the up-and-down and right-and-left rotation of the extension cork portion. This eliminates the need to add a complicated flow path configuration, i.e., a configuration for preventing deformation and rotation while preventing damage to the flow path.

The connecting portion 240 may include a rear portion 270 that extends further from the hinge 260 rearward. The deflection preventing portion and the angle restricting portion described above can be realized through the rear portion 270.

A rotating damper assembly 280 may be provided inside the rotating member 170 to be engaged with a rear portion of the connecting portion 240. At least one of the rotary damper assemblies 280 may be formed, and the rotary damper assemblies 280 may be provided on both sides of the connection part.

The rotary damper assembly 280 may include a rotary damper 281 and a bracket 282 having the rotary damper 281. The rotary damper 281 may be configured to rotate only when a predetermined torque or more is applied. That is, the oil or shaft in the rotary damper 281 may be forcedly inserted so as to rotate only at a predetermined torque or higher without rotating at a torque lower than a predetermined torque.

The rotary damper 281 may be seated inside the rotary member 170 through the bracket 282.

As shown in FIG. 10, a damper seat 173 on which the rotary damper 281 is seated may be formed in the rotary member 170. That is, the rotary damper 281 can be seated on the damper seat 173 through the bracket.

The rotary damper 281 and the hinge 260 are seated on the hinge seat 174 and the damper seat 173 and fixed to the rotary member 170 through a separate fixing member 290 Can be fixed. The fixing member 290 may be provided to fix at least one of the rotary damper 281 and the hinge 260 or may be a single member for fixing both the rotary damper 281 and the hinge 260.

A screw may be inserted between the hole 292 formed in the fixing member 290 and the hole 175 formed in the rotating member. In this way, the fixing member 290 can be coupled to the rotating member. Through this coupling, the hinge (i.e., the connecting portion) and the rotary damper can be firmly coupled to the rotary member within the rotary member.

The upper fixing part 180 is coupled to the upper part of the rotating member 170 to cover the upper part of the rotating member 170. A lower fixing part 152 is coupled to the lower part of the rotating member 170 to close the lower part of the rotating member 170. The rotating member 170 can rotate left and right between the upper rotating member 180 and the lower fixing member 152.

A main cock 150 is provided so as to extend outward from the inside of the lower fixing part 152. The main cock 150 may be connected to the coke passage 153 (see FIG. 4) at the lower fixing portion 152. The main cock 150 may be formed with a channel connection part 154 to be connected to the coke channel and a hole 155 for fixing the main cock 150 to the lower fixing part 152 . The main cock 150 can be firmly fixed within the lower fixing part 152 through the hole 155 and the screw.

The lower fixing part 152 may be coupled to the cabinet by a boss 152a.

11 is a cross-sectional view of a state in which all of the structures shown in FIG. 9 are combined.

As shown, the connection 240 is coupled to the cork handle 230 with at least a portion of the cork handle 230 positioned therein. Particularly, at one side of the connection part 240, one side of the connection channel 241 may be connected to the coke handle channel 235. The cork handle housings 231 and 232 can be formed inside the coke handle channel 235 by a part of the connecting channel 241 for a solid connection of both.

The connection portion 240 may have a protrusion 244 and a recess 245. The recess 245 may be formed between the protrusion 244 and the protrusion 244. The protrusions may be formed to extend in the radial direction. That is, the outer diameter of the connection portion 240 may be larger than that of the other connection portion 240.

In addition, a wire passage portion may be formed in the protrusion 244. Thus, when the protrusion 244 is mated and fixed within the cork handle housing, the wire can also be secured together.

Preferably, the cock handle 230 extends into the interior of the rotary member 170 for the aesthetic appearance of the cock handle 230. Accordingly, the cock handle 230 may be coupled to the rotary member 170 through the connection portion 140 inside the rotary member.

Specifically, the rear portion 233 of the housing shown in FIG. 8 can be penetrated into the through hole 172 of the rotating member 170. It is preferable that the outer diameter of the rear portion 233 is smaller than the outer diameter of the other portions of the cock handle 230. Therefore, the height of the rotating member 170 can be prevented from being excessively increased due to the size of the through-hole 172.

Hereinafter, the deflection preventing portion and the angle restricting portion will be described in detail with reference to FIGS. 12 and 13. FIG. FIG. 12 is a sectional view of the extension cork 220 when the connection portion 240 rises to the maximum, and FIG. 13 is a sectional view of the connection portion 240 when the connection portion 240 is fully downward.

