KR20110016375A - Liquid storage device - Google Patents

Abstract

PURPOSE: A liquid storage device is provided to effectively maintain quality since gases collected on the top of a liquid storage tank and gases inside a connection pipe can be discharged. CONSTITUTION: A liquid storage device comprises a storage tank(T:5), and a discharge pipe(3). The storage tank comprises a space for storing liquid(w). A discharge pipe is drawn from the inside of the storage tank to the outside of the storage tank. The discharge pipe comprises a main pipe(12) and a guiding pipe part(14). The main pipe comprises an opening(13) formed within the storage tank. The guiding pipe part is branched from the main pipe and is placed toward the top of the storage tank. A pocket portion(11) projected upward on the inner top of the storage tank is installed.

Description

LIQUID STORAGE DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid storage device used for storing and storing a beverage or other various liquids such as water by carrying out constant temperature control.

In order to store and store beverages, such as water, or other various liquids by carrying out constant temperature control, liquid storage devices including storage tanks for various devices, various facilities, and the like are used.

As such a liquid storage device, for example, the supply water from the outside such as tap water may be once moved into the storage tank, where the temperature is controlled and stored therein, and then the supply water can be supplied to the outside as necessary when necessary. .

In this type of liquid storage device, since the discharge pipe is drawn out from the storage tank, and the supply valve is provided in the discharge pipe, the supply amount to the outside can be appropriately adjusted by opening and closing the supply valve.

In addition, as an example of the liquid storage device, there is also a beverage server that allows the beverage to be supplied to the storage tank from a detachable container.

In this beverage server, a container containing a beverage such as mineral water is used, and the beverage in the container is transferred to a storage tank provided in the server body for storage, and then the stored beverage is stored at room temperature or cold temperature, or the stored beverage. Is heated so that it can be supplied to a suitable cup or PET bottle.

For example, as shown in patent document 1, in the storage tank T, there exists a server for beverages of the airless tank structure which made it difficult for the drinking water w and air a to contact.

In this beverage server, when the beverage (w) is injected into the storage tank (T) from the container (1) through the water pipe (6) as shown in FIG. 6, the beverage is reduced with the decrease of the internal beverage (w). A container 1 composed of a deformable flexible film is used.

At this time, in order to suppress that the drinking water w in the storage tank T contacts the air a, it can be set as the structure which discharges the drinking water w from the upper part of the storage tank T, for example.

However, especially in the tank structure etc. which require temperature management, such as a cold water tank, it may be necessary to set it as the structure which discharges the drinking water w from the lower part of the storage tank T.

When the drinking water w is discharged from the lower part of the storage tank T, even if it is an airless tank structure, the container 1 into which the drinking water w entered in the state in which the storage tank T was empty at the time of initial use may be a water pipe ( 6)), and when air (a) is mixed into the storage tank (T) during its use, a layer of air (a) is formed on the top of the beverage (w), and the beverage (w) and the air ( a) continues to be in contact.

Therefore, as shown in FIG. 6, it is effective to provide the exhaust valve 2 as an exhaust means in the upper part of the storage tank T. As shown in FIG.

Examples of the exhaust valve 2 include those shown in Figs. 7A and 7B. When the air a is discharged out of the storage tank T by manually operating the exhaust valve 2, The drinking water w flows down the storage tank T through the water pipe 6 so as to fill the void after the discharge (see Patent Document 1, for example).

(Prior art document)

(Patent literature)

[Patent Document 1]: Japanese Unexamined Patent Publication No. 2009-35322

According to the beverage server 10, when the exhaust valve 2 installed as the exhaust means of the storage tank T is no longer functioning due to a failure or the like, the beverage w continues to leak from the exhaust valve 2. Is assumed.

Moreover, since the exhaust valve 2 has a movable part, there is also a problem that regular maintenance is necessary for the movable part to function reliably.

Therefore, an object of the present invention is to make the exhaust means provided in the storage tank of the liquid storage device less trouble and less need for maintenance.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, this invention draws out a discharge pipe out of the said storage tank from inside the storage tank which has a space which can store a liquid inside, and can discharge the liquid in the said storage tank out of the said storage tank through the discharge pipe. In the liquid storage device, the discharge pipe includes a main pipe portion having an opening into the storage tank and a guide pipe portion branched from the main pipe portion and directed upward in the storage tank, and through the discharge pipe. When discharging the liquid received from the opening of the main pipe portion out of the storage tank, has a function of sucking the gas interposed in the upper portion of the storage tank through the induction pipe portion and simultaneously discharging the liquid out of the storage tank; Recall the amount of liquid appropriate to the space in which the discharged gas A configuration of a liquid storage device, which has a function of replenishing the storage tank, is adopted.

According to these constitutions, when gas is interposed in the upper part of the storage tank, when the liquid inside is discharged to the outside through the discharge pipe, the liquid moves in the main pipe part of the discharge pipe, and the fluid flows in the main pipe part. The phenomenon in which the gas (air) interposed on the upper part of the storage tank is led to the main pipe part through the guide pipe part occurs. This action is more pronounced the faster the flow of fluid in the main body, the expected so-called capillary phenomenon (venturi effect).

By this action, the gas interposed in the upper part of the storage tank can be discharged out of the storage tank together with the liquid in the storage tank.

In addition, when the liquid in the storage tank and the gas interposed in the storage tank are discharged out of the storage tank by being drawn by the flow of the liquid in the discharge pipe, the discharged liquid and the amount of liquid appropriate to the space in which the discharged gas is interposed are stored. As a function to be replenished in the tank, a liquid supply pipe (for example, a water pipe, etc.) capable of supplying a liquid to the storage tank by adding a predetermined liquid pressure from the upstream side, for example, is connected to the opening and closing operation of the discharge pipe from the liquid supply pipe. There is a technique to automatically replenish the liquid in the reservoir tank. In addition, a separate liquid supply source (e.g., a plastic container containing a liquid), which collects a predetermined amount of liquid, is connected to the storage tank, and the negative pressure is accompanied by the drop pressure or the discharge of the liquid and gas in the storage tank. The pressure balance in the storage tank and the liquid supply source may automatically replenish the liquid from the liquid source to the storage tank.

