JP2021014690A - Cistern - Google Patents

Abstract

To provide a cistern that can deliver cleaner tap water.SOLUTION: The cistern of the present invention comprises: a first tank into which tap water is introduced and which stores introduced tap water; a pump that sucks the tap water from the first tank to send to a supply destination of the tap water; and a second tank in which the tap water is drained from the first tank via a communication passage.SELECTED DRAWING: Figure 2

Description

The present invention relates to cistern.

It is known that when tap water as a raw material is supplied to a beverage manufacturing apparatus for producing coffee beverages and the like, a systern is provided between the water supply and the beverage manufacturing apparatus in order to avoid cross-connection (for example, patent). Documents 1 and 2).

Japanese Unexamined Patent Publication No. 2001-139097 JP-A-2018-7748

Residual old tap water in the cistern may reduce the taste and flavor of the beverage.

An object of the present invention is to provide a cistern capable of delivering cleaner tap water.

According to the present invention, for example
The first tank where tap water is introduced and the introduced tap water is stored,
A pump that sucks tap water from the first tank and sends it to the tap water supply destination.
A second tank in which tap water is drained from the first tank via a continuous passage is provided.
A cistern characterized by that is provided.

According to the present invention, it is possible to provide a cistern capable of delivering cleaner tap water.

(A) and (B) are external views of the cistern according to the embodiment. Explanatory drawing of the internal structure of the cistern of FIG. (A) to (C) are operation explanatory views of the systurn of FIG. (A) to (C) are operation explanatory views of the systurn of FIG.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. It should be noted that the following embodiments do not limit the invention according to the claims, and not all combinations of features described in the embodiments are essential to the invention. Two or more of the plurality of features described in the embodiments may be arbitrarily combined. In addition, the same or similar configuration will be given the same reference number, and duplicate description will be omitted.

<Structure of system>
1 (A) and 1 (B) are external views of Systurn 1 according to an embodiment of the present invention. In the figure, X and Y indicate horizontal directions orthogonal to each other, and Z indicates a vertical direction. In the illustrated example, the X direction is the left-right direction when the systurn 1 is installed, and the Y direction is the front-rear direction (depth direction). FIG. 1 (A)
The Systurn 1 has a slim outer shape that is elongated in the vertical direction, and is configured to have a relatively small installation area. The systurn 1 has a housing 2 that forms its exterior. The housing 2 is a hollow body having an oval shape in horizontal cross section and extending in a tubular shape in the vertical direction. The housing 2 encloses the pump 10, tanks 12, 13 and the like, which will be described later. The portion 2a constituting the lower part of the front surface of the housing 2 is removable from the remaining portion. The portion 2a is a C-shaped shell-shaped member, has an engaging portion (not shown) such as a claw that engages with the remaining portion in the peripheral portion, and is detachable from the remaining portion.

An operation unit 3 is provided on the upper part of the front surface of the systurn 1. The operation unit 3 includes a display unit 3a for displaying information to the user and an operation unit 3b for receiving an instruction operation by the user. The display unit 3a is, for example, a liquid crystal display device. The operation unit 3b is, for example, a plurality of push button type switches. The user can operate the operation unit 3b to instruct the operation of the systurn 1. Information such as the operating status of SysTurn 1 is displayed on the display unit 3a.

A window portion 5 extending in the vertical direction is provided in the central portion of the front surface of the cis-turn 1, and the user can visually recognize the inside of the cis-turn 1 through the window portion 5, particularly the water level of the tank 12 described later in the case of the present embodiment. can do. The window portion 5 of the present embodiment is composed of a member having translucency. However, the window portion 5 may be an opening (a gap without a member) formed in the housing 2.

A pipe from the tap water supply source is connected to the upper part of the back surface of the systurn 1, and an introduction pipe 6 into which tap water is introduced and a pipe to the tap water supply destination are connected to send tap water. A delivery pipe 7 and the like are provided. The delivery pipe 7 is provided with a manual cock 7a, and the delivery pipe 7 can be closed by the manual cock 7a when not in use.

Tap water is typically tap water supplied by a public water system. However, the tap water supplied to Systurn 1 may be a liquid supplied from the upstream side, such as a simple water supply business, a dedicated water supply, a simple dedicated water supply, or tap water from a water tank. The tap water supply destination by SysTurn 1 is, for example, a beverage production apparatus, and typically, a beverage production apparatus for producing coffee beverages.

A power cable 4 (only the root portion is shown in FIG. 1B) extends from the central part of the back surface of the systurn 1. The power cable 4 is connected to a power source (for example, an outlet), and power is supplied to the systurn 1 via the power cable 4.

