JP2020185280A - Beverage supplier - Google Patents

Abstract

To provide a beverage supplier that can reduce manufacturing cost for adjusting an amount of liquid to be extracted.SOLUTION: An electric kettle (100) includes: a water pouring lever (31); multiple flow channels (61, 62); a main on-off valve (41) for opening and closing the flow channels (61, 62) with operation to the water pouring lever (31), and a sub on-off valve (42); and a switching part for receiving a switching operation by a user and switching the opening and closing of the main on-off valve (41) to be disabled. An amount of liquid to be extracted from a pouring port (12) varies depending on switching of the switching part.SELECTED DRAWING: Figure 3

Description

The present invention relates to a beverage feeder such as a hand pot or an electric kettle.

Beverage dispensers, such as hand pots and electric kettles, that supply the contents of beverages by tilting the handle, are generally wide because they are easy to carry and can easily boil water. It is widespread.

For example, Patent Document 1 describes an electric kettle including an adjusting lever that moves an on-off valve up and down by rotating a cam. In this electric kettle, the on-off valve is moved in the vertical direction by operating the adjusting lever to adjust the degree of opening of the liquid supply port.

Further, Patent Document 2 describes an electric kettle provided with a hot water supply lever and a hot water amount changeover switch. In this electric kettle, by moving the hot water amount changeover switch, the water outlet shutter is lowered and the valve portion blocks a part of the flow path.

Japanese Unexamined Patent Publication No. 2012-196355 (published on October 18, 2012) Japanese Unexamined Patent Publication No. 2013-233225 (published on November 21, 2013)

However, the electric kettle described in Patent Document 1 or 2 is provided with a cam mechanism or a movement mechanism of a water outlet shutter for adjusting the amount of liquid to be poured, and there is a problem that the structure is complicated.

One aspect of the present invention is to realize a beverage feeder whose liquid volume can be adjusted by a simple structure.

In order to solve the above problems, the beverage feeder according to the first aspect of the present invention includes an extraction lever that accepts an extraction operation by a user, a plurality of flow paths that send liquid from a liquid storage unit to a spout, and the above. A plurality of on-off valves that are provided in at least one of a plurality of flow paths and open and close the flow path by an extraction operation of the extraction lever, and at least one of the plurality of on-off valves that accept a switching operation of a user. It is provided with a switching unit for invalidating the opening and closing of the switching target valve, and the amount of liquid extracted from the spout portion is changed by switching the switching unit.

The beverage feeder having the above configuration includes a plurality of flow paths for sending liquid from the liquid storage portion to the spout portion. Then, the plurality of on-off valves open and close a plurality of flow paths by the extraction operation of the extraction lever. Here, according to the above configuration, the switching unit accepts the switching operation of the user and invalidates the opening / closing of the switching target valve which is at least one of the plurality of on-off valves. Therefore, even if the valve is opened by the extraction operation of the extraction lever, the switching target valve whose opening and closing is invalidated by the switching portion remains closed. Therefore, among the plurality of flow paths, the liquid does not flow from the flow path provided with the switching target valve to the spout portion. Therefore, according to the above configuration, the amount of liquid extracted from the spout portion changes due to the switching of the switching portion.

According to the above configuration, the on-off valve in which the opening and closing of a plurality of flow paths for sending liquid from the liquid storage section to the spout section is linked to the extraction operation of the user, and the switching section for invalidating the opening and closing of the switching target valve. Is adjusted by. That is, the amount of liquid extracted from the spout portion changes by adjusting the opening and closing of the plurality of flow paths that send the liquid to the spout portion. Therefore, according to the above configuration, it is not necessary to provide a cam mechanism or a movement mechanism of the water outlet shutter for adjusting the amount of liquid to be poured, and the amount of liquid can be adjusted by a simple structure.

The beverage feeder according to the second aspect of the present invention may have a configuration in which the plurality of on-off valves are provided corresponding to each of the plurality of flow paths in the first aspect. As a result, it is possible to realize a beverage feeder capable of reducing the manufacturing cost of the mechanism for adjusting the extraction amount of the liquid.

In the beverage feeder according to the third aspect of the present invention, in the first or second aspect, the switching portion has a contact pressing portion that opens the valve by pressing the switching target valve and a non-applicable portion that does not press the switching target valve. The contact pressing portion may be provided, and the contact pressing portion and the non-contact pressing portion may be switched by accepting the switching operation of the user. As a result, the opening and closing of the switching target valve can be invalidated.

