JP3200074U - an electronic pot - Google Patents

Abstract

An electric kettle that can supply hot water at a constant constant temperature, saves time and power consumption, and prevents deterioration of water quality due to repeated heating. An outer case, an inner container 4 attached to the outer case, a lid 11, a water supply device 3, and a control device are provided. The inner container 4 is provided with an upper opening sealed by the lid 11 and a branch valve. The heating device 1 is provided between the inner container 4 and the outer case, and the heating device 1 is connected to a water transport device 5 that transports water in the inner container 4 to the heating device 1. A water supply port is provided that communicates with the water supply device 3 through the water supply control member and communicates with the circulation return passage 9 that returns the water in the heating device 1 to the inner container 4 through the circulation control member. The heating device 1 is provided with a water level sensor 7 and a water temperature sensor 6, and the water level sensor 7, the water temperature sensor 6, the heating device 4, the water pump 5-2, the water supply control member, and the circulation control member are electrically connected to the control device, respectively. Has been. [Selection] Figure 1

Description

  The present invention relates to the technical field of electric water heaters, and more particularly to an electric kettle used for supplying hot water for drinking in places such as general homes and offices.

  Electric pots are widely used in homes and offices as home appliances that boil water and have a thermal insulation function, and can always supply hot water and are easy to use and convenient. Currently, many commercially available electric pots use stainless steel inner containers and require a series of processing processes such as cutting, rolling, roll bending, welding, cleaning, spray coating, and polishing on stainless steel. Due to the complexity of the manufacturing process, it is easy to inadvertently leave harmful chemicals on the surface, or it can rust when operating in high temperature environments for extended periods. Moreover, since the stainless steel material has a high thermal conductivity, it is disadvantageous for keeping hot water in the inner container. And since a general electric pot provides only hot water of the real time temperature in an inner container, the suitable temperature of powdered milk (50 to 60 degreeC), the suitable temperature of tea (80 to 90 degreeC), the optimum temperature of instant noodles ( Although it is impossible to satisfy different requirements in constant temperature heating for hot water (such as 90 ° C. to 95 ° C.) in a short time, such needs are widely present in places such as homes and offices where there are many people. . In this case, by adjusting the set temperature of the electric pot to a higher temperature and heating all the water in the inner container to a higher temperature before providing it to tea, instant noodles, etc., waste of time and power consumption Become. At the same time, when heating is repeated several times, the water quality deteriorates and drinking such water over a long period is harmful to physical health.

  In order to solve at least one problem in the above-described prior art, the present invention can supply hot water at a constant constant temperature, save time and power consumption, and prevent deterioration of water quality due to repeated heating. Provide an electric kettle.

  In order to solve the above-mentioned problem, the present invention is an electric pot, and includes an outer case, a glass or ceramic inner container attached to the outer case, a lid, a water supply device, and a control device. The glass or ceramic inner container has an upper opening sealed by the lid and a lower opening provided with a branch valve, and a heating device is provided between the glass or ceramic inner container and the outer case. And the heating device communicates with the water supply device through the water supply control member, the water inlet communicating with the water transport device for transporting the water in the glass or ceramic inner container to the heating device, and the circulation control. A water supply port that communicates with a circulation return passage for returning water in the heating device to the glass or ceramic inner container via a member is provided. The heating device is provided with a water level sensor and a temperature sensor, and the water level sensor, the temperature sensor, the heating device, the water pump, the water supply control member, and the circulation control member are each electrically connected to the control device. . The electric pot of the present invention combines the heating function of a conventional water heater with the function of supplying water at a fixed constant temperature according to the specific needs of the present invention by a specially structured heating device. The purpose of quantitatively raising the temperature of the heated hot water at the same time as circulating heating can be achieved. In this way, after the water in the glass or ceramic inner container is heated and kept warm, if hot water at a higher temperature is required, a certain amount of hot water is transported to a heating device and reheated at a constant temperature. That's fine. Compared with the electric pot that heats all the water in the glass or ceramic inner container in the prior art, the electric pot of the present invention can save time and power consumption. In addition, when it is necessary to drink, it is sufficient to immediately heat and supply a certain amount of hot water, so that it is possible to prevent repeated heating of water in the glass or ceramic inner container. By repeatedly heating the water in the inner container, the problem of deteriorating water quality can be solved, and healthy drinking can be ensured.

