This invention relates to a water server which can discharge water that has been moved to a water storage tank from an exchangeable raw water container as drinking water.
Water servers are configured such that when a user operates a lever or a cock, thereby opening a valve, water in the water storage tank is discharged through a water discharge line, and is received in e.g. a cup of the user. One of such water servers includes a raw water container provided at the lower portion of the housing, and a water storage tank provided at a higher position than the raw water container. This type of water server is advantageous in that when exchanging the used raw water container with a new one, a user or an operator does not have to lift the new raw water container to a high place. Since the water storage tank is provided at a higher position than the raw water container, this water server includes a water supply line in which a pump is provided to lift water in the raw water container into the water storage tank through the water supply line by means of the pump. When water in the water supply tank decreases, the pump is automatically activated to lift water in the raw water container into the water supply tank until the water in the water storage tank increases to a predetermined amount (see e.g. the below-identified Patent documents 1 and 2).
A water server of the type in which the raw water container is placed upside down includes a piercing member which is configured to push up the plug of the raw water container with the container placed upside down. The water supply line has an end portion which is a portion of the piercing member. Most ordinarily, by lowering the raw water container with the plug in contact with piercing member, the plug is pushed up into the container. However, in another arrangement, as in Patent document 1, a piercing member is lifted with the raw water container kept stationary to push in the plug. In either case, by piecing the piercing member through the plug, the raw water container is opened, and simultaneously, the interior of the container is connected to the water supply line.
In the water server disclosed in Patent document 1, since the raw water container, water supply line and water storage tank are connected together in a sealed arrangement, if a rigid container is used as the raw water container, it will be necessary for the pump to generate a large force in order to lift water in the raw water container. Thus, as described in paragraphs [0021] and [0022] of Patent document 2, it is preferable to use a raw water container which is made of a soft material and collapsible as water remaining in the container decreases.
Even if a soft raw water container is used, however, in the arrangement in which the raw water container is placed upside down as in Patent document 1, when, with a reduction in water remaining in the container, the raw water container is collapsed such that its peripheral portion is folded until its height decreases to near the mouth of the container, the rigidity of the peripheral wall portion tends to become higher than the atmospheric pressure. Since the container is not collapsible thereafter, the load on the pump tends to increase.
In view of these circumstances, an object of the present invention is make it possible to exchange raw water containers as easily as possible, and simultaneously to minimize loads on the pump until the raw water container becomes empty.
In order to achieve this object, according to this invention, in a water server in which the raw water container is placed upside down at the lower portion of the housing, and in which the water supply line has an end portion which is a portion of the piercing member, whereby the raw water container can be easily exchanged with a new one, the raw water container has a portion which is collapsible under the atmospheric pressure as water remaining in the raw water container decreases. With this arrangement, from immediately after exchanging raw water containers, the pump can lift water in the raw water container without generating a large force. Since the water server further includes an air intake line through which atmospheric air can be freely sucked into the raw water container while the pump is activated, when water in the raw water container has been drawn up until the container is not collapsible any further, atmospheric air is spontaneously sucked into the raw water container through the air intake line by the amount equal to the amount of water that has been drawn up by the pump. Thus, the pump can lift water in the raw water container without generating a large force until the container becomes empty. The air intake line has an end portion which is a portion of the piercing member. With this arrangement, simultaneously when the raw water container is opened, the interior of the raw water container is connected to the air intake line, without the need for any additional work.
Preferably, the water server further comprises a sterilizer provided in the air intake line and configured to mix sterilizing gas into atmospheric air in the air intake line with the sterilizer operatively associated with the pump. With this arrangement, since sterilizing gas is mixed into the air intake line every time the pump is activated, it is possible to prevent growth of bacteria in the air intake line and in the raw water container after atmospheric air has been sucked into the raw water container.
Preferably, the air intake line is a passage through which the interior of the raw water container is normally in communication with the atmosphere. With this arrangement, it is possible to eliminate the need to open and close the air intake line in operational association with the pump, and to detect the degree of contraction of the raw water container under the atmospheric pressure. In order not to take in atmospheric air into the air intake line near the ground level, the air intake line should be brought into communication with the atmosphere at a level higher than the level of the raw water container. Further, since the raw water container is always in communication with the atmosphere through this air intake line, the air intake line needs a vertically extending pipe portion extending to a position higher than the upper limit of the water level in the raw water container. With this arrangement, when the raw water container is set in position in the upside down position, water in the raw water container flows into the air intake line until the water level in the air intake line becomes equal to the water level in the raw water container. Thus, the portion of the vertically extending pipe located near the water level tends to especially become wet. By forming this pipe portion from copper, it is possible to prevent growth of bacteria on the surface of the pipe over a prolonged period of time due to the sterilizing action of copper itself.