In the beverage feeder according to the fourth aspect of the present invention, in the third aspect, the switching between the contact pressing portion and the non-contact pressing portion is performed so that the contact pressing portion is relative to the switching target valve. The configuration may be performed by moving. With such a configuration, a mechanism related to switching can be configured while suppressing the thickness thereof.

In the beverage feeder according to the fifth aspect of the present invention, in any one of the first to fourth aspects, the plurality of flow paths are composed of the first and second flow paths, and the on-off valve is the first flow path. It is composed of a first on-off valve for switching the opening and closing of the second flow path and a second on-off valve for switching the opening and closing of the second flow path, and presses the first and second on-off valves in conjunction with the extraction lever. A valve opening portion for opening the valve is provided, and the valve opening portion is provided with the switching portion, and the first valve opening portion for opening the first on-off valve and the first valve opening portion are provided with the valve opening portion. A second valve opening portion for opening the second on-off valve in conjunction with the valve is provided, and switching of the switching portion invalidates the opening and closing of the first on-off valve, while opening and closing the second on-off valve. The opening and closing of the valve may be an effective configuration.

According to the above configuration, the opening and closing of both the first and second on-off valves can be switched by operating the extraction lever. According to the above configuration, the switching of the switching portion invalidates the opening and closing of the first on-off valve, while the opening and closing of the second on-off valve is effective. Therefore, by operating the extraction lever. When both the first and second on-off valves are switched to the open state, the second on-off valve is always in the open state. On the other hand, the opening and closing of the first on-off valve is invalid or effective depending on the switching operation of the switching portion by the user. Therefore, in the above configuration, both the first and second flow paths can be switched to the open state, and only the second flow path can be switched to the open state by operating the extraction lever and the switching unit. Therefore, when the beverage is extracted from the spout portion by operating the extraction lever, the amount of the liquid extracted from the spout portion can be switched.

In any one of aspects 1 to 5, the beverage feeder according to the sixth aspect of the present invention has a U-shape in which the cross-sectional shape perpendicular to the direction in which the liquid is extracted is recessed downward. The side wall surface forming the spout portion may have two flat planes extending upward from the curved surface forming the bottom portion of the spout portion.

According to the above configuration, the side wall surface forming the spout portion has two inclined planes extending upward from the curved surface forming the bottom portion of the spout portion, and thus the spout portion has. Means that two guides through which the beverage flows have been formed. That is, in addition to the guide for the beverage flowing through the entire spout portion, the guide for flowing a small amount of beverage is formed by the two eccentric planes and the curved surface forming the bottom portion. Therefore, when the amount of the beverage poured out from the spout portion is reduced, the rectification property of the beverage discharged from the spout portion is improved.

According to one aspect of the present invention, a beverage feeder capable of adjusting the amount of hot water can be realized by a simple structure.

1010 is a perspective view showing the appearance of the electric kettle according to the first embodiment of the present invention as seen from the side, and 1020 is a perspective view showing the appearance of the electric kettle according to the first embodiment of the present invention as seen from the front. Is. 2010 is a perspective view showing the appearance of the lid provided in the electric kettle according to the first embodiment of the present invention, and 2020 is an internal configuration of the lid provided in the electric kettle according to the first embodiment of the present invention. It is a perspective view which shows. It is sectional drawing which shows the structure of the lid body provided in the electric kettle which concerns on Embodiment 1 of this invention, 3010 shows the state of the lid body at the time of normal use, and 3020 is the state of the lid body at the time of a small amount use. Is shown. Regarding the electric kettle according to the second embodiment of the present invention, 4010 is a perspective view showing the appearance of the electric kettle as seen from above the spout portion. Further, 4020 is a cross-sectional view showing a cross-sectional shape perpendicular to the front-rear direction of the spout portion of the electric kettle.

[Embodiment 1]
Hereinafter, one embodiment of the present invention will be described in detail. 1010 of FIG. 1 is a perspective view showing the appearance of the electric kettle 100 according to the present embodiment as viewed from the side, and 1020 of FIG. 1 shows the appearance of the electric kettle 100 of the present embodiment as viewed from the front. It is a perspective view.

