JPH11197022A - Liquid container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely prevent liquid contents from flowing out during inclination of the liquid container and during fall of it. SOLUTION: In the liquid container comprising a container main body 1 having an inner container 3, a lid body 2 for the container main body 1, and an electric heater 4 for heating the inner container 3, the lid body 2 is provided with a vapor inlet 27 for leading vapor S, generated in the inner container 3, into the lid body 2 and a vapor draw-out vent for drawing the vapor out from the inside of the lid body 2. Also, between the vapor inlet 27 and the vapor outlet 28, an annular vapor passage 30 placed in a circle in the lid body 2 and along its side periphery is connected, thereby making it possible to form, during inclination of the liquid container and during fall of it, an air layer into a vapor passage 30 which is a part higher than a liquid level W in the inner container 3. Thus, even with no use of a fall stop water valve, liquid contents W is surely prevented from flowing out via the vapor passage 30.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid container, and more particularly, to a liquid container having a novel water stopping structure at the time of inclining, falling, or suddenly increasing internal pressure.

[0002]

2. Description of the Related Art Generally, in the case of a liquid container (for example, an electric water heater), water contained in an inner container is boiled by an electric heater. It is necessary to form a steam discharge passage for discharging air into the lid. The steam discharge passage is always open to prevent the internal pressure in the inner container from rising. In this case, if the liquid container is inclined or falls, the liquid leaks to the outside through the vapor discharge passage. An overturn water stop valve for closing the discharge passage is provided.

In addition, this type of liquid container is provided with a liquid discharging passage for discharging the liquid contained in the inner container to the outside, but the liquid discharging passage is always opened. In this state, if the liquid container is tilted or falls, the liquid will leak to the outside through the liquid discharging passage, so that when the liquid container is tilted in the middle of the liquid discharging passage or An overturn valve is provided to close the liquid discharge passage when overturned.

[0004]

However, in the case of the above-described water-stopping structure, when the main body is turned over, the content liquid suddenly reaches the water-stopping valve through the vapor discharge passage or the liquid discharge passage. In such a case, there is a possibility that the content liquid may flow out before the closing operation by the valve body. In addition, when the main body is inclined slowly, there is a possibility that the content liquid may flow out from a place where the water stop valve is difficult to operate.

[0005] The present invention has been made in view of the above points, and it is an object of the present invention to reliably prevent the outflow of a liquid content when a liquid container is tilted or falls.

[0006]

According to the basic structure of the present invention (the invention of claim 1), as means for solving the above problems, a container body having an inner container, a lid of the container body, A liquid container provided with an electric heater for heating the inner container, wherein the lid has a vapor inlet for guiding steam generated in the inner container into the lid, and a vapor outlet for discharging the vapor from the lid to the outside. In addition, an annular steam passage that extends around a side in the lid is connected between the steam inlet and the steam outlet.

[0007] With the above construction, even when the liquid container is tilted or overturned, an air layer is formed in a portion of the vapor passage above the liquid level in the inner container, thereby preventing the liquid container from overturning. Even without using a water valve, the outflow of the content liquid through the steam passage to the outside can be reliably prevented. In addition, since the length of the steam passage is increased, the amount of steam discharged from the steam outlet to the outside can be reduced, and convection of the outside air into the inner container hardly occurs.
It is also possible to reduce the power consumption of the electric heater required for keeping the hot water in the inner container warm. In addition, at the time of water heating, the heat of the steam is stored in the lid, and the power consumption of the electric heater required for water heating can be reduced.

When the vapor passage has an annular diameter as close as possible to the inner diameter of the inner container as in the second aspect of the present invention, it is ensured that the liquid container is inserted into the vapor passage when the liquid container is inclined or falls. An air layer can be formed, and the outflow of the content liquid to the outside via the vapor passage can be more reliably prevented.

When the steam passage is inclined upward from the steam inlet to the steam outlet as in the third aspect of the present invention, the condensation formed in the steam passage passes through the steam passage. The steam is returned into the inner container, and the inside of the steam passage can be kept clean at all times.

As in the invention of claim 4, a series of liquid discharge passages extending from the bottom of the inner container to the upper part of the container body are provided, and the liquid discharge passage is provided with a liquid full display section of the inner container. If a bypass channel is provided at a position above the inner container and bypasses the outer periphery of the inner container and constitutes a part of the liquid discharge passage, the inner container remains in the bypass channel even when the liquid container is tilted or overturned. An air layer is formed in the portion above the liquid level of the liquid, and it is possible to reliably prevent the content liquid from flowing out to the outside through the liquid discharge passage without using the water stop valve. Can be. In addition, even when the internal pressure rises sharply, the volume of the portion above the liquid level in the liquid discharge passage increases by the amount of the bypass flow passage, so that the content liquid is reliably prevented from flowing out through the liquid discharge passage. can do.