  Preferably, the water supply port includes two of an external water supply port communicating with the water supply device and a circulation water supply port communicating with the circulation return passage. Both the water supply control member and the circulation control member are electromagnetic valves.

  Of course, only one water supply port may be provided. The water supply control member and the circulation control member are the same member, and the structure thereof may include one three-way valve and two electromagnetic valves respectively connected to two outlets of the three-way valve. You may comprise a valve.

  Preferably, the water transport device includes a water transport passage communicating with a branch valve in a lower portion of the glass or ceramic inner container, and a water pump provided in the water transport passage.

  Preferably, the control device includes a hot water control module for heating water in the glass or ceramic inner container to a first set temperature, a water supply control module for controlling hot water to flow out of the water supply device, and glass. Or a temperature increase control module for heating a predetermined amount of hot water in the ceramic inner container to the second set temperature. The water heater control module is electrically connected to the heating device, the water pump, and the circulation control member. The water supply control module is electrically connected to the water pump and the water supply control member. The heating device, the water pump, and the water supply control member are electrically connected. The water supply control member and the circulation control member have an interlocking relationship. With the appropriately designed control modules, when using the electric pot of the present invention, hot water of various different set temperatures can be obtained by simply pressing a button on the control panel to meet different drinking requirements.

  Preferably, the water supply device includes a water supply nozzle provided in the outer case, and a water supply passage that communicates the water supply nozzle with a water supply port of the heating device.

  Preferably, a gas-liquid separation mechanism is provided in the water supply passage. By the gas-liquid separation mechanism, water vapor generated in heating and heating can be immediately discharged, and chlorine gas and other compounds dissolved during purification of tap water can be removed to the maximum.

  Preferably, the heating device is an electric pot or an electric heating body with a water tube.

  Preferably, the heating device is provided above the inner container made of glass or ceramics, and the lowest horizontal water level in the cavity of the heating device is at least 10 mm higher than the highest water level of the inner container made of glass or ceramics. In this way, when the water pump is turned off and the circulation is stopped, no extra power member is required, and the water in the heating device does not remain in the heating device for a long time, and the contents made of glass or ceramics by gravity action By returning to the vessel spontaneously, keeping the heating device dry ensures that the formation of scale or bacteria in the cavity of the heating device is reliably reduced, extending the routine descaling cycle and product life Can be extended.

  Preferably, the outside of the glass or ceramic inner container is surrounded by a heat insulating and heat insulating layer, and the distance between the heat insulating heat insulating layer and the glass or ceramic inner container is in the range of 0 to 25 mm.

  Preferably, a water level sensor and an alarm device for preventing the amount of water in the glass or ceramic inner container from being too much or too small are provided at the top and bottom of the glass or ceramic inner container, respectively. When the water level in the glass or ceramic inner container becomes higher than the highest water level or lower than the lowest water level, the water level sensor transmits a water level signal to the control device to stop the heating operation and issue an alarm signal. In this way, it is possible to effectively prevent the electric pot from overflowing or emptying.

  Preferably, the electric pot is provided with an emergency power source, and the emergency power source is a battery or a super capacitor. In this way, hot water can be supplied by temporarily supplying power to the electric kettle at the time of power failure or at a place where it cannot be connected to the power source.