As described above, it is possible to reduce the chance of the liquid and the gas contacting in the storage tank while reducing the failure of the exhaust means provided in the storage tank and the need for maintenance.

As the function of the guide pipe portion, the flow rate of the liquid in the discharge pipe, the length of the guide pipe portion (the length from the branch with the main pipe portion), the inner diameter of the guide pipe portion, and the like are appropriately set, thereby leaving the gas in the storage tank without leaving. It can be made to have a function to discharge | emit out of a tank. If the gas in the storage tank can be discharged out of the storage tank without remaining, the inside of the storage tank is always kept in the airless state, so that it can be in the most desirable state for quality maintenance. Moreover, it is preferable that the inner diameter of an induction pipe part is smaller than the inner diameter of a main pipe part normally.

In these configurations, when drawing gas interposed in the upper part of a storage tank through the opening part of an induction pipe part, the pocket part which protrudes upwards is provided in the upper part in the storage tank, and the opening part of the said induction pipe part exists in the said pocket part. It can be set as the structure which faced space.

If there is a pocket part, gas will collect easily in the space, and the suction of gas by the flow of the liquid which flows in a discharge pipe is also effective.

Moreover, in the structure provided with the guide pipe part in this way, the opening part of the said main pipe part faces the lower part of the said storage tank, and the said main pipe part extends upwards from the opening part, and the structure which reaches the branch with the said guide pipe part can be employ | adopted. .

If the opening of the main pipe portion is directed to the lower part of the storage tank, the liquid in a relatively low temperature state is mainly discharged with respect to the temperature difference between the upper part and the lower part in the storage tank, so that the relatively mixed gas is introduced from the induction pipe part in the absence of gas. The temperature rise which may be caused by mixing with the liquid at the top of the tank in the high temperature state can be reduced.

In addition, when a structure for transferring a liquid from the storage tank to a separate secondary tank or the like (for example, a tank having a heating function installed under the storage tank) is required, the pipe for transferring the liquid is It is preferable that the position withdraw | derived from a storage tank is higher than the position of the opening part of the said main pipe part, and it is lower below a certain distance than the opening part of the guide pipe part. This is because when the opening of the main pipe portion is positioned below the storage tank, it is less likely to be affected by the secondary tank in terms of temperature management, and the air mixing into the secondary tank can be reduced by making the opening of the guide pipe portion upward.

Moreover, the said main pipe part extends downward from the branch with the said guide pipe part, and can employ | adopt the structure drawn out of the said storage tank.

The main pipe portion of the discharge pipe extends once from the bottom of the storage tank, and is arranged so as to return from the top of the storage tank to the bottom, and the guide pipe portion is provided at the top thereof, whereby the branch between the main pipe portion and the guide pipe portion is in the longitudinal direction of the main pipe portion. The middle, the easier it is to arrange. As a result, when discharging the fluid from the discharge pipe out of the storage tank, the flow velocity of the liquid near the branch with the guide pipe portion is stabilized, and the dropping pressure at the time of discharge can be increased by the structure which is drawn out from the lower part of the tank. The suction phenomenon of the gas generated in the tube portion can be promoted.

In addition, the above-described opening of the main pipe portion is directed toward the lower portion of the storage tank, and the main pipe portion extends upward from the opening to reach the branch with the guide pipe portion, and the main pipe portion extends downward from the branch with the guide pipe portion, and is drawn out of the storage tank. Although each structure is effective alone, it is effective for the acceleration | stimulation of the suction phenomenon of the said gas, and stabilization of supply temperature, but it is preferable to have both.

The liquid storage device which consists of these structures can be used as a server for drinking water. The configuration may be configured such that a container containing liquid therein is detachable to a water pipe extending upward from the storage tank, and that the liquid in the container flows into the storage tank through the water pipe. .

In this beverage server, a container containing a beverage, for example, a container made of a hard material on the premise that the container does not deform when the internal beverage decreases and gas enters instead of the beverage. In the case of employ | adopting, it can be set as the structure which attached the intake apparatus for containers (for example, the intake opening extended upward from a check valve or a container) between a storage tank and a container. This structure is based on the premise of improving the quality in the liquid storage device, and may be provided with a sterilization mechanism of another intake device for the purpose of maintaining the quality of the container.

It is formed of a flexible material, and when the beverage in the container flows into the storage tank through the water pipe and the beverage in the container decreases, the container shrinks and deforms so that gas does not enter the inside from the water pipe side. A container may be employed.

That is, when the liquid in the storage tank and the gas interposed in the storage tank are discharged out of the storage tank by being drawn by the flow of the liquid in the discharge pipe, the amount of liquid appropriate for the discharged liquid and the space in which the discharged gas is interposed It is necessary to have a function to replenish the storage tank.

Moreover, the liquid storage device which consists of these structures can be applied to the server for beverages which consists of the following structures.

That is, the structure has the 1st tank which can store a liquid inside, and installs a 2nd tank below in parallel, and connects the 1st communication pipe | tube drawn out from the said 1st tank to a storage tank, and the liquid in a said 1st tank Is supplied to the storage tank, and the second communication tube drawn out from the storage tank is connected to the second tank so that the liquid in the storage tank is discharged out of the storage tank through the second communication tube to discharge the liquid. The second communication pipe has a main pipe portion having an opening into the storage tank, and a guide pipe portion branched from the main pipe portion and directed upward in the storage tank, and supplied through the second communication pipe. When the liquid received from the opening of the main pipe portion is discharged out of the storage tank, an image in the storage tank is passed through the guide pipe portion. And a function of simultaneously discharging the gas interposed into the storage tank out of the storage tank, and replenishing the discharge liquid and the liquid in an appropriate amount in the storage tank from the first tank to the storage tank. It is a server for drinks.