As shown in 1010 and 1020 of FIG. 1, the electric kettle 100 (hereinafter referred to as the present electric kettle 100) according to the present embodiment includes a kettle main body 10, a power supply stand 20, and a lid 30. There is. The kettle main body 10 (liquid storage portion) has an upper opening and a heating heater 14 is arranged at the bottom. A predetermined amount of beverage such as water is stored in the kettle main body 10. The kettle main body 10 is placed on the power supply stand 20, and power is supplied to the heating heater 14 of the kettle main body 10. The lid 30 is detachably provided so as to cover the opening of the kettle main body 10, and includes a detachable mechanism (not shown), a valve opening / closing mechanism (see FIG. 2), and the like. Further, a handle portion 11 that can be gripped by the user is provided on the side wall portion of the kettle main body 10.

Here, the lid 30 side is on the upper side and upper side with respect to the kettle main body 10, and the lower side and lower side on the power supply stand 20 side with respect to the kettle main body 10. Further, the handle portion 11 side with respect to the kettle main body 10 is the rear side and the rear side, and the side opposite to the handle portion 11 with respect to the kettle main body 10 is the front side and the front side.

A spout portion 12 is provided in front of the kettle body 10. As shown in 1020 of FIG. 1, the electric kettle 100 is provided with two flow paths 61 and 62 for supplying liquid from the kettle body 10 to the spout portion 12. In the vicinity of the spout portion 12, the flow path 62 (second flow path) is provided substantially in the center of the flow path 61 (first flow path). Further, the flow path 61 and the flow path 62 extend toward the spout portion 12 so as to be parallel to each other. The flow path 62 is configured such that the amount of liquid flowing through the flow path 62 is smaller than the amount of liquid flowing through the flow path 61. In the case of the electric kettle 100, the flow path 62 is configured to supply a sufficient amount (small amount) of hot water to the spout portion 12, for example, when dripping coffee.

2010 of FIG. 2 is a perspective view showing the appearance of the lid 30. Further, 2020 of FIG. 2 is a perspective view showing the internal configuration of the lid body 30. 3 is a cross-sectional view showing the configuration of the lid 30, FIG. 3 3010 shows the state of the lid 30 during normal use such as when hot water is poured into the cup ramen, and 3020 of FIG. 3 is , The state of the lid 30 when used in a small amount such as when dripping coffee.

As shown in 2010 and 2020 of FIG. 3, the lid 30 includes an upper lid 30a and a housing portion 30b. The housing portion 30b houses various members constituting various mechanisms of the lid 30 (valve opening / closing mechanism, mechanism for attaching / detaching from / from the kettle main body 10 and the like). The upper lid 30a is a member that closes the housing portion 30b.

A hot water amount changeover switch 36 is provided on the upper portion of the lid 30 so as to protrude from the upper lid 30a. Further, a water injection lever 31 (extraction lever) for receiving an extraction operation by the user is provided on the rear side portion of the lid 30 so as to protrude from the upper lid 30a and the housing portion 30b. In the electric kettle 100, when the water injection lever 31 is pressed downward, the main on-off valve 41 and the sub on-off valve 42, which will be described later, are opened, and the liquid in the kettle main body 10 is poured out from the spout portion 12.

The lid 30 includes a main on-off valve 41 (first on-off valve) and a sub on-off valve 42 (second on-off valve). The main on-off valve 41 and the sub on-off valve 42 are provided in the flow paths 61 and 62, respectively, and open and close the flow paths 61 and 62 by the extraction operation of the water injection lever 31. The main on-off valve 41 is a valve that switches the opening and closing of the flow path 61 by vertical movement, and when it moves downward, the flow path 61 is opened. Further, the sub on-off valve 42 is a valve that switches the opening and closing of the flow path 62 by vertical movement, and when it moves downward, the flow path 62 is opened. The hot water amount changeover switch 36 is configured to specify whether the opening / closing of the main on-off valve 41 is valid or invalid.

Further, the lid body 30 is provided with a compression coil spring 43 in the sub on-off valve 42. The compression coil spring 43 abuts from below the sub on-off valve 42 and urges the sub on-off valve 42 upward by its elastic force. Further, although not shown, the main on-off valve 41 is also provided with a compression coil spring that abuts from below the main on-off valve 41 and urges the main on-off valve 41 upward by an elastic force, similarly to the sub on-off valve 42. Has been done.

