JP6362934B2 - Beverage container connection structure for beverage server and beverage container with connection structure - Google Patents

Description

  The present invention relates to a beverage container connection structure for a beverage server and a beverage container with the connection structure, and more specifically, to a beverage server for connecting a beverage server and a beverage container for supplying a beverage to the beverage server. The present invention relates to a connection structure for a beverage container, and a beverage container with a connection structure having the connection structure.

  In recent years, beverage servers such as water servers have become widespread not only in companies but also in general households. The beverage server provides the beverage server user with a small amount of beverage in the beverage container connected to the beverage server.

  Patent document 1 is disclosing the drink server which provided the float valve so that gas might not mix in the piping system of a drink server, even when the drink in a drink container runs out. When there is drinking water in the beverage container, the float valve rises by buoyancy and opens the pipeline, so that drinking water is supplied to the piping system. On the other hand, when there is no drinking water in the beverage container, the float valve descends and abuts against the valve seat to close the conduit.

  Patent Document 2 discloses a beverage server that supplies water after cooling or heating. This beverage server uses a float valve called a separator float so as to suppress convection on the cold water side or hot water side on the side of the beverage container. By this separator float, the drinking water in a drink container and the drinking water in the cold water tank provided in the drink server are interrupted | blocked, and a convection is suppressed.

JP 2005-308297 A JP 2009-196650 A

  By the way, in order to prevent generation | occurrence | production of microbes, such as an underwater floating microbe, in a drinking water, the drink server is performing the sterilization process by heating the drink which has stayed in the drink server at night, for example. However, if germs are generated in the beverage in the beverage server and the beverage comes into contact with the beverage in the beverage container, and the germ is mixed into the beverage in the beverage container, the beverage server performs sterilization processing. However, the beverage in the beverage container cannot be sterilized.

  For this reason, it is necessary to block the beverage in the beverage container and the beverage in the beverage server. However, the beverage servers in Patent Documents 1 and 2 using a float valve have the following problems.

  In the case of the beverage server of Patent Document 1, when there is drinking water in the beverage container, the float valve floats and the pipe line is opened, so that the beverage in the beverage server may come into contact with the beverage in the beverage container.

  In the case of the beverage server of Patent Literature 2, the float valve rises to close the water outlet of the beverage container, so that the drinking water in the beverage container is temporarily blocked from the drinking water in the beverage server. However, since the float valve is based on buoyancy, the water outlet of the beverage container may not be sufficiently sealed.

  Moreover, since the drinking water of the beverage server adhering to the float valve adheres to the water outlet of the beverage container, there is a high possibility that the beverage in the beverage container will be contaminated by the bacteria when the bacteria in the beverage of the beverage server is generated. .

  The present invention has been made on the basis of the above technical recognition, and its purpose is for a beverage server capable of preventing the germs from being mixed in the beverage container even if the germs are generated in the beverage server. It is providing the connection structure of a drink container, and the drink container with a connection structure.

A connection structure for a beverage container for a beverage server according to the present invention,
A beverage container for a beverage server, comprising: a beverage server that provides a beverage by a user's operation; and a beverage container that houses the beverage and is installed on the beverage server and supplies the beverage to the beverage server. A connection structure,
A supply channel for distributing the beverage from the lower part of the beverage container;
An air chamber housing having an inner diameter larger than an inner diameter of the supply flow path and having an air chamber communicating with the supply flow path formed therein;
A connector provided at a lower portion of the air chamber housing and fitted with a receiving member provided in the beverage server;
With
The shape of the supply flow path and the air chamber housing is such that the air can be used regardless of whether the beverage server is providing or stopping serving when the beverage container is connected to the beverage server via the connector. It is configured to form an air pocket in the room.

Moreover, in the connection structure of the beverage container for the beverage server,
When the flow rate of the beverage supplied from the beverage server is 1 to 2 liters / minute, the inner diameter of the supply flow path is 5 mm to 12 mm, and the inner diameter of the air chamber housing is 25 mm to 40 mm. Good.

Moreover, in the connection structure of the beverage container for the beverage server,
At least a part of the supply flow path may be constituted by an elastically deformable elastic tube.