  Compared with the prior art, the electric bot of the present invention has the following beneficial effects. That is, the heating function of a conventional water heater is combined with the function of supplying water at a fixed constant temperature as required by the present invention by a specially structured heating device, while simultaneously circulating and heating water in a glass or ceramic inner container, The purpose of heating the hot water at a fixed amount can be achieved. In this way, after the water in the glass or ceramic inner container is heated and kept warm, if hot water at a higher temperature is required, a certain amount of hot water is transported to a heating device and reheated at a constant temperature. That's fine. Compared with the electric pot that heats all the water in the glass or ceramic inner container in the prior art, the electric pot of the present invention can save time and power consumption. In addition, when it is necessary to drink, it is sufficient to immediately heat and supply a certain amount of hot water, so that it is possible to prevent repeated heating of water in the glass or ceramic inner container. By repeatedly heating the water in the inner container, the problem of deteriorating water quality can be solved, and healthy drinking can be ensured. In addition, the electric pot of the present invention can realize automatic control by a control device, and can obtain hot water with a fixed amount of constant temperature by heating to meet various different drinking requirements.

FIG. 1 is a schematic structural view of an electric pot according to the present invention. FIG. 2 is a schematic structural view of a heating device according to one structure of the present invention. FIG. 3 is a partially exploded schematic view of an electric pot having the heating device of FIG. 2 of the present invention. FIG. 4 is a schematic structural view of a heating device according to another structure of the present invention.

  The technical configuration of the present invention will be further described below with reference to the drawings and examples.

Example 1
FIG. 1 is a schematic structural view of an electric pot according to the present invention. As shown in FIG. 1, the electric pot includes a container body, a lid 11, a control device (not shown) for controlling the operation of the electric pot, and a water supply device 3 for supplying water to the user. Including. The container body includes an outer case 2 and a glass or ceramic inner container 4 attached in the outer case 2, and an opening in the glass or ceramic inner container 4 is sealed by a lid 11. A heating device 1 with a water containing cavity is provided above the inner container 4 made of glass or ceramics. Between the glass or ceramic inner container 4 and the heating device 1, a water transport device 5 for transporting water in the glass or ceramic inner container 4 to the heating device 1, and water in the heating device 1 made of glass or ceramics. A circulation return passage 9 for returning to the vessel 4 is provided. The water supply device 3 communicates with the heating device 1. The circulation return passage 9 and the heating device 1 are connected by a circulation control member, and the water supply device 3 and the heating device 1 are communicated by the water supply control member. In order to ensure that water in the heating device 1 returns smoothly to the inner container through the circulation return passage 9, it is necessary that the lowest water level in the cavity of the heating device 1 is higher than the highest water level of the glass or ceramic inner container 4. is there. The heating device 1 may be provided at any other position between the glass or ceramic inner container 4 and the outer case 2, but in this way, not only the volume of the entire device is increased, but also the heating of the water It is also disadvantageous to return the device 1 to the cavity.

  In order to improve the heat retaining property, the present invention may further have a structure surrounding the outside of the glass or ceramic inner container 4 with the heat insulating and heat insulating layer 8 except that a two-layered container body is used. An interval of 25 mm or less is provided between the heat insulating layer 8 and the glass or ceramic inner container 4. The glass or ceramic inner container 4 of the present invention may be a round or square narrow mouth bottle, and preferably uses heat-resistant borosilicate glass. The heating device 1 is positioned above the shoulder of the glass or ceramic inner container 4. Moreover, in order to improve heat retention, it seals between the opening part of the inner container 4 made from glass or ceramics, and the cover body 11 of an electric pot with a flexible seal ring or silicone grease filling. The inner container 4 made of glass or ceramics may have a smooth inner surface, and a coating layer having an effect of heat insulation and aesthetic appearance may be provided on the outer surface by electroplating or spray coating. A water level sensor 7 and an inner container water temperature sensor 6 are provided at the bottom of the glass or ceramic inner container 4, and the water level sensor 7 is preferably a magnetic field water level sensor 7.

  The water supply device 4 includes a water supply nozzle 4-1 provided in the outer case 1 and a water supply passage 4-3 for communicating the water supply nozzle 4-1 and the heating device 1. A gas-liquid separation mechanism is provided in the water supply passage 4-3. The water supply passage and the heating device 1 communicate with each other via a water supply control member. In this embodiment, the circulation control member and the water supply control member are both electromagnetic valves, and are referred to as a first electromagnetic valve 21 and a second electromagnetic valve 22, respectively.