Further, the lid body 30 presses the first valve opening member 32 (valve opening portion, first valve opening portion) that opens by pressing the main on-off valve 41 downward, and the sub on-off valve 42 downward. It is provided with a second valve opening member 33 (valve opening portion, second valve opening portion) that opens the valve. The first valve opening member 32 is configured to press the main on-off valve 41 downward in conjunction with the water injection lever 31. Further, the second valve opening member 33 is configured to press the sub on-off valve 42 downward in conjunction with the first valve opening member 32.

More specifically, the water injection lever 31 is rotatably supported by the lid 30 around the support shaft 31a. Further, the front end of the water injection lever 31 is in contact with the rear end of the first valve opening member 32 from below. Further, the first valve opening member 32 is rotatably supported by the lid 30 around the support shaft 32a. The front end of the first valve opening member 32 is configured to abut from above on the upper part of the main on-off valve 41.

Further, the rear portion of the second valve opening member 33 is connected to the front portion of the support shaft 32a of the first valve opening member 32 via a support shaft (not shown). The second valve opening member 33 is rotatably connected to the first valve opening member 32 around the support shaft. Further, the front portion of the second valve opening member 33 is rotatably supported by the lid 30 around the support shaft 33b. Further, the second valve opening member 33 is configured such that the portion from the connecting portion with the first valve opening member 32 to the support shaft 33b abuts on the upper portion of the sub on-off valve 42 from above.

The electric kettle 100 is provided with a switching unit that accepts a user's switching operation and invalidates the opening / closing of the main on-off valve 41 (switching target valve) among the main on-off valve 41 and the sub on-off valve 42.

The switching portion includes a first valve opening member 32. The first valve opening member 32 opens by sliding at the opening 34 (non-contact pressing portion) that does not press the main on-off valve 41 from above and pressing the main on-off valve 41 from above. A slide member 35 (contact pressing portion) to be operated is provided.

The slide member 35 is guided by the first valve opening member 32 and slides through the opening 34. Switching between the slide member 35 (contact pressing portion) and the opening 34 (non-contact pressing portion) is performed by moving (sliding mode) the slide member 35 relative to the main on-off valve 41. ..

The switching unit includes a hot water amount switching switch 36 that receives a switching operation by the user and slides the slide member 35 and the opening 34 to switch. The hot water amount changeover switch 36 is configured to specify the opening and closing of the main on-off valve 41. The hot water amount changeover switch 36 invalidates the opening and closing of the main on-off valve 41 by switching whether the portion where the main on-off valve 41 overlaps with the first valve opening member 32 is the opening 34 or the slide member 35. It is configured as follows.

The opening 34 and the slide member 35 are arranged at a portion of the first valve opening member 32 that comes into contact with the main on-off valve 41. As shown in 3010 and 3020 of FIG. 3, the lower end of the hot water amount changeover switch 36 is connected to the slide member 35. The slide member 35 is rotatably connected to the first valve opening member 32 around the support shaft 35a.

Next, the adjustment of the amount of liquid discharged from the spout portion 12 by the switching mechanism will be described.

<When supplying the amount of liquid during normal use>
When the hot water amount changeover switch 36 is in the position where the normal amount of liquid is poured out (here, the position moved to the front side), the opening 34 at the position where it overlaps with the main on-off valve 41 of the first valve opening member 32 is , Closed by the slide member 35. In this state, when the water injection lever 31 is pressed downward, the front end of the water injection lever 31 rotates upward around the support shaft 31a, and the rear end of the first valve opening member 32 is pressed upward. Liver. Then, the front end portion of the first valve opening member 32 rotates downward around the support shaft 32a. Then, the slide member 35 provided on the first valve opening member 32 comes into contact with the main on-off valve 41 and presses the upper portion of the main on-off valve 41 from above. Therefore, the main on-off valve 41 is opened.

Further, as the front end of the first valve opening member 32 rotates downward, the rear end of the second valve opening member 33 rotates downward around the support shaft 33b. As a result, the second valve opening member 33 presses the upper portion of the sub on-off valve 42 from above, so that the sub on-off valve 42 is opened.

That is, both the main on-off valve 41 and the sub on-off valve 42 are opened, and the user can pour hot water from the spout portion 12 to the amount of liquid during normal use.