According to a fifth aspect of the present invention, the bypass flow path is formed by a path that returns from the outlet side of the liquid outlet passage to the original outlet side by bypassing the outer periphery of the inner container one round. Even if the liquid container falls in any direction, an air layer is formed in a part of the bypass flow path (that is, a part above the liquid level in the inner container), The outflow of the liquid to the outside can be more reliably prevented.

[0012] When the detour channel has an upward slope from the inlet side to the outlet side, residual liquid remaining in the liquid discharging passage after the liquid discharging operation is formed in the detour channel. It is collected in the inner container without accumulating in the inner container, and when used as a heat retaining container, it is possible to prevent a drop in the hot water temperature in the initial stage of the next liquid pouring.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Some preferred embodiments of the present invention will be described below with reference to the accompanying drawings.

First Embodiment (Corresponding to Claims 1 to 6) FIGS. 1 to 3 show a liquid container according to a first embodiment of the present invention.

As shown in FIGS. 1 to 3, this liquid container is of a water heater type that is heated and kept warm by an electric heater. It comprises a container body 1 having an inner container 3 and a lid 2 for opening and closing the upper opening 3a of the inner container 3 so as to be openable and closable. In this case, the electric heater 4 is provided on the bottom lower surface of the inner container 3. Reference numeral 5 indicates an inner container 3
This is a temperature sensor for detecting the temperature of the object.

The container main body 1 includes a metal (for example, stainless steel) inner container 3 forming an inner peripheral surface, a synthetic resin outer case 7 forming an outer peripheral surface, and an upper edge of the inner container 3. And a synthetic resin shoulder member 8 for connecting the upper case 11 and the upper edge of the outer case 7, and a synthetic resin bottom member 9 covering the lower end opening of the outer case 7. Is integrally provided with a hinge support portion 8a for locking the hinge pin 10 of the lid 2.

A pouring opening 11b, which is an outlet of a liquid pouring passage 11 described later, faces the upper portion of the container body 1 (specifically, the anti-hinge supporting portion of the shoulder member 8). A pipe cover 13 having a mouth 12 is provided.

An inlet 11a of a liquid discharge passage 11 for discharging a liquid (for example, hot water) in the inner container 3 to the outside is connected to a bottom surface of the inner container 3. The outlet passage 11 includes a substantially U-shaped lower connecting pipe 14 having one end connected to the inlet 11a, and a straight tubular transparent liquid pipe having a lower end connected to the other end of the lower connecting pipe 14. 15 and an upper connecting pipe 1 having a lower end connected to an upper end of the liquid quantity pipe 15.
6, a falling water stop valve 17 connected to the upper end of the upper connection pipe 16, and a substantially inverted L-shaped discharging pipe connected to the falling water stop valve 17 and facing the spout 12. It consists of 18.

An electric pump 6 is provided in the middle of the lower connecting pipe 14 constituting the liquid discharge passage 11. As shown in FIG. 2, the liquid amount pipe 15 constituting the liquid discharge passage 11 is disposed at a position slightly deviated from the front of the container body 1 to one side.

The upper connection pipe 16 is provided with a glass pipe which bypasses the outer periphery of the inner container 3 and forms a part of the liquid discharge passage 11 at a position above the liquid filling display portion 19 in the inner container 3. A bypass flow path 20 composed of the above is connected.
The bypass flow path 20 detours around the outer periphery of the inner container 3 from the outlet side of the liquid outlet passage 11 (that is, the upper connection pipe 16 side) once, and returns to the original outlet side (that is, the upper connection pipe 16). side)
Is formed by a passage returning to This way,
Even if the liquid container falls in any direction, an air layer is formed in a part of the bypass flow path 20 (that is, a part above the liquid level in the inner container 3), The outflow of the content liquid to the outside can be reliably prevented.

The outlet 20b of the bypass flow path 20 is positioned higher than the inlet 20a, and as a whole,
The slope is gentle upward from the side 0a toward the exit 20b. A partition 21 is formed between the inlet 20a and the outlet 20b of the bypass flow path 20, and the content liquid W entering the upper connection pipe 16 from the liquid flow pipe 15 passes through the bypass flow path 20 to the upper part. After returning to the connection pipe 16,
It is to be discharged to the outside via the discharge pipe 7 and the discharge pipe 18 (see FIG. 2). Further, the bypass channel 20 is supported by a support 22 fixed to the outer peripheral surface of the inner container 3 on the opposite side of the liquid discharge passage 11 in contact with the outer peripheral surface of the inner container 3.