  The water transport device 5 includes a water transport passage 5-1 and a water pump 5-2 provided in the water transport passage, and the water transport passage communicates with the bottom of the glass or ceramic inner container 4. The water pump is an electric pump with a long operating life, preferably a centrifugal pump.

  The heating device 1 of the present invention has two different structures, and may be an electric pot or an electric heating body with a water tube.

  FIG. 2 is an exploded structural schematic diagram of the electric pan. As shown in FIG. 2, the heating device 1 includes a pot body 1 </ b> A- 2 having an annular structure whose bottom is opened. An annular heating panel 1A-4 is provided at the bottom of the pot body 1A-2 as the bottom surface of the pot body 1A-2. An annular cavity for containing water is formed by bringing the inner and outer edges of the heating panel 1A-4 into close contact with the pot body 1A-2, and the volume of the cavity is 100 ml or more. A heating tube 1A-7 is fixed to the bottom of the heating panel 1A-4 by a clamp ring 1A-8. In order to satisfactorily seal the heating panel 1A-4 and the pot body 1A-2, a seal ring 1A-3 is provided at both the inner and outer contact positions of the heating panel 1A-4 and the pot body 1A-2. . The pot body 1A-2 is provided with a water inlet 1A-5, a circulating water inlet 1A-9, and an external water inlet 1A-10. The water inlet 1A-5 communicates with the water transport passage 5-1, the circulation water supply port 1A-9 communicates with the circulation return passage 9 via the first electromagnetic valve 21, and the outer water supply port 1A-10 is the first. It communicates with the water supply passage 3-1 through the two electromagnetic valves 22. A pot body water temperature sensor 1A-1 for controlling the temperature of the heated water is provided on the outer surface of the pot body 1A-2. At the bottom of the heating panel 1A-4, a temperature controller 1A-6 for preventing the heating tube from being blown is provided. The flow situation of the water in the electric pan is indicated by the arrow in FIG. FIG. 3 is a partially exploded schematic view of an electric pot having the electric pan structure of the present invention.

  FIG. 4 is a schematic diagram of an exploded structure of the electric heating body with a water tube. As shown in FIG. 4, the heating device 1 includes a holder portion 1B-4 and an electric heating tube 1B-2 with a water tube that is fixed to the holder portion by a fastening sheet 1B-1 and a support sheet 1B-3. Prepare. Two parallel water pipes communicate with each other. FIG. 4 shows a state in which the water pipe is incised in order to better explain the state of the water flow. The electric heating pipe 1B-2 is provided with an electric heating pipe temperature sensor 1B-5 and a temperature regulator 1B-6 for preventing the electric heating pipe 1B-2 from being blown. The water pipe of the electric heating pipe 1B-2 has a diameter of 4 mm or more, and the inside forms a cavity for containing water. The electric heating pipe is provided with a water inlet 1B-7 communicating with the water transport passage 5-1 and a water inlet 1B-8, and an electric heating pipe water temperature sensor 1B-9 is provided at the water inlet 1B-7. It is done. A three-way valve is connected to the water supply port IB-8, and one outlet of the three-way valve (that is, the circulation water supply port 1A-9) communicates with the circulation return passage 9 via the first electromagnetic valve 21, Another outlet (that is, the external water supply port 1A-10) communicates with the water supply passage 3-1 through the second electromagnetic valve 22. Naturally, a three-way solenoid valve may be used to connect to the water supply passage 3-1 and the circulation return passage 9, respectively, but this is not preferable from the viewpoint of cost. The flow state of the water in the electric heating body is indicated by an arrow in FIG. The electric pot performs the preheating function of the electric heating pipe 1B-2 by detecting the temperature with the electric heating pipe temperature sensor 1B-5. After the preheating is completed, the water pump 5-2 is controlled so that water in the glass inner container is injected into the electric heating pipe 1B-2, and the electric heating pipe 1B-2 is heated synchronously, and the electric heating pipe water temperature sensor 1B. -9 immediately senses the temperature of the water that has flowed in, and controls the amount of heat generated by the electric heating tube so that it functions to supply hot water at a constant temperature.