According to these structures, when gas is interposed in the upper part of a storage tank, when a liquid inside is discharged | emitted outside (to a 2nd tank side) through a 2nd communication tube, a liquid will move in the main part of the 2nd communication tube. Then, due to the pressure balance of the liquid, a phenomenon in which gas (air) interposed on the upper portion of the storage tank is led through the induction pipe part occurs. By this action, similarly to the above-described respective structures, the gas interposed on the upper portion of the storage tank can be discharged out of the storage tank together with the liquid in the storage tank.

Also, when the liquid in the storage tank and the gas interposed in the storage tank are discharged out of the storage tank by being drawn by the flow of the liquid in the discharge pipe, the amount of liquid appropriate for the discharged liquid and the space in which the discharged gas is interposed is removed. 1 tank is replenished in the storage tank.

Moreover, it is conventionally common that a 1st tank located upwards among a 1st tank and a 2nd tank is used for cold water supply or normal temperature water supply, and a 2nd tank located below is used for hot water supply. When the first tank located above is for cold water supply, a cooling device is provided in the first tank, and when the second tank located below is for hot water supply, a heating device is provided in the second tank.

By interposing such a storage tank between the first tank and the second tank, the liquid (drink water) warmed by the heating device is supplied to the tank for cold water supply or normal temperature water supply, and the liquid cooled by the cooling device is supplied with hot water. It is possible to suppress the calorific loss (fuel loss) and the quality maintenance performance that affect the tank of the dragon.

Functioning in this way, compared with the case where the first tank and the second tank are connected in a vertical pipe in the vertical direction, the hot water rising by making the pipe in an S-shape, that is, once the pipe is lowered again and made again The reason for this is that it becomes a shape that inhibits the fusion of cold water falling with and falling. At this time, there is a possibility that gas may be mixed in the pipe, but by adopting the configuration of the storage tank, the mixed gas can be discharged to the second tank side together with the liquid, and also reduced in space and both temperatures. It becomes the structure which can suppress inhibition of a phase.

With the above configuration, it is possible to reduce the chance of contact between the liquid and the gas in the storage tank and to reduce the failure of the exhaust means provided in the storage tank and to reduce the need for maintenance.

As the function of the induction pipe portion, the flow rate of the liquid in the discharge pipe, the length of the induction pipe portion (the length from the branch with the main portion), the inner diameter of the induction pipe portion, and the like are appropriately set as in the above-described configuration. The gas can be discharged out of the storage tank without leaving any gas. If the gas in the storage tank can be discharged out of the storage tank without remaining, the inside of the storage tank is always kept in the airless state, so that it can be in the most desirable state for quality maintenance. Moreover, it is preferable that the inner diameter of an induction pipe part is smaller than the inner diameter of a main pipe part normally.

In these configurations, when drawing gas interposed in the upper part of a storage tank through the opening part of an induction pipe part, the pocket part which protrudes upwards is provided in the upper part in the storage tank, and the opening part of the said induction pipe part exists in the said pocket part. It can be set as the structure which faced space.

If there is a pocket part, gas will collect easily in the space, and the suction of gas by the flow of the liquid which flows in a discharge pipe is also effective.

Moreover, in the structure provided with the guide pipe part in this way, the opening part of the said main pipe part faces the lower part of the said storage tank, and the said main pipe part extends upwards from the opening part, and the structure which reaches the branch with the said guide pipe part can be employ | adopted. .

Moreover, the said main pipe part extends downward from the branch with the said guide pipe part, and can employ | adopt the structure drawn out of the said storage tank.

By arranging the main part of the second communication pipe to extend from the lower part of the storage tank to the upper part and returning from the upper part of the storage tank to the lower part, and providing an induction pipe part on the top thereof, the branch of the main part and the induction pipe part is separated from the main part. The longer the middle, the easier the arrangement. As a result, when the fluid is discharged from the second communication pipe out of the storage tank, the flow velocity of the liquid near the branch with the guide pipe portion is stabilized, and the dropping pressure at the time of discharge can be increased by the structure which is drawn out from the lower part of the tank. The suction phenomenon of gas generated in the induction pipe part can be promoted.

In addition, the above-described opening of the main pipe portion is directed toward the lower portion of the storage tank, and the main pipe portion extends upward from the opening to reach the branch with the guide pipe portion, and the main pipe portion extends downward from the branch with the guide pipe portion, and is drawn out of the storage tank. Although the structure which exists alone is effective for the acceleration | stimulation of the suction phenomenon of the said gas, and stabilization of supply temperature, respectively, it is preferable to have both.

In addition, in the structure of the beverage server which interposed the storage tank between a 1st tank and a 2nd tank in this way, the gas by the discharge pipe which consists of each structure which each or one of the 1st tank and the 2nd tank mentioned above is comprised. It is good also as a liquid storage device provided with a discharge function. That is, it is good also as a structure of the storage tank of the liquid storage device which consists of each structure provided with the gas discharge function mentioned above for a 1st tank or a 2nd tank.

In addition, by applying these configurations, the conventional cold and hot water server having a cold water tank (including a tank storing at room temperature) that stores liquid such as water in a cold state and a hot water tank that stores the same in a warmed state Therefore, it is also possible to make the structure which the cold water tank in the upper part which is the basic structure, and the hot water tank in the lower part reverse up and down, and arrange | position the hot water tank in the upper part and the cold water tank in the lower part.

On the other hand, conventionally, the cold water tank and the hot water tank are arranged in the upper part because the discharge port (outlet of the discharge pipe) needs to be provided in the upper part of the tank in gas management in the hot water tank. When the discharge port of the hot water tank was located in the upper part of the tank, the hot water tank was inevitably disposed below. This is because the location of the outlet should be at a height convenient for the user standing on the floor.

For example, if the hot water tank is arranged above the cold water tank and a discharge port is provided only below the hot water tank, when a large amount of gas is interposed in the upper part of the hot water tank, there are factors such as heating accidents in an empty state. This is because it becomes.

However, a liquid storage device having a gas discharge function by the discharge pipe having the above-described configuration, that is, a configuration in which a guide pipe portion is provided in the main pipe portion of the discharge pipe, and the guide pipe portion faces the upper portion of the storage tank. By adopting the hot water tank of the tank, it is possible to eliminate the need to install the outlet (outlet of the discharge pipe) in the upper portion of the tank.