Moreover, in the connection structure of the beverage container for the beverage server,
The connector is
An engagement member provided therein with a first flow path through which the beverage supplied from the beverage container circulates;
A biasing member having a base end supported by the engagement member;
A valve body connected to the tip of the biasing member;
A cylindrical member in which a second flow path through which the beverage circulates is provided, and a valve seat for seating the valve body in a sealable manner is provided on an inner peripheral surface;
Have
The engaging member is configured so that the valve body and the biasing member are inserted into the cylindrical member, and the valve body is biased toward the valve seat by the biasing member. You may make it adhere to.

Moreover, in the connection structure of the beverage container for the beverage server,
A protrusion is provided at the lower end of the valve body of the connector,
The receiving member of the beverage server is provided with a contact portion,
When the connector is fitted to the receiving member, the protrusion comes into contact with the contact portion, whereby the protrusion is pushed up against the urging force of the urging member, and the valve body is You may make it space apart from the valve seat part of a shaped member.

A beverage container with a connection structure according to the present invention,
A connection structure according to the present invention;
A beverage container connected to the connection structure via the supply channel;
It is characterized by providing.

  In the present invention, the shapes of the supply flow path and the air chamber housing are configured to form an air pocket in the air chamber regardless of whether the beverage is being provided or stopped by the beverage server. Due to this air accumulation, the beverage in the beverage container is separated from the beverage in the beverage server when the beverage supply is stopped. In addition, while the beverage is being provided, the beverage in the beverage container is in a state of flowing from the supply flow path toward the beverage server via the air reservoir, so that the beverage in the beverage server does not flow back to the beverage container.

  Therefore, according to the present invention, even when germs are generated in the beverage server, the germs can be prevented from being mixed into the beverage container.

(A) is sectional drawing of the connection structure 1 of the drink container for drink servers which concerns on embodiment, the drink container 10, and the drink server 20 in the state before mounting | wearing with the drink server 20, (b), It is the top view of the receiving member 22 seen from the B direction of Fig.1 (a). 3 is an enlarged cross-sectional view of an air chamber housing 3 and a connector 4. FIG. It is sectional drawing of the connection structure 1, the drink container 10, and the drink server 20 of the drink container for drink servers in the state with which the drink server 20 was mounted | worn. It is sectional drawing of the connection structure 1, the drink container 10, and the drink server 20 of the drink container for drink servers in the state which is providing a drink. It is sectional drawing of the connection structure 1, the drink container 10, and the drink server 20 of the drink container for drink servers in the state which drink provision has been stopped. It is sectional drawing of the connection structure 1, the drink container 10, and the drink server 20 of the drink container for drink servers in the state which removed the connection structure 1 of the drink container for drink servers from the drink server 20. FIG. It is sectional drawing of the connection structure 1A of the drink container for drink servers which concerns on another embodiment of this invention.

  Hereinafter, embodiments according to the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the component which has an equivalent function in each figure.

  First, the structure of the beverage container connection structure 1 (hereinafter also simply referred to as “connection structure 1”), the beverage container 10 and the beverage server 20 according to the embodiment of the present invention is shown in FIGS. 1 and 2. Will be described with reference to FIG.

  FIG. 1A shows a cross-sectional view of the connection structure 1, the beverage container 10, and the beverage server 20 in a state before being attached to the beverage server 20. A part of the connector 4 (the urging member 6 and the valve body 7) is a side view (the same applies to FIGS. 3 to 6). In addition, in Fig.1 (a), sectional drawing of the drink container 10 and the drink server 20 is a partial sectional view which concerns on the part of the connection part vicinity with each connection structure 1. FIG. FIG.1 (b) shows the top view of the receiving member 22 seen from the B direction of Fig.1 (a). FIG. 2 is an enlarged cross-sectional view of the air chamber housing 3 and the connector 4.

  The beverage container connection structure 1 for a beverage server is for connecting the beverage container 10 and the beverage server 20. First, the beverage container 10 and the beverage server 20 will be described, and then the beverage container connection structure 1 for the beverage server will be described.

  As shown in FIG. 1A, the beverage container 10 contains a beverage (water, juice, etc.) 15 therein. The beverage container 10 is installed on the beverage server 20 and supplies the beverage to the beverage server 20.

  As shown in FIG. 1A, the beverage container 10 includes a main body portion 13, a spout portion 11 provided at a lower portion of the main body portion 13, and a cap portion 12.