The water stop valve 17 is provided with a valve chamber 23 formed above the bypass flow path 20 in the middle of the liquid discharge passage 11, and a liquid discharge passage formed in the valve chamber 23. And a valve body 24 that operates to close the valve hole 23a communicating with the main body 11 when the main body falls.
The valve element 24 is guided by a virtual funnel-shaped guide rib 25 formed in the valve chamber 23 and is slidable obliquely upward to close the valve hole 23a. That is, the valve body 24 is slid while being guided by the guide ribs 25 when the liquid container falls, and closes the valve hole 23a, whereby the water is prevented from falling. In the case of the embodiment, the bypass flow path 2
The formation of 0 is not always necessary since the outflow of the content liquid W to the outside when the liquid container is tilted, falls, or when the internal pressure sharply rises can be prevented. However, the liquid container may fall down vigorously, or the pressure in the inner container 3 may rise sharply, so that the outflow channel 20 alone cannot prevent the outflow of the content liquid W to the outside. It is more desirable to provide.

On the other hand, the lid 2 is provided with a hinge pin 1 with respect to a hinge supporting portion 8a of the shoulder member 8 in the container body 1.
And the inner container 3 is attached to the lower surface of the bottom plate 2b of the lid 2 so as to be openable and closable.
A cover plate 26 made of sheet metal for covering the upper opening 3a is attached. Reference numeral 31 denotes a lock mechanism for keeping the lid 2 closed.

The lid 2 has a vapor inlet 27 which opens at the center of the lid plate 26, and an opening at the rear (in other words, slightly forward) of the top plate 2a of the lid 2. A steam outlet 28 is formed. A substantially funnel-shaped steam chamber 29 is formed below the steam outlet 28.

The steam inlet 27 and the steam outlet 28
(Specifically, an annular steam passage 3 surrounding the side circumference in the lid 2 is provided between the steam passage 3 and the inlet 29 a of the steam chamber 29.
0 is connected. As shown in FIG. 5, the steam passage 30 extends in the centrifugal direction from the steam inlet 27 and extends to the outermost periphery in the lid 2, and the steam passage 30 extends from the outer end of the centrifugal passage 30 a An arc-shaped passage 30b that goes around the side circumference in the lid 2 and makes substantially one round, and a centripetal passage 30c that extends from the end of the arc-shaped passage 30b in the centripetal direction and is connected to the inlet 29a of the steam chamber 29. It is inclined upward from the steam inlet 27 to the steam outlet 28 (see FIG. 3). The vapor passage 30 has an annular diameter that is as close as possible to the inner diameter of the inner container 3 because an air layer can be reliably formed in the vapor passage 30 when the liquid container is tilted or falls. Is desirable.

By the way, the steam passage 30 is, for example,
It is formed by cutting an extruded straight silicone rubber pipe at predetermined intervals and then bending it into a predetermined shape. This facilitates the formation of the steam passage 30. Reference numeral 32 denotes a metal elbow joint connected between the centripetal passage 30c in the steam passage 30 and the steam chamber inlet 29a, and reference numeral 33 denotes a steam chamber inlet 29a and the elbow joint 32.
This is a seal packing that seals the seam.

The vapor passage 30 draws out the vapor generated in the inner container 3 to the outside, so that the pressure in the inner container 3 rises abnormally, and the content liquid flows through the liquid discharge passage 11.
(For example, hot water) W is provided to prevent inadvertent pouring out of the pouring port 11b.

The liquid container constructed as described above operates as follows.

When the energization of the electric heater 4 is started, the content liquid W contained in the inner container 3 is heated and boiled to generate steam S. The steam S is supplied from the steam inlet 27 to the steam passage 30.
The steam is discharged to the outside through the steam outlet 28 through the steam chamber 29. Since the steam passage 30 is supposed to go around the outermost periphery in the lid 2, the passage length becomes longer, and the steam passage 30 becomes longer.
Condensation will occur in the interior. Therefore, the amount of steam discharged from the steam outlet 28 to the outside is reduced. In addition, since convection of the outside air into the inner container 3 does not easily occur, the power consumption of the electric heater 4 required for keeping the hot water in the inner container 3 can be reduced. Further, at the time of water heating, the heat held by the steam is stored in the lid 2, so that the power consumption of the electric heater 4 required for water heating can be reduced. Further, the steam passage 30 is connected to the steam outlet 28 from the steam inlet 27 side.
Side, the steam passage 30
Condensation generated in the inside of the inner container 3 passes through the steam passage 30.
The inside of the steam passage 30 can be kept clean at all times.