That is, since the discharge pipe can be taken out from the bottom of the hot water tank, the hot water tank can be installed above the cold water tank without any problems. As a result, the high temperature tank having the correct temperature balance can be arranged at the top and the low temperature tank at the bottom, so that the component placement application of the device can be expanded, and the compactness and the high efficiency can be achieved.

Moreover, the following method can be employ | adopted as the exhaust method of the gas mixed in the storage tank using the liquid storage device which consists of these structures, and the drainage method at the time of use of a storage tank, or maintenance.

That is, the second communication tube includes a main pipe portion having an opening into the storage tank and an induction pipe portion branched from the main pipe portion and directed upward in the storage tank, and the liquid received from the opening of the main pipe portion outside the storage tank. At the time of discharge, the gas interposed in the upper part in the storage tank is sucked and simultaneously discharged out of the storage tank. Moreover, in order to discharge all the liquid in a storage tank at the time of completion | finish of use and maintenance, the drainage | exhaust / drainage method of the storage tank of a liquid storage device characterized by providing the drain port in the lowest part in the tank of a main part.

The present invention uses the flow of the liquid in each water pipe, so that the gas collected in the upper portion of the storage tank and the gas in the communication tube of the tank tube can be discharged, thereby reducing the chance of liquid and gas contact in the storage tank, It can be made into a preferable state on fats and oils. In addition, the movable part can be eliminated by using the flow of liquid in the discharge pipe when the gas is discharged, and it can be used as an exhaust means having less trouble and less maintenance, and can also improve temperature management and fuel efficiency. to be.

Embodiment of this invention is described based on drawing. The beverage server 20 having the liquid storage device of the present embodiment has a water pipe extending upward from the storage tank T having a space in which the beverage (liquid) w can be accommodated as shown in FIG. 1A. The container 1 made of resin is detachable to (6). By attaching the container 1 to the water pipe 6, the beverage w in the container 1 flows down into the storage tank T through the water pipe 6 by its own weight. In addition, the storage tank T is equipped with the cooling device which is not shown in figure. Hereinafter, this storage tank T is called "cold water tank 5."

In the present embodiment, the container 1 is formed of a flexible material, so that the beverage w in the container 1 flows into the cold water tank 5 through the water pipe 6 and the container ( When the drinking water w in 1) decreases, the container 1 shrinks and deforms so that the volume of the inside decreases, so that air (gas) a does not enter the inside of the water pipe 6. have.

This container 1 and the cold water tank 5 are accommodated in the container storage part 21 and the main body 22 of the server 20 for beverage shown in FIG. 3, respectively.

Referring to the configuration of the liquid storage device, as shown in FIG. 1A, the discharge pipe 3 is drawn out of the cold water tank 5 as the storage tank T, extends out of the main body 22, and the discharge pipe 3 is connected to the discharge pipe 3. The supply valve 7 which opens and closes freely is provided.

When the supply valve 7 is opened, the drinking water w in the cold water tank 5 can be appropriately supplied to an external cup, a container such as a PET bottle, and the supply is stopped when the supply valve 7 is closed. Opening and closing of the supply valve 7 can be performed by operating a lever as shown in FIG. 3, for example.

In the present embodiment, another tank 5 '(hereinafter referred to as "hot water tank 5'") is provided below the cold water tank 5, and is distinguished from the upper cold water tank 5. have.

The hot water tank 5 'is provided with a space for accommodating the beverage w therein, and is provided with a heating device (not shown) to store the beverage w in the warm state.

This hot water tank 5 'is also housed inside the main body 22 of the beverage server 20. A discharge pipe 3 'is drawn out from the hot water tank 5' and extends out of the main body 22, and a supply valve 7 'freely opened and closed is provided in the discharge pipe 3'.

When the supply valve 7 'is opened, the warmed beverage w in the hot water tank 5' can be appropriately supplied to a container such as an external cup or a plastic bottle, and the supply is closed when the supply valve 7 'is closed. The stopping point is the same as in the case of the cold water tank 5.

The cold water tank 5 and the hot water tank 5 'are connected by a communication tube 8. The communicating tube 8 is connected to the upper part of the said cold water tank 5, and the lower part of the hot water tank 5 ', and is provided with the opening-closing valve 8a in the middle.

The drinking water w in the cold water tank 5 flows into the hot water tank 5 'by its own weight through the communicating tube 8.

In addition, in this embodiment, in order to minimize the heat influence from the hot water tank 5 'with respect to the drink water w in the cold water tank 5, the communication tube 8 is withdrawn from the upper part of the cold water tank 5, and the hot water tank is carried out. It connects to the lower part of 5 ', and ensures the length long enough. In the cold water tank 5, the partition plate 5b is disposed near the opening of the communication tube 8, and, for example, when the beverage w flows back from the hot water tank 5 ', the beverage w is It does not spread widely throughout the cold water tank 5. Moreover, in order to prevent generation | occurrence | production of the retention water in the communication pipe 8, the said switching valve 8a is provided near the upper end of the communication pipe 8. As shown in FIG.

Moreover, the cold water tank 5 is equipped with the pocket part 11 which protrudes upwards at the upper end. By this pocket part 11, the space in the cold water tank 5 has the space which protrudes upward more than the upper surface of the cold water tank 5 at the top. That is, the space in this pocket part 11 is located most upward in the cold water tank 5. In the present embodiment, the upper surface of the cold water tank 5 is closed by a cover 5a having a flat lower surface as shown in FIG. 1A, and the inner surface of the pocket portion 11 protrudes upward with respect to the flat lower surface. . Moreover, the flat lower surface is an inclined surface which gradually rises as it approaches the pocket portion 11, and has a function of guiding air a to the pocket portion 11.

In addition, in this embodiment, although the pocket part 11 is integrally provided in the cover 5a which opens and closes which closes the upper surface of the cold water tank 5, the pocket part 11 may be provided in the cover 5a in this way. If the cover 5a is not provided, the cover 5a may be integrally provided with the upper surface of the tank. Hereinafter, it is the same in the storage tank T of each embodiment.