When the user stops pouring hot water, the downward pressing of the water injection lever 31 is stopped. Then, due to the elastic force of the compression coil spring 43 or the like, the pressed water injection lever 31 returns to the initial position of the water injection lever 31, the first valve opening member 32, and the second valve opening member 33. As a result, the main on-off valve 41 and the sub on-off valve 42 return to the closed state, and the supply of hot water from the kettle main body 10 is stopped.

<When supplying the amount of liquid when using a small amount>
When the hot water amount changeover switch 36 is in the position where a small amount of liquid is poured out (here, the position is moved to the rear side), the opening 34 at the position where it overlaps with the main on-off valve 41 of the first valve opening member 32 is Not closed by the slide member 35. In this state, when the water injection lever 31 is pressed downward, the front end of the water injection lever 31 rotates upward around the support shaft 31a, and the rear end of the first valve opening member 32 is pressed upward. Liver. Then, the front end portion of the first valve opening member 32 rotates downward around the support shaft 32a.

Here, since the main on-off valve 41 passes through the opening 34 of the first valve opening member 32, it does not come into contact with the slide member 35. Therefore, the main on-off valve 41 is not pressed from above (hereinafter referred to as non-pressing) and is not opened (the main on-off valve 41 remains in the closed state).

On the other hand, as the front end of the first valve opening member 32 rotates downward, the second valve opening member 33 rotates downward around the support shaft 33b. As a result, the second valve opening member 33 presses the upper portion of the sub on-off valve 42 from above, so that the sub on-off valve 42 is opened.

That is, while the main on-off valve 41 is in the closed state, the sub on-off valve 42 is in the open state, and the liquid is supplied only from the flow path 62. Therefore, the user pours hot water from the spout portion 12 and uses a small amount of liquid. It becomes possible to pour the amount.

In this way, the electric kettle 100 includes a water injection lever 31 that accepts the extraction operation of the user, flow paths 61 and 62 that send liquid from the kettle body 10 to the spout portion 12, and a main on-off valve 41 and a sub on-off valve 42. , With a switching part. The main on-off valve 41 and the sub on-off valve 42 are provided in the flow paths 61 and 62, respectively, and open and close the flow paths 61 and 62 by the extraction operation of the water injection lever 31. Further, the switching portion includes an opening 34 provided in the first valve opening member 32, a slide member 35, and a hot water amount switching switch 36, and accepts a switching operation of the user, and opens and closes the main on-off valve 41 and the sub. Of the valves 42, the opening and closing of the main on-off valve 41 (switching target valve) is invalidated. The electric kettle 100 has a configuration in which the amount of liquid extracted from the spout portion 12 changes depending on the switching of the switching portion.

According to the electric kettle 100, even if the valve is opened by the extraction operation of the water injection lever 31, the main on-off valve 41 whose opening and closing is invalidated by the switching portion remains closed. Therefore, of the flow paths 61 and 62, the liquid does not flow from the flow path 61 provided with the main on-off valve 41 to the spout portion 12. Therefore, the amount of liquid extracted from the spout portion 12 changes due to the switching of the switching portion.

In the electric kettle 100, the main on-off valve 41 and the sub on-off valve 42, and the main on-off valve 41 in which the opening and closing of the flow paths 61 and 62 for sending the liquid from the kettle main body 10 to the spout portion 12 are linked to the extraction operation of the user. It is adjusted by a switching unit that disables opening and closing. That is, the amount of liquid extracted from the spout portion 12 changes by adjusting the opening and closing of the flow paths 61 and 62 that send the liquid to the spout portion 12. Therefore, since the amount of liquid extracted changes only by the opening / closing switching operation of the main on-off valve 41 and the sub on-off valve 42 provided in the flow paths 61 and 62, a multi-stage cam or a water outlet shutter is provided for one liquid supply flow path. Compared to a conventional beverage feeder in which the amount of liquid extracted by the liquid is adjusted, the structure of the mechanism for adjusting the amount of liquid extracted does not require high precision. Therefore, it is possible to realize a beverage feeder capable of reducing the manufacturing cost of the mechanism for adjusting the extraction amount of the liquid. Furthermore, in order to adjust the amount of liquid to be poured out, it is not necessary to provide a cam mechanism or a moving mechanism of the water outlet shutter, and the amount of liquid can be adjusted by a simple structure.