A drainage pipe 8 for draining unnecessary tap water in the systurn 1 is provided at the lower part of the back surface of the systurn 1. A pipe connecting the drain port and the systurn 1 is connected to the drain pipe 8. The drain pipe 8 is provided with a manual cock 8a, and the drain pipe 8 can be closed by the manual cock 8a when drainage is not performed.

The internal structure of Systurn 1 will be described with reference to FIG. A pump 10, a tank 12, and a tank 13 are arranged in the internal space of the housing 2. The tank 12 is a container with an open upper part for storing tap water. Tap water is introduced into the tank 12 via the introduction pipe 6. A valve 9 for opening and closing the introduction pipe 6 is provided in the middle of the introduction pipe 6. The valve 9 is an electrically driven valve such as a solenoid valve or an electric valve, and is controlled to be opened when water is stored and closed in other cases.

The tank 12 is provided with a float switch 16. The float switch 16 includes a float 16a arranged in the tank 12. The water level is detected by changing the position of the float 16a according to the water level of tap water stored in the tank 12. The float switch 16 at least detects whether or not the tap water in the tank 12 has reached the upper limit water level. When the upper limit water level is reached, the valve 9 can be closed to automatically prevent tap water from being introduced into the tank 12. The float switch 16 may also detect whether or not the tap water in the tank 12 has reached the lower limit water level. When the lower limit water level is reached, the valve 9 can be opened to automatically introduce tap water into the tank 12.

In the case of this embodiment, the tank 12 is made of a translucent material. For example, it is composed of a colorless transparent or colored transparent acrylic material or a vinyl chloride material. The float 16a is arranged behind the window portion 5. The user can visually recognize the position of the float 16a in the Z direction through the window portion 5 and the front side wall portion of the tank 12 from the outside of the systurn 1, thereby checking the water level (remaining amount) of tap water in the tank 12. You can check.

A light emitting device 17 is provided in the housing 2. The light emitting device 17 is a device that illuminates the float 16a, and has, for example, a plurality of LEDs as a light emitting element. By illuminating the float 16a, it is possible to improve the visibility when the user visually recognizes the float 16a. The light emitting device 17 may be arranged in the internal space of the tank 12, but in the present embodiment, it is arranged outside the tank 12. In the case of the present embodiment, the light emitting device 17 is arranged behind the tank 12 in the Y direction, and the illumination light of the light emitting device 17 floats through the wall portion of the tank 12 as shown by the broken line arrow in FIG. It reaches 16a and further penetrates the window portion 5. In other words, the float 16a is located between the window portion 16a and the light emitting device 17, and the wall portion on the rear side of the tank 12 is located between the float 16a and the light emitting device 17.

When the light emitting device 17 illuminates the float 16a via the tank 12, the tap water in the tank 12 is also illuminated, and the visibility of the water surface is improved. Therefore, the user can easily check the remaining amount of water stored in the tank 12 through the window portion 5. The light emitting device 17 may always emit light, or may emit light on condition that the user operates the operation unit 3b. The light emission may be blinking.

The pump 10 is an electric pump driven by a motor, sucks tap water from the tank 12 through the water absorption pipe 11, and sends it out through the delivery pipe 7. The water absorption pipe 11 passes through the end portion of the tank 12 in the Z direction rather than the central portion in the X direction. The end portion (lower part in the illustrated example) on the tank 12 side in the Z direction of the water absorption pipe 11 is bifurcated into the pipe portion 11a and the pipe portion 11b. The lower end of the pipe portion 11a is located at a height of H1 from the bottom surface of the tank 12, and the lower end of the pipe portion 11b is located at a height of H2 (H <H2) from the bottom surface of the tank 12. When the tap water level in the tank 12 is higher than the height H2, the tap water is sucked from both the pipe portions 11a and 11b. When the amount of water stored in the tank 12 decreases and the water level falls between the heights H1 and H2, tap water is sucked only from the pipe portion 11a. Tap water is less likely to remain in the pipe portion 11b. When the water level becomes lower than the height H1, tap water is not sucked into the water absorption pipe 11. Since the airway is secured by the pipe portion 11b, the tap water in the water absorption pipe 11 easily flows downward from the pipe portion 11a and the pipe portion 11b, and the tap water is prevented from remaining in the water absorption pipe 11.