The discharge pipe 3 for supplying the drinking water w to the outside is provided with a main pipe part 12 having an opening 13 into the cold water tank 5 and upward from the main pipe part 12 as shown in FIG. 1A. It is provided with a guide pipe portion 14 branched toward the space in the pocket portion 11.

The induction pipe part 14 is a pipe having an inner diameter smaller than that of the main pipe part 12, and the cold water tank receives the drinking water w opened from the opening 13 of the main pipe part 12 by opening the supply valve 7. (5) When discharged out, the air a in the pocket 11 is sucked by the so-called Venturi effect by the flow of the beverage water w in the main portion 12, and at the same time the cold water tank 5 ) Has the function of ejecting out. That is, as shown by the arrow v1 in FIG. 1B, when the flow of the beverage water w in the main pipe part 12 occurs, the suction force in the direction of the arrow y acts on the guide pipe part 14 by the flow, and as a result, induction Air a is drawn in from the opening 14a of the pipe part 14.

Moreover, in this embodiment, the said opening part 13 of the said main pipe part 12 faces the lower part of the said cold water tank 5, and the said main pipe part 12 is a distance from the opening part 13 as a rising part 12a straight. extending upward by h3, bent at an almost touching position on the upper surface of the cold water tank 5 (equivalent to the lower surface of the lid 5a), and then becoming a horizontal portion 12b to extend horizontally by a distance h2 have. The branch r with the induction pipe part 14 is provided in the middle of this horizontal part 12b.

The main pipe portion 12 extends downwardly as a lower portion 12c straight down from the horizontal portion 12b having the branch r with the guide pipe portion 14 by a distance h1, after which the cold water tank 5 It is drawn out. The rising height hO of the induction pipe part 14 from the branch r to the upper end opening 14a is set sufficiently small with respect to the distances h1 and h3.

The operation of the beverage server 20, that is, the method of evacuating the air a mixed into the cold water tank 5 using the beverage server 20 will be described.

As shown in Fig. 2 (a), in a state where there is no drink water w in the cold water tank 5, the container 1 is inserted into the water pipe 6 to fix the container 1. 2, illustration of the lower part of hot water tank 5 'is abbreviate | omitted.

The beverage w in the container 1 gradually flows into the cold water tank 5 by its own weight, and the container 1 shrinks and deforms so that the volume of the internal space thereof is reduced (see FIG. 2 (b)). ).

At this time, when the air pressure in the cold water tank 5 becomes high, the flow of the drinking water w from the container 1 to the cold water tank 5 is stopped at a certain place, but by opening the supply valve 7 appropriately, the cold water The air a in the tank 5 is discharged to the outside, and the rise of the air pressure in the cold water tank 5 can be controlled. At this time, since the position in the cold water tank 5 of the horizontal part 12b is high (distance h3 from the bottom part of the cold water tank 5), it can prevent that drinking water w is discharged in large quantities.

As the beverage water w flows down, the beverage water w in the cold water tank 5 gradually raises the water level, and finally, the water level reaches the upper surface of the cold water tank 5 as shown in FIG. .

At this time, air a remains in the space in the pocket part 11. This is because the space in the pocket portion 11 is located most upward in the cold water tank 5.

Here, the supply valve 7 is opened, and the drinking water w received from the opening 13 of the main pipe part 12 is discharged out of the cold water tank 5. By discharging the beverage w, the beverage w moves in the discharge pipe 3, i.e., the main pipe portion 12, and is attracted to the flow, and the air in the pocket 11 is led through the guide pipe portion 14. A phenomenon in which (a) is attracted (see arrow y in FIG. 1B) occurs, and as a result, the air a in the cold water tank 5 can be discharged out of the cold water tank 5 without leaving it.

As a result, the air a remaining in the cold water tank 5 is eliminated. As a result, the opportunity for the drinking water w to come in contact with the air a can be reduced, and the state can be brought into a desirable state in terms of quality maintenance and hygiene. Moreover, since the induction pipe part 14 as an exhaust means does not have a movable part like a conventional exhaust valve, it can be used as an exhaust means with few troubles and little maintenance.

In this embodiment, the main part 12 of the discharge pipe 3 has the opening part 13 in the cold water tank 5 facing downward in the lower part of the cold water tank 5, and the main part 12 is the opening part. It extends upward from (13) (rising part 12a) and reaches the branch r with the induction pipe part 14 (horizontal part 12b), and after that, the main pipe part 12 extends downward (lower part). (12c)) It was set as the structure drawn out from the cold water tank 5.

However, the structure of the main pipe part 12 of the discharge pipe 3 is not limited to this embodiment, and the induction pipe part 14 branched from the main pipe part 12 exhibits the above-mentioned suction effect, and the pocket part 11 is carried out. If it has a function which can discharge the gas (a) inside, it can arrange | position in free form.

For this reason, for example, rather than providing the opening part 13 near the bottom part of the cold water tank 5, the said rising part 12a is abbreviate | omitted or shortened (the said distance h3 is shortened), and the said opening part ( The shape of the 13 opening in the height direction intermediate | middle or relatively upper part in the cold water tank 5, or the lower part 12c is abbreviate | omitted or shortened (shortening the said distance h1), and the discharge pipe 3 is a cold water tank. The form etc. which are drawn out from the comparatively upper part of (5) outside are also considered.

However, if the branch r between the main pipe part 12 and the induction pipe part 14 is too close to the opening 13, the flow rate of the beverage w in the vicinity of the branch r is not stable and air Since the suction force may weaken, it is preferable that the branch r between the main pipe part 12 and the guide pipe part 14 is not too close to the opening 13. On the contrary, if the branch r between the main pipe portion 12 and the induction pipe portion 14 is too close to the supply valve 7, the flow rate of the beverage w in the vicinity of the branch r is not stable, and air Since the suction force may be weakened, it is preferable that the branch between the main pipe part 12 and the induction pipe part 14 is not too close to the supply valve 7.