The electric kettle 100 has a configuration in which two flow paths for supplying liquid to the spout portion 12 are provided, but the present invention is not limited to the above configuration, and three or more flow paths are provided, and the plurality of flow paths are provided. The opening / closing of at least one of the flow paths of the above may be invalidly switched by the switching unit. With such a configuration, the amount of hot water can be adjusted.

Further, the electric kettle 100 has a configuration in which a main on-off valve 41 and a sub on-off valve 42 are provided in each of the flow paths 61 and 62, but the present invention is not limited to the above configuration, and a plurality of flow paths are provided. An on-off valve that opens and closes the flow path by the extraction operation of the extraction lever may be provided in at least one of the plurality of flow paths.

Further, according to the electric kettle 100, the valve opening portion that opens by pressing the main on-off valve 41 and the sub on-off valve 42 in conjunction with the water injection lever 31 is provided with a switching portion to open the main on-off valve 41. A first valve opening member 32 for valve opening and a second valve opening member 33 for opening the sub on-off valve 42 in conjunction with the first valve opening member 32 are provided. Then, by switching the switching portion, the opening / closing of the main on-off valve 41 becomes invalid, while the opening / closing of the sub on-off valve 42 is effective.

In the electric kettle 100, the opening and closing of both the main on-off valve 41 and the sub on-off valve 42 can be switched by operating the water injection lever 31. Then, by switching the switching portion, the opening / closing of the main on-off valve 41 becomes invalid, while the opening / closing of the sub on-off valve 42 is effective. When switched to the open state, the second on-off valve is always in the open state. On the other hand, the main on-off valve 41 is disabled or enabled depending on the switching operation of the hot water amount switching switch 36 by the user. Therefore, by operating the water injection lever 31 and the hot water amount changeover switch 36, both the flow paths 61 and 62 can be switched to the open state, and only the flow path 62 can be switched to the open state. Therefore, when the beverage is poured out from the spout portion 12 by operating the water injection lever 31, the amount of liquid poured out from the spout portion 12 can be switched. For example, by moving the hot water amount changeover switch 36 backward, the amount of hot water poured out from the spout portion 12 can be switched to a small amount of hot water when dripping coffee.

[Embodiment 2]
Other embodiments of the present invention will be described below. For convenience of explanation, the same reference numerals will be added to the members having the same functions as the members described in the above embodiment, and the description will not be repeated.

In the present embodiment, the rectifying mechanism of the hot water discharged from the spout portion 12 will be described. As shown in 2010 and 2020 of FIG. 2 and 3010 and 3020 of FIG. 3, the electric kettle 100 is provided with a rectifying cylinder member 51. The rectifying cylinder member 51 is provided at the front end of the flow paths 61 and 62. Further, the front end of the flow path 62 is arranged behind the front end of the flow path 61.

The hot water poured out from the flow paths 61 and 62 passes through the rectifying cylinder member 51 and flows into the spout portion 12. At this time, the rectifying cylinder member 51 functions as a guide for the flow of hot water flowing into the spout portion 12. Therefore, hot water is poured out from the spout portion 12 in a state of being rectified by the rectifying cylinder member 51. As a result, in the electric kettle 100, the rectifying cylinder member 51 improves the rectifying property of the hot water poured out from the spout portion 12.

Further, the electric kettle 100 is characterized by the structure of the spout portion 12 in order to improve the rectification property of the hot water to be poured out. 4010 of FIG. 4 is a perspective view showing the appearance of the spout portion 12 of the electric kettle 100 as viewed from above. Further, 4020 of FIG. 4 is a cross-sectional view showing a cross-sectional shape perpendicular to the front-rear direction of the spout portion 12 of the electric kettle 100.

As shown in 4010 and 4020 of FIG. 4, the spout portion 12 has a U-shape having a downwardly recessed cross-sectional shape perpendicular to the front-rear direction (that is, the direction in which the liquid is extracted). The cross-sectional shape of the spout portion 12 is axisymmetric with respect to the center line C. Further, the distance between the side walls facing each other forming the spout portion 12 becomes smaller toward the front. Further, the top bottom portion of the spout portion 12 (the bottom portion of the cross-sectional shape (U-shape) of the spout portion 12) is configured to be positioned upward as it goes forward.