  The control device of the present invention includes a water heater control module for heating water in a glass or ceramic inner container 4 to a first set temperature, a water supply control module for controlling hot water to flow out of the water supply device 3, and glass Or a temperature increase control module for heating a predetermined amount of hot water in the ceramic inner container 4 to the second set temperature. The first set temperature is generally 99 ° C. to 100 ° C., that is, the boiling temperature of water, and the second set temperature may be variously set according to drinking requirements. By controlling parameters such as the amount of heat generated by the heating device 1, the amount of water supplied, and the flow rate of water supplied, hot water having different temperatures can be obtained. The water heater control module is electrically connected to the heating device 1, the water pump 5-2, and the first electromagnetic valve 21, and the water supply control module is electrically connected to the water pump 5-2 and the second electromagnetic valve 22, The temperature control module is electrically connected to the heating device 1, the water pump 5-2, and the second electromagnetic valve 22. The first solenoid valve 21 and the second solenoid valve 22 have an interlocking relationship, that is, when one is open, the other is closed.

  Moreover, you may provide an emergency power supply in an electric pot as needed, and can thus supply hot water by temporarily supplying power to the electric pot at the time of a power failure or in a place where it cannot be connected to the power supply. The emergency power supply preferably uses a battery or a super capacitor.

  The operation principle of the electric pot of the present invention is as follows. That is, first, the lid 11 is opened and a certain amount of water (tap water may be used as a water source) is placed in the glass or ceramic inner container 4. The power supply is turned on, and the water pump control module of the control device controls the water pump 5-2 so that water in the glass or ceramic inner container 4 is injected into the cavity of the heating device 1. After the water in the heating device 1 is heated, it is returned to the inner container through the circulation return passage 9. The direction of water circulation is indicated by the arrows in FIGS. In this way, until it is detected by the inner container water temperature sensor 6 that all the water in the glass or ceramic inner container 4 has been heated to the first set temperature (that is, in a boiling state) and satisfies the drinking condition, Perform circulating heating. At this time, the heating device 1 stops heating, and the water in the cavity of the heating device 1 spontaneously returns to the glass inner container. Therefore, by maintaining the anhydrous state in the cavity of the heating device 1, the cavity of the heating device 1 is maintained. It is possible to reliably reduce the generation of scale or bacteria. In this case, the electric pot is kept warm. When it is necessary to drink hot water directly in the glass or ceramic inner container 4, the water supply control module turns on the second electromagnetic valve 22 and the water pump 5-2 by the operation of the control panel of the electric pot by the user. By controlling the water supply passage 3-1 to communicate with the water supply port of the heating device 1, hot water is allowed to flow out of the water supply nozzle 3-2 to satisfy the user's drinking requirements. The water flow direction is shown in FIG. When the water supply passage is opened, the first electromagnetic valve 21 in the circulation return passage 9 is closed in order to prevent water from returning directly from the circulation water supply port 1A-9 to the glass inner container. Of course, another water supply passage (not shown) may be provided directly. In this case, an independent water pump is provided in the water supply passage, and both ends of the water supply passage communicate with the bottom of the inner container and the water supply nozzle, respectively. Yes. When the independent water pump is activated, hot water is drawn up and supplied to the user. When it is necessary to heat and supply hot water at a fixed constant temperature, the temperature raising control module is turned on by the control panel, and the second solenoid valve 22 and the water pump 5-2 are controlled to turn on and circulate. The first electromagnetic valve 21 in the return path is closed and the heating device 1 is activated to perform heating. A certain amount of hot water sucked up by the water pump 5-2 is heated in the lumen of the heating device 1 to rise to the second set temperature, and flows out from the water supply nozzle 3-2 through the water supply passage 3-1.