As shown in the drawing, the connection unit 240 rotates up and down with respect to the hinge 260. It can be understood that the rear portion 170 of the connecting portion 240 is opposite to the up-and-down rotation of the extension cork 210 with respect to the hinge. The extension cork 210 is rotated downward only when the rear portion 270 of the connection portion 240 is rotated upwards and the extension portion 270 of the connection portion 240 is rotated downward, So that it rotates upward.

In the present embodiment, a structure for selectively preventing the connection portion 240, particularly the rear portion of the connection portion 240, or preventing the extension cork portion 220 from sagging and / .

First, the deflection preventing portion will be described in detail.

A gear 271 may be formed at a distal end of the connection portion 240, that is, at a rear portion 270 of the connection portion 240. The gear 271 may be provided to be engaged with the rotation damper 281. As shown in FIG. 12, for example, when the rotary damper 281 rotates clockwise, it can be seen that the rear portion 270 performs an upward rotation. The reverse is also true.

That is, only when the rotation damper rotates, the rear portion 270 is raised or lowered, so that the extension cork portion 220 can be rotated up and down. Therefore, the rotation damper 281 may be provided to rotate only when a torque of a predetermined magnitude or more is applied. That is, in order to generate a torque equal to or greater than a predetermined magnitude, the extension cork 220 can be rotated only when a user applies a force of a predetermined magnitude or more to the extension cork 220.

Therefore, when the force of the user, that is, the external force, is not applied to the extension cork portion 220, the extension cork portion 220 does not rotate. That is, deflection of the extension cork portion 220 can be prevented.

On the other hand, the rotary damper 281 can generate a repulsive force proportional to the speed of the damper. In other words, when an excessive force is applied to the extension cork portion 220, the extension cork portion 220 can be prevented from suddenly rotating by absorbing the force.

The gear 271 and the rotary damper 281 are provided in a pair so that wear and damage of the gear 271 and the rotary damper 281 can be prevented.

As a result, the sag prevention unit can be realized through the coupling relation between the rotary damper 281 and the rear portion 270 of the extension portion.

As shown, the rear portion 270 may constitute an angle restricting portion for restricting the upward maximum rotation and the maximum fall rotation angle. The angle restricting portion is provided in the through hole 172 to limit a maximum rotation angle of the extension cork portion.

The angle restricting portion may include an upper angle limiting surface 291 and a lower angle restricting surface 173 that are selectively in contact with the rear portion 270. An upper angle restricting surface 291 which is in contact with an upper surface 272 of the rear portion 270 when the extension cork portion 220 rotates up to the maximum, And a lower angle restricting surface 173 that is in contact with the lower surface 273 of the rear portion 270. [

Therefore, further rotation is limited by the surface contact of both. That is, even if a force that causes further rotation is applied by surface contact, this force can be dispersed on the contact surface.

The upper angle limiting surface 291 may be formed in the fixing member 290. The lower angle limiting surface 173 may be formed on the rotary member 170. More specifically, the lower angle limiting surface 173 may extend from the through hole 172 to the inside of the rotary member 170.

The contact surface generated at the upper angle limiting surface 291 and the lower angle limiting surface 173 may be a single plane or a plurality of planes. For example, the contact surface may have a plurality of planes formed in a step or step shape.

For example, in FIGS. 12 and 13, the upper angle limiting surface 291 is shown as being in a single plane configuration, and the lower angle limiting surface 173 is shown formed in a stepped configuration.

The maximum rising angle and the maximum falling angle of the extending cork 220 are determined through the angle restricting portion. However, it is preferable that the extended cork portion 220 does not contact the through-hole 172 at the maximum raised position and the lowered position. This is because such contact may damage the surface of the elongated cock portion 220 or the through hole 172.

Therefore, the surface contact is first generated inside the rotary member 170 before the both contact with each other, so that the maximum rotation angle is limited. Of course, it is preferable that the through hole 172 is formed to have a long vertical length so that the contact between the through hole and the extension caulk 220 is eliminated. The vertical length of the through hole should be determined considering the outer diameter of the extended cork 220 and the maximum vertical spacing of the extended cork 220 in the through hole.