  The main body 13 of the beverage container 10 is a soft single or double or more bag made of a film (also referred to as “bag”), and a part to which the spout part 11 is attached is opened. The main body 13 may be a container made of a resin such as polyethylene terephthalate resin or glass.

  The beverage container 10 is connected to the connection structure 1 via a supply flow path (described later) of the connection structure 1.

  In addition, it is preferable that the drink container 10 is comprised so that it may deform | transform easily as the drink 15 is supplied and the content decreases, and the inside of the drink container 10 does not become a negative pressure. Thereby, with the decrease in the contents of the beverage container 10, it is possible to prevent the supply of the beverage from being hindered and the beverage from flowing backward.

  For example, the beverage container 10 is preferably a bag-in-box in which a bag-shaped beverage container made of a film is housed in a cardboard box. Thereby, in addition to said effect, the handleability at the time of installing in the server 20 for drinks can also be improved.

  The spout part 11 is a cylindrical member attached to the opening of the main body part 13. The cap part 12 is attached to the spout part 11 so as not to be easily detached by a stopper.

  As shown in FIG. 1A, the cap portion 12 is provided with a connecting portion 12a. The connecting portion 12 a is formed as a cylindrical protrusion, and the beverage container 10 is connected to the elastic tube 2 by the fitting of the connecting portion 12 a into the elastic tube 2.

  The beverage server 20 provides a beverage by a user's operation. For example, the user pours a desired amount of beverage from the beverage server 20 into a container such as a cup by operating a beverage dispensing means (not shown) such as a lever of the beverage server 20.

  As shown in FIG. 1, the beverage server 20 includes a main body portion 21, a receiving member 22, and a beverage dispensing path 23 connected to the receiving member 22. Each of the receiving member 22 and the beverage dispensing path 23 is a tubular member provided in the main body portion 21 and distributes the beverage supplied from the beverage container 10 to the inside.

  As shown in FIGS. 1A and 1B, the receiving member 22 is provided with a contact portion 22a. Although this contact part 22a is mentioned later for details, it is for opening the non-return valve of the connector 4 so that the drink 15 supplied from the drink container 10 can pass.

  Next, the connection structure 1 of the beverage container for beverage servers will be described.

  The connection structure 1 includes a supply flow path, an air chamber housing 3, and a connector 4. The supply flow path includes an elastic tube 2 as shown in FIG. The elastic tube 2 is a tube that can be elastically deformed. Thus, when the beverage container 10 is connected to the beverage server 20, the connector 4 may be attached to the receiving member 22 of the beverage server 20 while holding the air chamber housing 3 of the connection structure 1. For this reason, it is not necessary to connect the beverage server 20 with the heavy beverage container 10 while finely adjusting the position, and it becomes easy to connect the beverage container 10 to the beverage server 20.

  As shown in FIG. 1A, the air chamber housing 3 is constituted by, for example, a cylindrical member (for example, made of resin).

  A connection portion 3 a is provided on the upper portion of the air chamber housing 3. The connection portion 3 a is formed as a cylindrical protrusion, and the air chamber housing 3 is connected to the elastic tube 2 by the connection portion 3 a being fitted into the elastic tube 2.

  In this embodiment, the connection part 12a of the cap part 12, the elastic tube 2, and the connection part 3a of the air chamber housing 3 constitute a supply flow path. The supply channel extends from the lower part of the beverage container 10 and distributes the beverage 15 in the beverage container 10.

  As shown in FIG. 1A, an air chamber A is formed inside the air chamber housing 3. The air chamber A has an inner diameter larger than the inner diameter of the supply channel, particularly the inner diameter of the outlet of the supply channel (that is, the inner diameter of the connecting portion 3a), and communicates with the supply channel. Note that air is present in the air chamber A before the connection structure 1 is attached to the beverage server 20.

  Further, as shown in FIG. 1A, the air chamber housing 3 has a step portion 3b, and the inner diameter of the air chamber housing 3 changes sharply at the step portion 3b. That is, the inner diameter of the air chamber housing 3 changes steeply from the inner diameter of the connecting portion 3a to the inner diameter of the air chamber A in the step portion 3b.

  The connector 4 is provided in the lower part of the air chamber housing 3 as shown in FIGS.