By pressing a hot water supply switch (not shown), the electric pump 6 is operated and the content liquid W is discharged through the liquid discharge passage 11, but the liquid container is tilted or overturned. In this case, as shown in FIG. 4, an air layer is formed in a portion of the steam passage 30 above the liquid level W in the inner container 3, so that the water stop valve is not required. In addition, the outflow of the content liquid W to the outside through the steam passage 30 can be reliably prevented.

On the other hand, when the liquid container is slowly tilted or turned over, the water stop valve 17 may not be operated. Because the bypass flow path 20 is formed,
As shown in FIG. 4, the upper part of the bypass flow path 20 is higher than the liquid level of the content liquid W in the inner container 3, and an air layer is formed in this part. Therefore, the outflow of the content liquid W to the outside through the liquid discharge passage 11 can be reliably prevented by the presence of the air layer. In addition, even when the internal pressure is rapidly increased, the volume of the portion higher than the liquid level in the liquid discharge passage 11 is increased by the amount of the bypass flow passage 20, and therefore, the content liquid W through the liquid discharge passage 11 is discharged. Outflow to the outside can be reliably prevented.

Further, by setting the outlet 20b of the bypass flow path 20 higher than the inlet 20a, the residual liquid remaining in the liquid discharge passage 11 after the liquid discharging operation does not accumulate in the bypass flow path 20 and the inner container 3, the temperature of the hot water can be prevented from lowering at the initial stage of the next liquid pouring.

Further, by contacting the bypass channel 20 with the outer peripheral surface of the inner container 3, heat conduction from the inner container 3 to the bypass channel 20 is obtained. Even if the residual liquid is present, it is possible to prevent the temperature from lowering.

In the above description, the bypass channel 20 is constituted by a passage which goes around the outer periphery of the inner container 3 in the embodiment, but the bypass channel 20 goes around the outer periphery of the inner container 3. It may be constituted by a passage that reciprocates without the need.

The steam passage 30 may extend around the inside of the lid 2 any number of times. Furthermore, in addition to the above-described substantially circular shape, a square,
It may be a polygonal shape such as a hexagon. Furthermore, FIG.
As shown in FIG.
a and a portion other than the centripetal passage 30c can be formed in a meandering shape, and as shown in FIG.
If the liquid reservoir 30d is formed in the portion b, the vapor passage 3
Since the amount of liquid accumulated in 0 increases, leakage of liquid to the outside at the time of falling can be more reliably prevented, dew condensation of steam S is promoted, and the amount of discharged steam can be further reduced.

Second Embodiment (Claims 1, 2, 4 to 6)
FIG. 8 shows a structure of a lid in a liquid container according to a second embodiment of the present invention.

In this case, the steam passage 30 includes ribs 34, 34 integrally formed on the upper surface of the bottom plate 2b of the lid 2 so as to form, for example, an annular shape as shown in FIG. 5, and upper ends of the ribs 34, 34 And a passage formed between the cover body 35 and the cover body 35 to be welded by high frequency. In this case, the steam passage 30 is horizontal. In this case, the configuration of the steam passage 30 is simplified. Other configurations are the same as those in the first embodiment, and a description thereof will be omitted.

In the above description, a water heater type liquid container is described as an embodiment. However, the present invention is also applicable to a liquid container of a type that only retains heat or only stores liquid.

[0039]

According to the invention of the present application (the invention of claim 1),
In a liquid container including a container body having an inner container, a lid of the container main body, and an electric heater for heating the inner container, the vapor generated in the inner container is guided to the lid into the lid. A steam inlet and a steam outlet for discharging from the lid to the outside are provided, and between the steam inlet and the steam outlet, a ring-shaped steam passage around a side circumference in the lid is connected. Even when the liquid container is tilted or overturned, an air layer is formed in a portion above the liquid level in the inner container in the steam passage even when the liquid container is overturned. There is an excellent effect that the outflow of the content liquid through the liquid can be reliably prevented. In addition, since the length of the steam passage becomes longer, the amount of steam discharged from the steam outlet to the outside can be reduced, and convection of the outside air into the inner vessel is less likely to occur, so that the hot water in the inner vessel is kept warm. The power consumption of the electric heater required for the above can also be reduced. In addition, at the time of water heating, the heat of the steam is stored in the lid, and the power consumption of the electric heater required for water heating can be reduced.

When the vapor passage has an annular diameter as close as possible to the inner diameter of the inner container as in the second aspect of the present invention, it is ensured that the liquid container is inserted into the vapor passage when the liquid container is inclined or falls. An air layer can be formed, and the outflow of the content liquid to the outside via the vapor passage can be more reliably prevented.