100: Water purifier 110: Cabinet
120: dispenser 130: tray
140: user interface 150: main cock
155: an outflow lever 170: a rotating member
200: extension cork part 210: extension cork
220: outgoing button 230: cock handle
240: connection part 241: connection part
250: inner channel 260: hinge (rotating shaft)
280: Rotation damper assembly 290: Fixing member

Claims (18)

cabinet;
A dispenser provided in front of the cabinet to form a space in which water is to be dispensed;
A rotatable member provided to the cabinet so as to be rotatable in the left and right direction;
An extension cork portion extending from the rotation member and configured to rotate left and right integrally with the rotation member;
A hinge provided on the extension cork portion so that the extension cork portion is vertically rotated relative to the rotary member; And
And a slack preventing unit provided to allow the extension cork unit to rotate up and down when a predetermined torque or more is applied. The method according to claim 1,
Wherein a through hole is formed in the rotating member, and the extending cock extends through the through hole to the outside of the rotating member. 3. The method of claim 2,
The extension cork portion
Cork handle;
An extension cock provided at one side of the cock handle to perform water outflow; And
And a connection part connected to the rotary member at the other side of the cock handle. The method of claim 3,
Wherein the hinge is formed on the connecting portion, and a hinge seating portion in which the hinge is rotatably seated is formed in the rotating member. 5. The method of claim 4,
And a fixing member for fixing at least one of the hinge and the sag prevention unit to the rotary member within the rotary member. 5. The method of claim 4,
Wherein the extension cork portion, the rotation member, the hinge, the sag prevention portion, and the fixing member are integrally rotated left and right. The method of claim 3,
The sag preventing unit
A gear formed on the connecting portion; And
And a rotation damper provided to be engaged with the gear so as to be rotated when a predetermined torque or more is applied thereto. 8. The method of claim 7,
And a damper seating portion in which the rotary damper is seated is formed in the rotary member. 9. The method according to any one of claims 1 to 8,
Further comprising: a main cock provided separately from the extension cork portion, wherein the main cock is installed to be at least spaced apart from the cabinet so as to be outgoing. 10. The method of claim 9,
And a rotary member fixing unit for supporting the rotary member such that the rotary member is rotatable with respect to the cabinet. cabinet;
A dispenser provided in front of the cabinet to form a space in which water is to be dispensed;
A rotary member having a through hole formed therein and rotatable in the cabinet;
An extension cock extending from the inside to the outside through the through hole and configured to rotate left and right integrally with the rotary member;
A hinge provided on the extension cork portion so that the extension cork portion is vertically rotated relative to the rotary member; And
And an angle restricting portion provided in the through hole to limit a maximum angle of rotation of the extension cork portion. 12. The method of claim 11,
The extension cork portion
A cork handle adapted to urge the user in contact;
An extension cock provided at one side of the cock handle to perform water outflow; And
And a connecting portion connected to the rotary member at the other side of the cock handle and having the hinge formed therein. 13. The method of claim 12,
Wherein the connecting portion includes a rear portion further extending rearward from the hinge,
The angle restricting portion includes an upper angle limiting surface that is in contact with an upper surface of the rear portion when the rear portion is rotated so as to maximally rise, and a lower angle limiting surface that is in contact with a lower surface of the rear portion when the rear portion is rotated down to the lowest position. Wherein the drinking water supply device comprises: 14. The method of claim 13,
Wherein at least one of the upper angle limiting surface and the lower angle limiting surface is formed to extend from the through hole to the inside of the rotating member. cabinet;
A dispenser provided in front of the cabinet to form a space in which water is to be dispensed;
A rotary member having a through hole formed therein and rotatable in the cabinet;
A cork handle provided to extend out of the through hole and to be rotated leftward and rightward in unison with the rotary member by a user's operation,
An inner passage extending from the inside of the cabinet to the inside of the rotary member; And
And a connection portion having a connection portion for connecting the extension cock to the internal flow path and a rotation portion for rotating up and down by a user's operation. 16. The method of claim 15,
And a cock handle channel is provided in the cock handle, and the extension cock is connected to the connection channel through the cock handle channel. 17. The method of claim 16,
Wherein the cock handle is provided with an outflow button for operating the outflow through the cooking cock,
Wherein the connection portion includes a wire passage portion to which a wire connected to the outlet button is fixed outside the connection portion flow path. 18. The method according to any one of claims 15 to 17,
And an inner flow path of a flexible material for allowing up and down and left and right rotation of the extension cork portion.

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