In the spout portion 12 of the electric kettle 100, the side wall 13 constituting the spout portion 12 is not a flush surface but is composed of a plurality of surfaces. More specifically, the side wall 13 is composed of side wall surfaces 13a, 13b, and 13c. The side wall surface 13a is a surface forming the bottom portion of the spout portion 12. Further, the side wall surface 13c is a surface forming the upper portion of the spout portion 12. The side wall surface 13b is a surface that connects the side wall surface 13a and the side wall surface 13c.

The side wall surface 13a and the side wall surface 13c are curved surfaces forming a U-shaped surface, while the side wall surface 13b is an eccentric plane. Two side wall surfaces 13b are provided so as to be line-symmetric with respect to the center line C, and the side wall surfaces 13b are bent upward and extend from the side wall surface 13a. Further, the distance between the two side wall surfaces 13b and 13b becomes smaller toward the front. The distance between the two side wall surfaces 13b and 13b at the front end of the spout portion 12 is smaller than the width of the flow path 62.

In the spout portion 12, the side wall surface 13a and the side wall surface 13b form a guide for the flow of hot water flowing only in the flow path 62. Further, the side wall surfaces 13a to 13c form a guide for hot water flowing through both the flow paths 61 and 62. As described above, in the electric kettle 100, a guide for the flow of hot water flowing only in the flow path 62 is formed in the spout portion 12. Therefore, when the amount of hot water to be poured out is reduced by moving the hot water amount changeover switch 36 rearward, the rectification property of the hot water poured out from the spout portion 12 is improved.

Further, in the present embodiment, the case where the beverage supply device is the electric kettle 100 has been described as an example, but the beverage supply device is not limited to this. The present embodiment can be suitably applied to all beverage dispensers such as hand pots and electric kettles that supply contents such as beverages by holding and tilting a handle.

The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention.

10 Kettle body (liquid storage part)
12 Spout 13 Side wall 13a Side wall surface (curved surface forming the bottom of the spout)
13b Side wall surface (eccentric plane)
30 Lid 31 Water injection lever (extraction lever)
32 First valve opening member (valve opening portion, first valve opening portion)
33 Second valve opening member (valve opening portion, second valve opening portion)
34 Opening (non-contact pressing part, switching part)
35 Slide member (contact pressing part, switching part)
36 Hot water amount changeover switch 41 Main on-off valve (first on-off valve)
42 Sub on-off valve (second on-off valve)
61 flow path (first flow path)
62 Channel (second channel)
100 electric kettle (beverage dispenser)

Claims (6)

An extraction lever that accepts the user's extraction operation,
Multiple channels that send liquid from the liquid storage section to the spout section,
A plurality of on-off valves provided in at least one of the plurality of flow paths and which open and close the flow paths by an extraction operation of the extraction lever.
It is provided with a switching unit that accepts the switching operation of the user and invalidates the opening / closing of the switching target valve, which is at least one of the plurality of on-off valves.
A beverage feeder in which the amount of liquid extracted from the spout is changed by switching the switching portion. The beverage feeder according to claim 1, wherein the plurality of on-off valves are provided corresponding to each of the plurality of flow paths. The switching portion includes a contact pressing portion that opens the valve by pressing the switching target valve and a non-contact pressing portion that does not press the switching target valve, and receives the switching operation of the user. The beverage feeder according to claim 1 or 2, wherein the contact pressing portion and the non-contact pressing portion are switched. The beverage feeder according to claim 3, wherein the switching between the contact pressing portion and the non-contact pressing portion is performed by moving the contact pressing portion relative to the switching target valve. .. The plurality of flow paths consist of a first flow path and a second flow path.
The on-off valve comprises a first on-off valve for switching the opening and closing of the first flow path and a second on-off valve for switching the opening and closing of the second flow path.
A valve opening portion for opening the valve by pressing the first and second on-off valves in conjunction with the extraction lever is provided.
The valve opening portion
A first valve opening portion, which is provided with the switching portion and opens the first on-off valve,
A second valve opening portion for opening the second on-off valve in conjunction with the first valve opening portion is provided.
The beverage feeder according to any one of claims 1 to 4, wherein the switching of the switching unit invalidates the opening and closing of the first on-off valve, while the opening and closing of the second on-off valve is effective. .. The spout portion has a U-shape having a downwardly recessed cross-sectional shape perpendicular to the direction in which the liquid is extracted.
The beverage feeder according to any one of claims 1 to 5, wherein the side wall surface forming the spout portion has two flat planes extending upward from the curved surface forming the bottom portion of the spout portion. ..

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