  As shown in FIG. 2, the connector 4 of this embodiment is configured as a check valve, and includes an engaging member 5, a biasing member 6, a valve body 7, and a cylindrical member 8. The engaging member 5, the urging member 6, and the valve body 7 may be integrally formed by resin molding or the like, or may be a combination of individually molded members. .

  The engaging member 5 is provided with a flow path B1 through which the beverage 15 supplied from the beverage container 10 flows.

  The urging member 6 is a member whose base end portion 6 a is supported by the engaging member 5. As shown in FIG. 2, the urging member 6 is constituted by a coil spring, for example. In addition, the shape of the biasing member 6 is not particularly limited, and may be composed of one or more columnar or plate-like elastic members, or a combination of a plurality of coil springs in a double spiral shape. It may be configured. The urging member 6 is preferably made of resin from the viewpoint of preventing corrosion by the beverage 15.

  The valve body 7 is connected to the distal end portion 6 b of the urging member 6. When the connector 4 is not connected to the beverage server 20 and is closed, the valve body 7 is seated on the valve seat portion 8a of the tubular member 8 so as to be hermetically sealed. Further, as shown in FIG. 2, the valve body 7 is provided with a protrusion 7a at the lower end. The shape of the valve body 7 is not limited to the top shape shown in FIG. 2, but may be any shape that can be seated (sealed) on the valve seat portion 8 a of the tubular member 8.

  The cylindrical member 8 is provided with a flow path B2 through which the beverage 15 flows. A valve seat portion 8 a for seating the valve body 7 in a sealable manner is provided on the inner peripheral surface of the lower portion of the cylindrical member 8.

  Moreover, the cylindrical member 8 has the outer edge part 8b extended to a radial direction outer side from an upper part, as shown in FIG. The outer edge portion 8 b closes the space between the tubular member 8 and the air chamber housing 3 and engages with the lower end of the air chamber housing 3.

  The engaging member 5 includes a tubular member 8 such that the valve body 7 and the urging member 6 are inserted into the tubular member 8 and the valve body 7 is urged by the urging member 6 toward the valve seat portion 8a. It is fixed to. The engaging member 5 is, for example, fitted with a convex portion (not shown) provided on the outer peripheral surface of the engaging member 5 and a concave portion (not shown) provided on the inner peripheral surface of the cylindrical member 8. By fitting, it is fitted to the tubular member 8.

  Next, the case where the connection structure 1 is mounted on the beverage server 20 will be described with reference to FIG. FIG. 3 shows a cross-sectional view of the connection structure 1, the beverage container 10, and the beverage server 20 in a state where the beverage server 20 is mounted.

  As shown in FIG. 3, the beverage container 10 is connected to the beverage server 20 by attaching the connector 4 to the receiving member 22 of the beverage server 20. More specifically, when the receiving member 22 of the beverage server 20 enters the recess C formed in the cylindrical member 8, the cylindrical member 8 of the connector 4 and the receiving member 22 of the beverage server 20 are fitted, and the connector 4 is fixed to the beverage server 20.

  Further, when the connector 4 is fitted to the receiving member 22 of the beverage server 20, the protruding portion 7a of the valve body 7 comes into contact with the contact portion 22a as shown in FIG. Accordingly, the protrusion 7 a is pushed up against the urging force of the urging member 6, and the valve body 7 is separated from the valve seat 8 a of the tubular member 8. The beverage 15 supplied from the beverage container 10 can pass between the valve body 7 and the tubular member 8.

  Then, the beverage 15 supplied from the beverage container 10 flows out from the supply flow path, passes between the valve body 7 and the cylindrical member 8, and fills the receiving member 22 and the beverage dispensing path 23 of the beverage server 20.

  Next, a state in which a beverage is provided from the beverage server 20 will be described with reference to FIG. FIG. 4 shows a cross-sectional view of the connection structure 1, the beverage container 10, and the beverage server 20 in a state in which a beverage is being provided. In addition, the drink 25 in FIG. 4 has shown the drink by the side of the drink server 20. FIG.

  When a user operates a beverage dispensing means such as a lever to dispense a beverage from the beverage server 20, a beverage 15 corresponding to the amount dispensed from the beverage server 20 is supplied as shown in FIG. The air flows out from the passage into the air chamber A of the air chamber housing 3.