The present invention provides a water server comprising a housing, an exchangeable raw water container which has a plug and which can be set at a lower portion of the housing in an upside-down position, a water storage tank mounted in the housing at a position higher than the raw water container, a water supply line through which water in the raw water container can be drawn up into the water storage tank, a water discharge line through which water in the water storage tank can be discharged, and a piercing member configured to push up the plug of the raw water container when the raw water container is placed at the lower portion of the housing in the upside-down position, wherein the water supply line has an end portion which is a portion of the piercing member, characterized in that the raw water container is made of a soft material and has a portion which is collapsible under the atmospheric pressure when water remaining in the raw water container decreases, wherein the water server further comprises an air intake line through which atmospheric air can be freely sucked into the raw water container while the pump is activated, and wherein the air intake line has an end portion which is a portion of the piercing member. With this arrangement, the raw water container can be set in position easily, and also it is possible to minimize the load on the pump until the raw water container becomes empty.
A water server embodying the present invention is described with reference to the accompanying drawings. As shown in
The housing 1 is a vertically elongated machine casing having a storage space at its lower portion into which the slide table 8 can be slid together with the raw water container 2. The lower portion of the housing 1 refers to its lower half portion up to half the height of the housing 1. The storage space of the housing 1 is covered by the front wall of the slide table 8 when the slide table 8 is fully slid into the storage space.
The raw water container 2 is made of a soft material and, as shown in
The water storage tank unit 3, shown in
For accurate positioning of the slide table 8 relative to the housing 1, the slide table 8 is coupled to a guide portion of the housing 1. The slide table 8 can be slid into and out of the housing in a horizontal straight line. The slide table 8 may be a carriage independent of the housing 1.
As shown in
As shown in
As shown in
The upwardly extending pipe 6d has a second end connected to an air chamber 6e. The air intake line 6 has a second end portion 6f which serves as an atmospheric air intake port of the air chamber 6e which communicates with the atmosphere in the housing 1. A filter such as an activated charcoal filter is mounted in the second end portion 6f of the air intake line 6 to remove pollutants contained in atmospheric air, such as dust, odors and bacteria, when atmospheric air passes therethrough.
The air intake line 6, through which the interior of the raw water container 2, in which raw water is stored, communicates with the atmosphere, comprises the first end portion 6a, joint portion 6b, connecting pipe 6c, vertically extending pipe 6d, and the second end portion 6f, which is located at the air chamber 6e. Through the air intake line 6, the interior of the raw water container 2 is always in communication with the atmosphere. Since the interior of the air intake line 6 and the interior of the water storage tank unit 3 are always at the atmospheric pressure, the water level in the vertically extending pipe 6d is always equal to the water level in the raw water container 2.
Since atmospheric air is sucked into the raw water container 2, any mass of water in the air intake line 6 disappears by the time the water level in the container 2 decreases to WL2. However, since the portion of the air intake line 6 below the water level WL1 tends to be wet. Thus, measures are preferably taken to prevent growth of bacteria at this portion of the air intake line 6. The portion of the air intake line 6 in which the water level becomes equal to the water level in the raw water container 2 extends between WL1 and WL2, and is a portion of the vertically extending pipe 6d. The portion of the vertically extending pipe 6d between WL1 and WL2 is made of copper. Since the water surface exists near this portion for a relatively long period of time until the raw water container 2 begins sucking air, this portion tends to become especially wet. But since this portion is made of copper, and copper itself has a sterilizing function, it is possible to prevent growth of bacteria on the surface of the copper pipe at this portion for a prolonged period of time. If the portion of the vertically extending pipe 6d up to the connecting point with the sterilizer 7, shown in
The sterilizer 7 is configured to mix sterilizing gas into atmospheric air in the portion of the air intake line 6 higher than the portion of the air intake line 6 in which the water level becomes equal to the water level in the raw water container 2. Such sterilizing gas may be generated in the air intake line 6, or may be supplied into the air intake line 6 from outside the air intake line 6. If an ozone generator, which generates ozone from atmospheric air, is used as the sterilizer 7, it becomes unnecessary to replenish sterilizing gas. Such an ozone generator may be of the photochemical reaction type, which irradiates introduced atmospheric air with ultraviolet light, of the silent discharge type, which generates ozone by discharging electricity through introduced atmospheric air, of the corona discharge type, or of the composite discharge type, which is a combination of more than one discharge type.