  The magnetic field level sensor 7 at the bottom of the inner container can always detect the amount of water in the inner container. If the water level is lower than the minimum water level, it cannot be heated in the electric pot. On the other hand, when it is detected by the inner container water temperature sensor 6 that the water temperature in the glass inner container falls below the set holding temperature, the heating device 1 is activated to hold the water set in the glass or ceramic inner container 4. Recirculate heating to temperature.

  The above-described examples are merely preferred embodiments of the present invention, and do not limit the present invention. Any improvements, modifications, substitutions, combinations or simplifications made without departing from the spirit and principle of the present invention should be included in the protection scope of the present invention as equivalent exchanges.

Claims (10)

An outer case (2); a glass or ceramic inner container (4) attached to the outer case (2); a lid (11); a water supply device (3); The ceramic inner container (4) has an upper opening sealed by the lid (11) and a lower opening provided with a branch valve, and the glass or ceramic inner container (4) and the outer case ( 2), a heating device (1) with a water accommodation cavity is provided, and the heating device (1) supplies water in the glass or ceramic inner container (4) to the heating device (1). A water inlet that communicates with the water transport device (5) to be transported and the water supply device (3) through a water supply control member, and water in the heating device (1) through the circulation control member is transferred to the glass or Ceramic content A water supply port (1A-9, 1A-10, 1B-8) communicating with the circulation return passage (9) returning to (4) is provided, and the water transport device (5) is the glass or ceramic inner container An electric pot comprising a water transport passage (5-1) communicating with a branch valve in the lower part of (4) and a water pump (5-2) provided in the water transport passage (5-1),
The heating device (1) is provided with a water level sensor that detects the amount of water in the cavity, and a temperature sensor that detects the water temperature in the heating device (1),
The water level sensor, the temperature sensor, the heating device (1), the water pump (5-2), the water supply control member, and the circulation control member are electrically connected to the control device, respectively.
An electric kettle characterized by that. One water supply port (1A-9, 1A-10, 1B-8) is provided,
The water supply control member and the circulation control member are the same member, and are configured by one three-way solenoid valve, or two solenoids connected to one three-way valve and two outlets of the three-way valve, respectively. Composed of valves,
The electric pot according to claim 1. The two water supply ports (1A-9, 1A-10, 1B-8) are provided as an external water supply port communicating with the water supply device (3) and a circulation water supply port communicating with the circulation return passage (9). And
The water supply control member and the circulation control member are electromagnetic valves;
The electric pot according to claim 1. The heating device (1) is provided above the glass or ceramic inner container (4), and the horizontal minimum water level in the cavity of the heating device (1) is that of the glass or ceramic inner container (4). At least 10 mm higher than the highest water level,
The electric pot according to claim 1. The water supply device (3) includes a water supply nozzle (3-2) provided in the outer case (2), the water supply nozzle (3-2), and the water supply port (1A-9 of the heating device (1)). 1A-10, 1B-8) and a water supply passage (3-1) communicating with each other,
The electric pot according to claim 1. A gas-liquid separation mechanism is provided in the water supply passage (3-1).
The electric kettle according to claim 5 characterized by things. The heating device (1) is an electric heating body with an electric pan or a water tube,
The electric kettle according to any one of claims 1 to 6, characterized in that The outside of the glass or ceramic inner container (4) is surrounded by a heat insulating and heat insulating layer,
The distance between the heat insulation and heat insulation layer and the glass or ceramic inner container (4) is in the range of 0 to 25 mm.
The electric pot according to claim 1. A water level sensor and an alarm device for preventing the amount of water in the glass or ceramic inner container (4) from being too much or too small are provided on the top and bottom of the glass or ceramic inner container (4), respectively. ,
The electric pot according to claim 1. The electric pot is provided with an emergency power source, and the emergency power source is a battery or a super capacitor.
The electric pot according to claim 1.