The tank 13 is a container whose upper surface is open to receive tap water drained from the tank 12. A pipe 14 is provided at the bottom of the tank 12, and the pipe 14 opens to the bottom surface of the tank 12. The pipe 14 forms a continuous passage between the tank 12 and the tank 13, and the tap water in the tank 12 naturally falls into the tank 13 through the pipe 14. A valve 15 for opening and closing the pipe 14 is provided in the middle of the pipe 14. The valve 15 is an electrically driven valve such as a solenoid valve or an electric valve, and is controlled to be opened when the tank 12 is drained and closed in other cases.

A drainage pipe 8 is separably connected to the peripheral wall portion of the tank 13. The tap water temporarily stored in the tank 13 is discharged from the drain pipe 8.

In the case of the present embodiment, the pump 10 is arranged above the tank 12 so as to overlap the tank 12 in the Z direction, and the tank 13 is arranged below the tank 12 so as to overlap the tank 12 in the Z direction. By arranging the pump 10, the tank 12, and the tank 13 side by side in the Z direction in this order, the systurn 1 can be vertically elongated, and its slimming can be achieved.

The operation unit 3 is supported by a control circuit 3c that controls the entire system turn 1. The control circuit 3c includes a processor typified by a CPU, a memory that stores programs and data executed by the processor, an input / output interface, and a communication interface (for example, a short-range wireless interface) that communicates with a beverage manufacturing device to which tap water is supplied. Etc., and controls the drive of the pump 10, the valve 9, the valve 15, and the light emitting device 17. Further, the water level detection result of the float switch 16 is input to the control circuit 3c.

The control content executed by the control circuit 3c may include, for example, an automatic mode and a manual mode. In the automatic mode, a predetermined operation is automatically executed.

For example, control for automatically introducing tap water into the tank 12 can be mentioned. Specifically, the control circuit 3c acquires the water level detection result of the float switch 16 and opens the valve 9 when the water level is the lower limit. As a result, tap water is introduced into the tank 12 via the introduction pipe 6. Further, the valve 9 is closed when the water level detection result of the float switch 16 is acquired and the upper limit water level is reached. This blocks the introduction of tap water.

Further, for example, a control for automatically supplying tap water in the tank 12 to a supply destination can be mentioned. Specifically, when a supply request from the beverage manufacturing apparatus of the supply destination is received, the pump 10 is operated to deliver tap water. Further, the operation of the pump 10 is stopped when the supply stop request from the beverage manufacturing apparatus of the supply destination is received.

Further, for example, a control for automatically cleaning the inside of the tank 12 can be mentioned. Specifically, the valve 15 is opened when the systurn 1 is activated. As a result, the old tap water remaining in the tank 12 is drained to the tank 13. Further, the valve 9 is opened. As a result, tap water is introduced into the tank 12 via the introduction pipe 6 and further drained into the tank 13. Old tap water droplets adhering to the bottom of the tank 12 can be removed. Subsequent introduction of fresh tap water into the tank 12 can prevent old tap water from mixing.

In the manual mode, the user drives / stops the pump 10, opens / closes the valve 9, and opens / closes the valve 15 in response to an instruction from the operation unit 3b.

<Example of operation of Systurn>
An operation example of the systurn 1 will be described with reference to FIGS. 3 (A) to 4 (C). FIG. 3A shows a state in which tap water is stored in the tank 12. The valve 9 is opened and the valve 15 is closed. Tap water is introduced into the tank 12 via the introduction pipe 6 and stored.

FIG. 3B shows a state in which tap water in the tank 12 is sent to the supply destination. The pump 10 is driven, and the tap water in the tank 12 is sent to the supply destination via the water absorption pipe 11 and the delivery pipe 7. The valve 15 is closed. The valve 9 may be opened or closed. When the valve 9 is open, tap water delivery and water storage are performed in parallel.

FIG. 3C shows a state in which tap water in the tank 12 is drained to the tank 13. The valve 15 is opened and the valve 9 is closed. Pump 10 is stopped. By draining the tap water in the tank 12, the old tap water in the tank 12 can be removed, and cleaner tap water can be stored in the tank 12. The tap water in the tank 12 can be drained at the end of use of Systurn 1, at the start of use, or at predetermined time intervals. In many cases, using tap water stored the day before or a little while ago does not cause any problems when making beverages, but for beverages with strong taste such as coffee beverages, use old tap water. As a result, the taste and flavor of the beverage may be deteriorated. By providing the tap water drainage function in the tank 12, fresh tap water can always be stored in the tank 12.