  As shown in FIG. 4, the beverage 15 flowing out from the supply flow channel is accumulated to some extent in the air chamber A, but flows out into the beverage dispensing channel 23 without filling the air chamber A completely. This is a flow rate (hereinafter, referred to as “flow rate X”) from which the beverage 15 flows out from the supply channel to the beverage chamber 20 via the connector 4 from the flow rate (hereinafter referred to as “flow rate X”). This is because “flow velocity Y”) is equal to or higher than the flow velocity X.

  Here, the flow rates X and Y depend on the degree of opening of the beverage dispensing means of the beverage server 20, but when the beverage dispensing means is fully opened (that is, the beverage supply amount is maximized). The flow velocities X and Y are maximized. The maximum values of the flow velocities X and Y are determined by the inner diameter of the air chamber A and the inner diameter of the supply flow path. If the maximum value of the flow rate Y is equal to or greater than the maximum value of the flow rate X, the flow rate Y is equal to or greater than the flow rate X in any open state (supply amount).

  Therefore, by appropriately determining the inner diameter of the air chamber A and the inner diameter of the supply flow path (for example, the ratio of the inner diameter of the air chamber A to the inner diameter of the supply flow path is a predetermined value or more), the flow velocity Y is always the flow velocity. It becomes possible to make it X or more.

  As described above, since the flow velocity Y is always greater than or equal to the flow velocity X, the beverage 15 flowing out from the supply flow path does not completely fill the air chamber A, and an air reservoir (air layer) D exists in the air chamber A. To do.

  While the beverage is being provided, since the beverage 15 is flowing from the supply channel toward the beverage server 20 via the air reservoir D, the beverage 25 of the beverage server 20 does not flow back to the beverage container 10. Absent. Therefore, even if germs are generated in the beverage server 20, it is possible to prevent the germs from being mixed into the beverage container 10 while providing the beverage.

  Next, a state where no beverage is provided from the beverage server 20 will be described with reference to FIG. FIG. 5 shows a cross-sectional view of the connection structure 1, the beverage container 10, and the beverage server 20 in a state where the beverage provision is stopped.

  When the user returns the beverage dispensing means such as a lever to the original position and stops dispensing the beverage, the beverage 15 in the beverage container 10 does not flow out of the supply channel. As shown in FIG. 5, the air pocket D exists also in this state. For this reason, the beverage 15 in the beverage container 10 is separated from the beverage 25 in the beverage server 20 by the air reservoir D while the beverage is not being provided.

  As described above, the air reservoir D is formed in the air chamber A of the air chamber housing 3 regardless of whether the beverage is being provided or stopped. While the provision of the beverage is stopped, the beverage 15 in the beverage container 10 is separated from the beverage 25 of the beverage server 20 by the air reservoir D. During the provision of the beverage, since the air reservoir D exists, the beverage 15 always flows in the direction toward the beverage server 20 via the air reservoir D. Therefore, the beverage 25 of the beverage server 20 does not flow back to the beverage container 10. That is, the beverage 25 of the beverage server 20 does not contact the beverage 15 in the beverage container 10.

  Therefore, according to the present embodiment, even if germs are generated in the beverage server 20 and the germs are floating in the beverage 25, the germs are not mixed in the beverage container 10.

  Next, conditions for forming the air pocket D will be described.

  In order to form the air reservoir D, it is necessary that the air in the air chamber A does not move to the beverage container 10 side through the supply channel. Therefore, the inner diameter of the air chamber A must be somewhat larger than the inner diameter of the supply flow path. Furthermore, it is necessary to consider the supply rate of the beverage from the beverage server 20 (the flow rate of the beverage 25). That is, since the pressure in the air chamber A increases as the flow rate of the beverage 25 increases, the air in the air chamber A easily escapes to the beverage container 10 side. Therefore, for example, the inner diameter of the air chamber A is determined after grasping the maximum supply speed of the beverage server 20.

For example, when the flow rate of the beverage supplied from the beverage server 20 is 1 to 2 liters / minute, the inner diameter of the supply flow path (the inner diameter of the connection portion 3a) is 5 mm to 12 mm, and the inner diameter of the air chamber housing 3 is 25 mm. It is preferably ˜40 mm. Thus, an air reservoir D is formed in the air chamber A regardless of whether the beverage server 20 is providing or stopping serving. It should be noted that these numerical ranges may be arbitrarily narrowed to exclude a part (and one point in the range may be excluded), and the same effect as before the removal may be obtained in the range after the removal. Is.