The sterilizer 7 shown is configured to mix sterilizing gas with atmospheric air in the air chamber 6e too. A delay circuit is provided in the air chamber 6e so that atmospheric air introduced into the air chamber 6e is mixed with sterilizing air and stays therein. The delay circuit thus reduces bacteria in atmospheric air in the air chamber 6e and prevents growth of bacteria in the air chamber 6e.
An air introducing pipe 12 is connected to the water storage tank unit 3 at a level higher than the upper limit of the water level in the water storage tank unit 3. The air introducing pipe 12 is always in communication with the vertically extending pipe 6d and the air chamber 6e. When the water level in the water storage tank unit 3 falls, atmospheric air containing sterilizing gas which remains in the air chamber 6e, which is at the atmospheric pressure, is sucked into the water storage tank unit 3 through the air introducing pipe 12.
The sterilizer 7 is controlled in operative association with the pump 4a. Specifically, in the simplest arrangement, the pump 4a and the sterilizer may be configured such that when the pump 4a is switched on or off, the sterilizer 7 is simultaneously switched on or off. However, in order to keep the concentration of sterilizing gas to a suitable level, the sterilizer 7 may be programmed so as to be turned on and off based on a timer and/or on the concentration of sterilizing gas as detected, independently of the pump 4a.
(When Exchanging Raw Water Containers 2)
From the state of
(Startup Procedure of the Water Server)
When the pump 4a is switched on in the state of
(While Water is being Discharged from the Water Server)
With the water level in the water storage tank unit 3 at the upper limit, when water in the water storage tank unit 3 (i.e. water in the cold water tank 3a or in the warm water tank 3b) is discharged through the water discharge line 5, the water level in the water storage tank unit 3 (which is the water level in the cold water tank 3a) falls, which cause atmospheric air in the air chamber 6e, which contains sterilizing gas, is sucked into the upper portion of the water storage tank unit 3. This prevents growth of bacteria in the water storage tank unit 3. As long as raw water remains in the air intake line 6, no atmospheric air flow occurs in the vertically extending pipe 6d and further downstream.
(Replenishing Water into the Water Storage Tank Unit 3)
After water has been repeatedly discharged through the water discharge line 5, when the water level sensor detects that the water level in the water storage tank unit 3 has reached the lower limit, the pump 4a is automatically activated until the above-mentioned predetermined upper limit is reached again.
(When Air is Spontaneously Sucked into the Raw Water Container 2)
After repeatedly replenishing water into the tank unit, when the volume of the raw water container 2 decreases until the a peripheral wall portion 2a of the container 2 is bent in a complicated manner and as a result, its rigidity becomes higher than the atmospheric pressure, the container 2 reaches a point where its volume does not decrease any further. This state of the container 2 is shown by solid line in
(When Air is Spontaneously Sucked into the Raw Water Container 2 while the Pump 4a is Activated)
(When Air is Spontaneously Sucked into the Raw Water Container 2 while the Pump 4a is not Activated)
Even while the pump 4a, shown in
(When the Raw Water Container 2 has Become Empty)
When the water level in the raw water container 2 reaches WL2 (see
This invention is not limited to the above-described embodiments, but various modifications are possible within the scope of the claims. For example, since collapsibility of the raw water container under the atmospheric pressure is correlated to such parameters as the load on the pump and water remaining in the container, the pump may be controlled in operative association with the control of an on-off valve for the air intake line based on e.g. a sensor and a pump operation history such that the raw water container is brought into communication with the atmosphere through the air intake line only when necessary, thereby improving hygiene.
Number | Date | Country | Kind |
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2012-029210 | Feb 2012 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/066969 | 7/3/2012 | WO | 00 | 9/3/2014 |