In addition, it is preferable that the position of the supply valve 7 provided in the discharge pipe 3 generally is the height which a person handling it is easy to operate. In addition, a space for placing a cup or a PET bottle under the supply valve 7 is required. Moreover, it is necessary to load the container 1 which is a supply source of beverage water w in the upper part of the cold water tank 5.

In this regard, in particular, assuming that the beverage server is mounted on a table such as a desk or a table, the position of the supply valve 7 is preferably a height that is easy for a person standing on the floor to operate. Therefore, a space for placing a cup, a PET bottle, or the like under the supply valve 7 is required. For this reason, in the case of a tabletop drinking water server, it was common that the position of the supply valve 7 necessarily becomes a position higher than a predetermined distance above the mounting surface on the desk or table.

However, in the conventional beverage server 10, the discharge pipe 3 for supplying the beverage w to the outside is configured to be drawn out from the bottom of the cold water tank 5 (for example, a conventional example is shown. 6, the cold water tank 5 must be disposed above the supply valve 7 installed in the discharge pipe 3. For this reason, there existed a problem that the beverage server 10 was enlarged (the height of apparatus became high). Since the height of the supply valve 7 is limited to the height which is easy to operate, the height corresponding to a cup, a PET bottle, etc., the position of the cold water tank 5 will also become high. Moreover, when the position of the cold water tank 5 becomes high, since the loading position of the container 1 also becomes high, the situation in which the container 1 cannot be attached or detached easily is also assumed.

In that respect, according to the structure of this invention, when the discharge pipe 3 has passed through the said branch part r of the main pipe part 12, the withdrawal position out of the cold water tank 5 is free. For this reason, as described above, the discharge pipe 3 can be drawn out to the outside in the upper portion of the cold water tank 5 by omitting or shortening the length 12c (shortening the distance h1). . For this reason, the position of the supply valve 7 with respect to the cold water tank 5 can be made high compared with the case of the conventional drink server 10. In other words, this makes it possible to downsize the server for beverages 20. By miniaturizing the apparatus, the loading position of the container 1 can be set low, and as a result, the container 1 can be easily attached or detached.

This effect is similarly effective also in the other embodiments shown below in addition to this embodiment, and is especially effective in the table-top beverage server 20 mounted on a table, such as a desk or a table, and used.

For example, as shown in FIG. 4, in the vicinity of the branch r between the main pipe part 12 and the guide pipe part 14, the branch r is made smaller by the inner diameter of the main pipe part 12 than before and after. It is possible to increase the flow rate (flow velocity in the direction of the arrow v1 in the drawing) of the beverage w in the vicinity. As this flow velocity increases, the suction force (the suction force in the arrow y direction in the figure) of the air a acting through the induction pipe portion 14 also increases.

In addition, in this embodiment, in order to make the inner diameter of the main pipe part 12 smaller than front and back in the vicinity of the branch r between the main pipe part 12 and the guide pipe part 14, as shown in FIG. The bulging part 12d is provided in the surface of the side in which the guide pipe part 14 branches among the inner walls of 12). The bulging part 12d is provided in both the upstream side and the downstream side with the guide pipe part 14 fitted. According to this structure, it is effective in raising the flow velocity in the vicinity of branch r.

In addition, the installation of the hot water tank 5 'is abbreviate | omitted, and the structure which provided only the cold water tank 5 to supply the drinking water w can also be implemented. At this time, the cold water tank 5 is similar in that it functions as the storage tank T of a liquid storage device.

Another embodiment is shown in FIG. 5A. In this embodiment, since the main structure is the same as the above-mentioned embodiment, description is abbreviate | omitted and it demonstrates below centering on difference with the above-mentioned embodiment.

As described above, the beverage server 20 is provided with an intermediate tank 15 in the middle of a communication tube 8 connecting the cold water tank 5 and the hot water tank 5 'as shown in FIG. 5A. It is different from form.

The discharge function of the gas a in the cold water tank 5 is the same as the above-mentioned embodiment, and the beverage water w is discharged through the discharge pipe 3 withdrawn from the cold water tank 5. By discharging outside, the air a mixed in the cold water tank 5 is sucked by the flow of the drinking water w in the discharge pipe 3, and the air a is discharged to the outside.

Moreover, in this embodiment, the said intermediate tank 15 provided in the middle of the communication pipe 8 also has the function of discharging air a.

That is, in addition to making the cold water tank 5 function as the storage tank T of the liquid storage device which has the discharge function of the gas a, the intermediate tank 15 also has the liquid storage which has the discharge function of the gas a. It functions as the storage tank T of an apparatus.

Hereinafter, the cold water tank 5 is called the 1st tank 5 and the hot water tank 5 'is called the 2nd tank 5'. The 1st tank 5 and the 2nd tank 5 'are provided in parallel in the up-down direction.

The first communication pipe 8b drawn out from the first tank 5 extends downward and is connected to communicate with the inner space through the lid 15a of the intermediate tank 15. The lower end of the first communication tube 8b opens downward in the lower portion of the intermediate tank 15. The beverage w in the first tank 5 is supplied to the intermediate tank 15 through the first communication tube 8b.

In this embodiment, in order to minimize the heat effect from the 2nd tank 5 ', the point which draws out the communication pipe 8 from the upper part of the 1st tank 5 is the same as that of embodiment mentioned above.

Moreover, the 2nd communication tube 8c is pulled out from the intermediate tank 15, and this 2nd communication tube 8c is connected so that it may communicate with the space in the said 2nd tank 5 '.

That is, the second communication tube 8c is branched upwardly from the main portion 17 having an opening 18 into the intermediate tank 15, as shown in FIG. 5A, and the intermediate portion 15c. The guide pipe part 14 which faces the space of the upper part in the tank 15 is provided.

The induction pipe part 14 is a pipe having an inner diameter smaller than that of the main pipe part 17, and when discharging the drinking water w received from the opening 18 of the main pipe part 17 toward the second tank 5 '. By the flow of the beverage water w in the main pipe 17, the air a in the intermediate tank 15 is sucked and discharged out of the intermediate tank 15 at the same time. That is, when the flow of the beverage water w in the main pipe part 17 occurs, the suction force acts downward to the guide pipe part 14 by the flow, and as a result, air (from the opening 14a of the guide pipe part 14) is applied to the air ( a) is pulled in.