  When the beverage 15 in the beverage container 10 is exhausted, the connection structure 1 of the beverage container for the beverage server is removed from the beverage server 20 by the user. FIG. 6 shows a cross-sectional view of the connection structure 1, the beverage container 10, and the beverage server 20 in a state removed from the beverage server 20.

  As shown in FIG. 6, when the connector 4 is pulled out from the beverage server 20 (receiving member 22), the valve body 7 does not come into contact with the contact portion 22 a of the receiving member 22. It seats on the valve seat part 8a of the shaped member 8 in a sealable manner. As a result, the residual water 26 remaining in the air chamber A and the cylindrical member 8 is prevented from flowing out of the connector 4.

  Thus, according to this embodiment, when the connection structure 1 is removed from the beverage server 20, the valve of the connector 4 automatically closes, so that the remaining water 26 in the connector 4 scatters to the outside or the beverage server 20 It can prevent dripping. As a result, the remaining water 26 is prevented from adhering to the periphery of the receiving member 22 of the beverage server 20 and causing the generation of bacteria.

  As described above, in the present embodiment, the shape of the supply flow path and the air chamber housing 3 is such that the beverage server 20 provides the beverage in the use state where the beverage container 10 is connected to the beverage server 20 via the connector 4. The air reservoir D is formed in the air chamber A regardless of whether it is in the middle or not in service. Since the beverage 15 in the beverage container 10 is separated from the beverage in the beverage server 20 by the air reservoir D, even if germs are generated in the beverage server 20, the germs can be prevented from being mixed into the beverage container 10.

  The “shape of the supply flow path and the air chamber housing 3” here includes the inner diameter of the supply flow path (particularly the diameter of the outlet of the supply flow path) and the inner diameter of the air chamber A of the air chamber housing 3, The shape of the flow path (for example, the shape of the elastic tube 2) and the shape of the air chamber A (for example, a cylindrical shape having a step portion 3b) are also included.

  In addition, in said embodiment, although the connector 4 was comprised as a non-return valve, this invention is not limited to this. For example, the connector 4 may be a seal member (for example, a laminate including an aluminum foil) that seals the opening at the lower end of the air chamber housing 3. In this case, when the connector 4 is mounted on the beverage server 20, the sharpened upper end of the receiving member 22 breaks through the seal member, so that the connector 4 is fitted with the receiving member 22.

  Moreover, in said embodiment, although the air chamber housing 3 was connected to the drink container 10 via the elastic tube 2, this invention is not restricted to this, Another embodiment which does not use an elastic tube is also assumed. Is possible. For example, the air chamber housing 3 may be directly connected to the beverage container 10. In this case, the connection part 12a of the cap part 12 and the connection part 3a of the air chamber housing 3 directly communicate with each other to form a supply flow path. In addition, the cap part 12 and the air chamber housing 3 may be integrally formed as one member.

  Alternatively, a supply channel may be provided in the air chamber housing 3. FIG. 7: has shown sectional drawing of the connection structure 1A of the drink container for drink servers which concerns on another embodiment. As shown in FIG. 7, the air chamber housing 3 is inserted into the spout portion 11, and a tubular member 8 is fitted to the spout portion 11 so as to fix the air chamber housing 3.

  As shown in FIG. 7, the air chamber housing 3 is provided with a cylindrical portion 3 c so as to protrude from the upper surface toward the internal air chamber A. The cylindrical portion 3c is a supply flow path, and the inner diameter of the cylindrical portion 3c is smaller than the inner diameter of the air chamber A. The cylindrical portion 3 c communicates with the air chamber A, and the beverage in the beverage container 10 flows out into the beverage server 20 through the inside of the cylindrical portion 3 c, the air chamber A, and the connector 4.

  In the present invention, the supply flow path can be formed in the air chamber housing 3 like the cylindrical portion 3c. Further, the supply flow path may be formed by a through hole (supply hole) provided in the upper surface of the air chamber housing 3 instead of the cylindrical shape protruding into the air chamber A. A plurality of cylindrical portions 3c or the above supply holes may be provided.