FIG. 4A shows a state in which tap water in the tank 13 is drained. By opening the manual cock 8a, the tap water in the tank 13 is drained to the outside of the systurn 1 through the drain pipe 8. FIG. 4B shows an example of cleaning the lower part of the tank 12. By introducing tap water into the tank 12 and draining it to the tank 13, old tap water adhering to the vicinity of the bottom surface of the tank 12 can be washed away. By opening the manual cock 8a and opening the valve 9 and the valve 15, it is possible to form a flow of tap water such as introduction pipe 6 → tank 12 → pipe 14 → tank 13 → discharge pipe 8.

FIG. 4B shows a state in which the tank 13 is removed. The tank 13 can be taken out to the front side of the systurn 1 by removing the portion 2a of the housing 2. As a result, tap water in the tank 13 can be drained. The tank 13 can also be washed.

<Summary of Embodiment>
The above embodiment discloses at least the following devices.

1. 1. The cistern of the above embodiment
The first tank (for example) where tap water is introduced and the introduced tap water is stored,
A pump (for example) that sucks tap water from the first tank and sends it to the tap water supply destination.
A second tank (for example), in which tap water is drained from the first tank via a continuous passage, is provided.
According to this embodiment, it is possible to provide a cistern capable of delivering cleaner tap water.

2. 2. In the above systurn
The pump is placed on the first tank so as to overlap the first tank in the vertical direction.
The second tank is arranged under the second tank so as to overlap the first tank in the vertical direction.
According to this embodiment, the outer shape of the cistern becomes vertically long, and slimming can be achieved.

3. 3. The above systurn
A drainage pipe (for example, 8) communicating with the second tank is further provided.
According to this embodiment, drainage is facilitated.

4. The above systurn
Further comprising a housing (eg 2) surrounding the first tank, the pump and the second tank.
A portion of the housing (eg 2a) is removable from the rest
When a part of the housing is removed, the second tank can be removed.
According to this embodiment, the second tank can be washed.

5. The above systurn
Further equipped with a float switch (for example, 16) for detecting the water level of tap water stored in the first tank.
The float of the float switch (eg 16a) is visible from outside the systurn.
According to this embodiment, the water level of the first tank can be confirmed from the outside.

6. The above systurn
A light emitting means (for example, 17) for illuminating the float is further provided.
According to this embodiment, the visibility of the float can be improved.

7. In the above systurn
The first tank is made of a translucent material.
The light emitting means illuminates the float through the first tank.
According to this embodiment, the visibility of the water level of tap water stored in the first tank can be improved.

8. In the above systurn
The pump sucks tap water from the first tank via a water absorption pipe (for example, 11).
The water absorption pipe has an end portion on the side of the first tank branched into a first pipe portion (for example, 11a) and a second pipe portion (for example, 11b).
The water level at which the first pipe portion and the second pipe portion absorb water is different.
According to this embodiment, tap water is less likely to remain in the water absorption pipe.

Although the embodiments of the invention have been described above, the invention is not limited to the above-described embodiments, and various modifications and changes can be made within the scope of the gist of the invention.

1 Systurn

Claims (8)

The first tank where tap water is introduced and the introduced tap water is stored,
A pump that sucks tap water from the first tank and sends it to the tap water supply destination.
A second tank in which tap water is drained from the first tank via a continuous passage is provided.
This is a cistern that is characterized by that. The systan according to claim 1.
The pump is placed on the first tank so as to overlap the first tank in the vertical direction.
The second tank is arranged under the second tank so as to overlap the first tank in the vertical direction.
This is a cistern that is characterized by that. The system according to claim 1 or 2.
A drainage pipe communicating with the second tank is further provided.
This is a cistern that is characterized by that. The system according to any one of claims 1 to 3.
Further comprising a housing surrounding the first tank, the pump and the second tank.
Part of the housing is removable from the rest
When a part of the housing is removed, the second tank can be removed.
A cistern characterized by that. The system according to any one of claims 1 to 4.
Further equipped with a float switch for detecting the water level of tap water stored in the first tank,
The float of the float switch is visible from the outside of the systurn.
This is a cistern that is characterized by that. The systan according to claim 5.
A light emitting means for illuminating the float is further provided.
This is a cistern that is characterized by that. The systan according to claim 6.
The first tank is made of a translucent material.
The light emitting means illuminates the float through the first tank.
This is a cistern that is characterized by that. The system according to any one of claims 1 to 7.
The pump sucks tap water from the first tank via a water absorption pipe.
In the water absorption pipe, the end on the side of the first tank is branched into a first pipe portion and a second pipe portion.
The water level of the first pipe and the second pipe are different.
This is a cistern that is characterized by that.