As a result, the beverage w in the intermediate tank 15 is discharged out of the intermediate tank 15 through the second communication tube 8c, and the discharged beverage w is supplied to the second tank 5 '. It is supposed to be.

For example, in the full water state of the second tank 5 ', the supply valve 7' of the discharge pipe 3 'drawn out from the second tank 5' is opened and the beverage ( supply w) externally. This lowers the water level of the beverage w in the second tank 5 '. However, as the water level decreases, the drinking water w received from the opening 18 of the main pipe portion 17 from the intermediate tank 15 through the second communication pipe 8c flows into the second tank 5 '. The beverage w in the second tank 5 'is replenished in full water.

It is assumed that air a remains in the upper part of the intermediate tank 15 from now on. It is conceivable that this air a can be generated, for example, by heating of the beverage w in the second tank 5 '.

When air a is interposed in the intermediate tank 15 as described above, when the beverage w in the intermediate tank 15 is discharged out of the intermediate tank 15 toward the second tank 5 '. The air a interposed at the upper portion of the intermediate tank 15 is sucked and simultaneously discharged out of the intermediate tank 15. That is, when the beverage w is sucked into the main pipe 17 from the opening 18, the air a is sucked together with the beverage w.

In addition, according to the decrease of the beverage (w) in the intermediate tank (15) and the accompanying discharge of the gas (a), the amount of the beverage (w) suitable for the space in which the reduced beverage (w) and the gas (a) was interposed. ) Flows out from the first tank 5 through the first communication pipe 8b, and the beverage w is replenished so that the intermediate tank 15 is in a full water condition.

For this reason, the air (a) which remains in the intermediate tank 15 disappears, As a result, the opportunity to contact the drink water w and the air a can be reduced, and it can be made into the state favorable for quality maintenance and hygiene.

Moreover, the structure shown in FIG. 5B can also be employ | adopted as a structure of the main pipe part 17 and the intermediate tank 15 of the 2nd communication pipe 8c.

In the structure shown in this FIG. 5B, the intermediate tank 15 is equipped with the pocket part 11 which protrudes upward at the upper end. By this pocket part 11, the space in the intermediate tank 15 has the space which protrudes more upwards than the upper surface of the said intermediate tank 15 at the top. That is, the space in this pocket part 11 is located most upward in the intermediate tank 15. As shown in FIG. In this embodiment, the upper surface of the intermediate tank 15 is closed by the lid 15a having a flat lower surface as shown in FIG. 5B, and the inner surface of the pocket portion 11 protrudes upward with respect to the flat lower surface. . Moreover, the flat lower surface is an inclined surface which gradually rises as it approaches the pocket portion 11, and has a function of guiding air a to the pocket portion 11.

In addition, in this embodiment, although the pocket part 11 is integrally provided in the cover 15a which opens and closes which closes the upper surface of the intermediate tank 15, the pocket part 11 may be provided in the cover 15a in this way. In the case where the lid 15a is not provided, the cover 15a may be integrally provided with the upper surface of the tank.

In this configuration, the second communication tube 8c for supplying the beverage w to the outside is provided with a main portion 17 having an opening 18 into the intermediate tank 15 as shown in FIG. 5B, and The induction pipe part 14 which branches upward from the main pipe part 17 and faces the space in the said pocket part 11 is provided. This point is the same as the structure shown in FIG.

The induction pipe part 14 is a pipe having an inner diameter smaller than that of the main pipe part 17, and when discharging the drinking water w received from the opening 18 of the main pipe part 17 toward the second tank 5 '. By the flow of the drinking water w in the main pipe 17, the air a in the pocket 11 is sucked by the so-called Venturi effect and simultaneously discharged out of the intermediate tank 15. That is, as shown by the arrow v1 in FIG. 5B, when the flow of the beverage water w in the main pipe part 17 occurs, the suction force in the direction of the arrow y acts on the guide pipe part 14 by the flow. Air a is drawn in from the opening 14a of the pipe part 14.

In these embodiments shown in FIGS. 5A and 5B, the intermediate tank 15 (reservation) is similar to the cold water tank 5 (reservation tank T) in the embodiment illustrated in FIG. 1A described above. The opening 18 of the main pipe section 17 in the tank T opens downward in the intermediate tank 15, and the main pipe section 17 rises from the opening 18. It extends straight upward as 17a, and it curves in a horizontal direction, and becomes a horizontal part 17b, and extends in a horizontal direction after that. Moreover, the branch r with the said guide pipe part 14 is provided in the middle of this horizontal part 17b.

Moreover, the main pipe part 17 extends straight downward as a lower part 17c from the horizontal part 17b which has the branch r with the said guide pipe part 14, and it is withdrawn from the said intermediate tank 15 after that. have.

The operation of the liquid storage device having this configuration, that is, the method of evacuating the air a mixed in the intermediate tank 15 as the storage tank T will be described.

It is assumed that air a remains in the space in the pocket part 11 of the intermediate tank 15 from now on. Thus, when air a is interposed, the drinking water w in the 2nd tank 5 'is opened by opening the supply valve 7' of the 2nd tank 5 '(refer FIG. 5A). Decreases), the drinking water w in the intermediate tank 15 is supplied toward the second tank 5 'through the second communication tube 8c.

By discharging the beverage water w, the beverage water w moves in the second communication tube 8c, that is, the main pipe portion 17, and is attracted to the air to draw the air in the pocket portion 11 through the induction pipe portion 14. The phenomenon in which (a) is attracted (see arrow y in FIG. 5B) occurs, and as a result, the air a in the intermediate tank 15 can be discharged out of the intermediate tank 15 without leaving.

In addition, the structure of the main part 17 of the 2nd communication pipe 8c provided in the intermediate tank 15 shown in FIG. 5A is the beverage server 20 shown in FIG. 1A or 5A, for example. You may employ | adopt instead of the structure of the main pipe part 12 of the discharge pipe 3 arrange | positioned at the cold water tank 5.