  The valve body 7 may be provided with a flow hole 7b as shown in FIG. This flow hole 7b is for securing a certain amount of beverage flow. In a state where the valve body 7 is pushed up, the width of the flow path is narrowed and the flow rate may be reduced. However, by providing the flow hole 7b in the valve body 7, regardless of the opening degree of the valve. A predetermined flow rate can be ensured.

  Moreover, the drink container 10 and the connection structure 1 are normally conveyed as a drink container with a connection structure connected to each other. For this reason, a cap or the like that protects the connector 4 is connected to the connection structure 1 so that the protruding portion of the valve body 7 is not pushed when the valve body 7 comes into contact with any object during transportation and the beverage 15 does not flow out. May be provided.

  Based on the above description, those skilled in the art may be able to conceive additional effects and various modifications of the present invention, but the aspects of the present invention are not limited to the above-described embodiments. Various additions, modifications, and partial deletions can be made without departing from the concept and spirit of the present invention derived from the contents defined in the claims and equivalents thereof.

1,1A Beverage container connection structure 2 for beverage server Elastic tube 3 Air chamber housing 3a Connection portion 3b Step portion 3c Cylindrical portion 4 Connector 5 Engaging member 6 Energizing member 6a Base end portion 6b Tip portion 7 Valve body 7a Projection Part 7b Flowing hole 8 Tubular member 8a Valve seat part 8b Outer edge part 10 Beverage container 11 Spout part 12 Cap part 12a Connection part 13 Body part 15 Beverage 20 Beverage server 21 Body part 22 Receiving member 22a Contact part 23 Beverage extraction path 25 Beverage 26 Residual water A Air chambers B1 and B2 Flow path C Recess D Air pool

Claims (6)

A beverage container for a beverage server, comprising: a beverage server that provides a beverage by a user's operation; and a beverage container that houses the beverage and is installed on the beverage server and supplies the beverage to the beverage server. A connection structure,
A supply channel for distributing the beverage from the lower part of the beverage container;
An air chamber housing formed therein with an air chamber communicating with the supply flow path;
A connector provided at a lower portion of the air chamber housing and fitted with a receiving member provided in the beverage server;
With
In the state before connecting the beverage container to the beverage server, an air reservoir exists in the air chamber,
In the state of use in which the inner diameter of the air chamber is larger than the inner diameter of the supply flow path and the beverage container is connected to the beverage server via the connector, the beverage server is providing or stopping serving. The flow rate of the beverage flowing out from the air chamber to the beverage server via the connector is equal to or higher than the flow rate of the beverage flowing out of the supply flow channel into the air chamber. A structure for connecting a beverage container for a beverage server, wherein an air pocket continues to exist . When the flow rate of the beverage supplied from the beverage server is 1 to 2 liters / minute, the inner diameter of the supply flow path is 5 mm to 12 mm, and the inner diameter of the air chamber housing is 25 mm to 40 mm. The connection structure of a beverage container for a beverage server according to claim 1.   The connection structure for a beverage container for a beverage server according to claim 1, wherein at least a part of the supply flow path is formed of an elastic tube that can be elastically deformed. The connector is
An engagement member provided therein with a first flow path through which the beverage supplied from the beverage container circulates;
A biasing member having a base end supported by the engagement member;
A valve body connected to the tip of the biasing member;
A cylindrical member in which a second flow path through which the beverage circulates is provided, and a valve seat for seating the valve body in a sealable manner is provided on an inner peripheral surface;
Have
The engaging member is configured so that the valve body and the biasing member are inserted into the cylindrical member, and the valve body is biased toward the valve seat by the biasing member. The connection structure of a beverage container for a beverage server according to any one of claims 1 to 3, wherein the connection structure is fixed to the beverage server. A protrusion is provided at the lower end of the valve body of the connector,
The receiving member of the beverage server is provided with a contact portion,
When the connector is fitted to the receiving member, the protrusion comes into contact with the contact portion, whereby the protrusion is pushed up against the urging force of the urging member, and the valve body is The beverage container connection structure for a beverage server according to claim 4, wherein the connection structure is separated from the valve seat portion of the member. A connection structure according to any one of claims 1 to 5,
A beverage container connected to the connection structure via the supply channel;
A beverage container with a connection structure, comprising:

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