In the case where the steam passage has an upward slope from the steam inlet to the steam outlet as in the third aspect of the present invention, the condensation formed in the steam passage passes through the steam passage. The steam is returned into the inner container, and the inside of the steam passage can be kept clean at all times.

As in the invention of claim 4, a series of liquid discharge passages extending from the bottom of the inner container to the upper part of the container body are provided, and the liquid discharge passage is provided with a liquid full display section of the inner container. If a bypass channel is provided at a position above the inner container and bypasses the outer periphery of the inner container and constitutes a part of the liquid discharge passage, the inner container remains in the bypass channel even when the liquid container is tilted or overturned. An air layer is formed in the portion above the liquid level of the liquid, and it is possible to reliably prevent the content liquid from flowing out to the outside through the liquid discharge passage without using the water stop valve. Can be. In addition, even when the internal pressure rises sharply, the volume of the upper part of the liquid in the liquid discharge passage increases by the amount of the bypass flow passage, so that the content liquid is reliably prevented from flowing out to the outside through the liquid discharge passage. can do.

According to a fifth aspect of the present invention, the bypass flow path is formed by a path which returns from the outlet side of the liquid outlet passage to the original outlet side by bypassing the outer periphery of the inner container one round. Even if the liquid container falls in any direction, an air layer is formed in a part of the bypass flow path (that is, a part above the liquid level in the inner container), The outflow of the liquid to the outside can be more reliably prevented.

In the case where the bypass flow path has an upward slope from the inlet side to the outlet side, residual liquid remaining in the liquid discharge passage after the liquid discharging operation is formed in the bypass flow path. It is collected in the inner container without accumulating in the inner container, and when used as a heat retaining container, it is possible to prevent a drop in the hot water temperature in the initial stage of the next liquid pouring.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a liquid container according to a first embodiment of the present invention.

FIG. 2 is a front view showing a cross section of a part of the liquid container according to the first embodiment of the present invention.

FIG. 3 is an enlarged vertical sectional view of a lid of the liquid container according to the first embodiment of the present invention.

FIG. 4 is a longitudinal sectional view showing a state of the liquid container according to the first embodiment of the present invention when the liquid container falls down.

FIG. 5 is a plan view of a vapor passage in the liquid container according to the first embodiment of the present invention.

FIG. 6 is a plan view showing a modification of the vapor passage in the liquid container according to the first embodiment of the present invention.

FIG. 7 is a plan view showing another modified example of the vapor passage in the liquid container according to the first embodiment of the present invention.

FIG. 8 is an enlarged vertical sectional view of a lid in a liquid container according to a second embodiment of the present invention.

[Explanation of symbols]

1 is a container body, 2 is a lid, 3 is an inner container, 4 is an electric heater, 6 is an electric pump, 8 is a shoulder member, 11 is a liquid discharge passage, 14 is a lower connection pipe, 15 is a liquid flow pipe, 16 Is an upper connection pipe, 17 is a water stop valve, 18 is a discharge pipe, 19 is a liquid full display section, 20 is a bypass flow path, 20a is an inlet, 20b is an outlet, 2
7 is a steam inlet, 28 is a steam outlet, 30 is a steam passage,
S is vapor, W is content liquid.

Claims (6)

[Claims] 1. A liquid container comprising a container body having an inner container, a lid of the container main body, and an electric heater for heating the inner container, wherein the lid has a liquid generated in the inner container. A steam inlet for guiding the steam into the lid and a steam outlet for discharging the steam from the lid to the outside, and a side circumference in the lid between the steam inlet and the steam outlet. A liquid container having a rotating annular vapor passage connected thereto. 2. The liquid container according to claim 1, wherein the vapor passage has an annular diameter as close as possible to the inner diameter of the inner container. 3. The liquid container according to claim 1, wherein the vapor passage has an upward slope from the vapor inlet side to the vapor outlet side. . 4. A series of liquid discharge passages extending from the bottom of the inner container to the upper part of the container body, and the liquid discharge passage is provided at a position above a liquid full display portion of the inner container. The liquid container according to any one of claims 1 to 3, wherein a bypass flow path that bypasses an outer periphery of the inner container and forms a part of the liquid discharge passage is provided. 5. The method according to claim 1, wherein the bypass flow path is formed by a path that detours around the outer circumference of the inner container from the outlet side of the liquid outlet path and returns to the original outlet side. 5. The liquid container according to 4. 6. The liquid container according to claim 4, wherein the bypass channel has an upward slope from an inlet side to an outlet side.