In addition, in these embodiment, although the water storage server 20 was demonstrated as an example as a liquid storage device, it is not limited to these embodiment, The structure of this invention is various other things, such as a tank for storage of various liquids, and a storage tank, for example. It can employ | adopt as a liquid storage apparatus provided with the various storage tanks used for storing and storing a liquid.

1A is an overall view of one embodiment

1B is an enlarged view of main parts of FIG. 1A;

2 (a) to 2 (d) are explanatory diagrams showing the action of the embodiment.

Figure 3 is an overall view of the beverage server

4 is an enlarged view of main parts of another embodiment;

5A is an overall view of another embodiment

5B is an enlarged view illustrating main parts of a modification of the embodiment of FIG. 5A.

6 is an overall view of a conventional example

7A and 7B are enlarged views of main parts of the exhaust valve of the conventional example;

<Code description>

One… Container 2.. Exhaust valve

3, 3 ', 9... Discharge pipe 4.. Vent

5... Cold water tank (first tank) 5 '... Hot water tank (second tank)

5a, 15a... Cover 5b... Partition plate

6... Water pipe 7, 7 '... Supply valve

8… Communicating tubes 8a, 9a... On-off valve

8b... First communication tube 8c... Second communication tube

10, 20... Server for beverages 11. Pocket part

12, 17... Lead portions 12a, 17a... Rise

12b, 17b... Horizontal portions 12c, 17c... Lower part

13, 18... Opening 14. Guide pipe

14a... Opening 15... Medium tank

21... Container storage portion 22... main body

a… Gas (air) w... drink

T… Storage tank

Claims (9)

The discharge pipes 3 and 8c are taken out of the storage tanks T and 5 and 15 from inside the storage tanks T and 5 and 15 having a space capable of storing liquid w therein, and the discharge pipes 3 and 8c. In the liquid storage device which makes it possible to discharge the liquid (w) in the storage tank (T; 5, 15) out of the storage tank (T; 5, 15) through The discharge pipes 3 and 8c branch off from the main pipe parts 12 and 17 and the main pipe parts 12 and 17 having openings 13 and 18 into the storage tanks T and 5 and 15, respectively. (T; 5, 15) having an induction pipe portion 14 facing upwards, the liquid (w) received from the openings (13, 18) of the main pipe parts (12, 17) through the discharge pipes (3, 8c) ) Is discharged out of the storage tanks (T) 5 and 15, the gas (a) interposed on the upper part in the storage tanks (T; 5, 15) is sucked through the induction pipe part 14 and the A function of discharging out of the tanks T; Liquid storage device, characterized in that it has. The method of claim 1, The upper part in the storage tank (T; 5, 15) is provided with a pocket portion 11 protruding upwards, the opening 14a of the guide pipe portion 14 is directed toward the space in the pocket portion 11 Liquid storage device. The method of claim 2, The openings 13 and 18 face the lower portion of the storage tanks T and 5 and 15, and the main pipe portion 12 extends upwardly from the openings 13 and 18, so that the openings 13 and 18 face each other. Liquid storage device characterized by reaching a branch (r). 4. The method according to any one of claims 1 to 3, The main pipe portion (12, 17) extends downward from the branch (r) with the guide pipe portion (14), and is drawn out of the storage tank (T; 5, 15). The beverage server provided with the liquid storage device as described in any one of Claims 1-4, Comprising: The liquid w is provided inside with respect to the water pipe 6 extended upward from the storage tank T; The container 1 accommodated therein is detachable, and the liquid w in the container 1 flows down into the storage tank T 5 through the water pipe 6. . A beverage server provided with the liquid storage device according to any one of claims 1 to 5, wherein the first tank (5) capable of storing liquid (w) therein is provided with a second tank (5 '). It is installed in parallel below and the 1st communication pipe 8b withdraw | derived from the said 1st tank 5 is connected to the storage tank T; 15, and the liquid in the said 1st tank 5 carries out the said storage tank T; 15), and the second communication tube 8c drawn out from the storage tank T 15 is connected to the second tank 5 'so that the liquid in the storage tank T 15 is removed. The liquid w is discharged out of the storage tank T 15 through the two communicating pipes 8c, and the discharged liquid w is supplied to the second tank 5 '. The second communicating tube 8c branches from the main body 17 having an opening 18 into the storage tank T 15 and the upper part in the storage tank T 15. In the case of discharging the liquid w received from the opening 18 of the main pipe portion 17 through the second communication pipe 8c to the outside of the storage tank T; And a function of simultaneously discharging the gas (a) intervening in the upper portion of the storage tank (T) 15 through the induction pipe part 14 out of the storage tank (T) 15 at the same time, and discharging the liquid (w). And a function of replenishing the liquid w in an amount appropriate to the space in which the gas a is interposed from the first tank 5 into the storage tank T 15. Beverage servers. The method of claim 6, The opening 18 faces the lower portion of the storage tank T 15, and the main pipe 17 extends upward from the opening 18 to reach the branch r with the guide pipe 14. Drinking water server having a liquid storage device, characterized in that. 8. The method according to claim 6 or 7, The main pipe part (17) extends downward from the branch (r) with the guide pipe part (14), and is drawn out of the storage tank (T; 15). 9. A method of evacuating gas (a) incorporated into storage tanks (T) 5, 15 of the liquid storage device according to any one of claims 1 to 8, wherein the discharge pipes (3, 8c) are connected to the storage tank ( T; 5, 15 main pipe parts (12, 17) having openings (13, 18) into and branched from the main pipe parts (12, 17) guide pipe portion 14 toward the space in the pocket (11) And When the liquid w taken in from the openings 13 and 18 of the main pipe parts 12 and 17 is discharged out of the storage tanks T and 5 and 15, the storage tank is connected through the induction pipe part 14. A method of evacuating a storage tank of a liquid storage device, characterized in that the gas (a) interposed above the (T; 5, 15) is sucked and discharged out of the storage tank (T; 5, 15) at the same time.

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