SK284643B6 - Thermally-insulated vessel with electric heating - Google Patents

Abstract

Thermally-insulated vessel with electric heating concerned the container (1) consists of the glass vacuum biwall inner and outer container (1a, 1b) placed in the cover (3), which encloses the container (1), the lid (4) closing upper mouth (3a) of the cover (3) and the heater (2) placed in the container (1), next part is the operating substratum (11) for the regulation ascent of the heater (2) and the aqua-level detector (10) for the provision of the aqua-level signal to the operating substratum (11).

Description

The invention relates to an electrically heated heat insulating vessel, in particular to an electric heating heat insulating vessel capable of retaining the contents of a vessel, e.g. hot water at the desired high temperature using a low amount of electricity.

BACKGROUND OF THE INVENTION

Up to now, electrical containers intended solely for thermal insulation or containers combining the ability to boil water and maintain its temperature are generally known. E.g. Japanese Published Patent Application No. 109517/1987 not explored deals with an electrical thermal insulating container with a container consisting of an inner and an outer part which are separated by a vacuum (hereinafter referred to as a vacuum double container or a simpler container). On this vacuum double container a lid with a bellows air pump is installed and a heater is installed at the bottom of the container.

The vacuum double container in said heat insulating vessel with electric heating is formed of metal, e.g. Stainless steel, which on the one hand has the advantage that the water heats up rapidly due to the high thermal conductivity of the metals, but on the other hand, the disadvantage is that the hot water also cools rapidly due to the high thermal conductivity. In order to overcome this drawback, conventional electrical insulating vessels use electrical heaters to keep hot water in the container at the desired heater temperature of about 1000 W. Such a high-performance heater produces a large amount of heat and if there is a small amount of water in the container, it quickly boils, which can cause the empty container to heat up. If battery power is required, the high-performance heater consumes a lot of energy and places too high demands on the battery. As a result, it is almost impossible to use batteries as a source for electrical insulating vessels. Consequently, the location where the electric-heat-insulating vessel equipped with a high-performance heater can be used is confined to the interior of buildings with an available external power supply and the device cannot therefore be used as portable.

SUMMARY OF THE INVENTION

These drawbacks can be overcome by a glass vacuum double-walled container equipped with a heater. It is therefore an object of the present invention to provide an electrically heated heat insulating vessel capable of safely and stably maintaining the contents of the vessel at a desired high temperature with low power consumption.

SUMMARY OF THE INVENTION The present invention provides an electrical heating heat-insulating vessel comprising a container comprising a glass vacuum double-walled container housed in a housing enclosing the container, a lid that closes the upper opening of the housing and a heater housed in the container. for controlling the heater output and a water level detector to provide a water level signal to the control substrate.

In a preferred embodiment, the heater has a power input of 1 to 20 W. An example of a low power heater is a light emitting heater, such as e.g. light bulb.

In another preferred embodiment, the heater is disposed at the bottom of the cartridge. In another preferred embodiment, the heater is powered by battery power, e.g. a lithium accumulator serving as a source of electric power for the heater, in particular for a portable heat insulating vessel with electric heating.

In another preferred embodiment, said container is provided with a cable for supplying electrical power to the heater.

The container of the invention has excellent heat insulating properties, which are due to the essential characteristics of the glass vacuum double-walled container, so that the container exhibits a remarkably low temperature drop even immediately after filling the container with water when the drop should be steeper compared to metal vacuum double-walled containers. This low temperature drop allowed the hot water to be kept at the desired temperature by a low-performance heater. As a low-power heater, a light-emitting heater, e.g. a bulb, a lamp whose light also allows the inside of the cartridge to be observed. The low power consumption of the heater allows battery power, especially by the battery, and the vessel can therefore also be used from outside buildings after installing the batteries.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 is a cross-sectional view of an electrical thermal insulating vessel of the invention.

In FIG. Figures 2 and 3 are individual cross-sections showing various equipment of the electrical thermal insulation vessel of the invention.

Fig. 4 shows a comparative graph of the decrease in temperature of hot water stored in the electrical thermal insulating vessel of the invention and the values for a conventional metal thermal insulating vessel versus time.

Fig. 5 shows the time change in the temperature of the hot water in the vessel at a constant value for the supply of electrical energy to the electrical heat insulating vessel of the invention.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1, the glass vacuum double container container 1 and the low power heater 2 are housed in the housing 3 and the upper opening 3a of the housing 3 is closed by the lid 4. As the lid 4, a conventional air pump container lid containing an operating button 5 is used. 6, a gasket 8 with an air inlet path with a check valve 7a and a through pipe 9.

The cartridge 1 is made of glass material, e.g. borosilicone glass, so that the inner container 1a and the outer container 1b are joined at their open ends and form a double container with a metal-coated surface. Examples of metal coating materials include conventional materials such as gold, silver, aluminum and titanium. The enclosed space 1c between the inner container 1a and the outer container is maintained in a vacuum state, the value of which is about 10 ³ to 10 ⁴ mm of mercury.

The lower opening of the container 1e is formed in the lower part of the container as a connection between the reservoir 1d in the container 1 and the outer surroundings of the container 1. The open ends of the inner container 1a and the outer container 1b are connected around the lower opening 1e. A protective cover 15 protecting the heater part 2 is placed in the lower opening le and this protective cover 15 is airtightly sealed in the lower opening le against the container 1 with sealing material 17. Illumination allowed by the heater emitting light in the heater part 2 e.g. The protective cover 15 need not be made of glass; the material may be a metal such as e.g. stainless steel or aluminum. As the sealing material 17, for example, silicone rubber, fluorine rubber, ethylene-propylene rubber, etc. may be used. Instead of the sealing material 17, as an alternative, sealing the space 1c by direct connection or metal sealing with the glass of the inner container 1a, the outer container only with the protective cover 15 can be used.

Part 2 comprises a light emitting heater and an integral temperature measuring device together with a portion of the protective cover 15 penetrating into the reservoir 1d in the reservoir 1. Power is supplied to the heater portion 2 externally through the control substrate 11, power supply connector 12, power cable 13 and As an illuminating heater, e.g. the control filament lamp used for the electrical equipment, the normal filament lamp, the halogen filament lamp or a filament lamp filled with noble gas (eg argon, krypton or xenon). The lamp which can be used in the present invention can be e.g. a bulb such as a tungsten bulb and various light-emitting lamps such as a voltage. arc lamp, glow lamp, mercury lamp and fluorescent lamp. In FIG. 1, a tungsten lamp used directly as an electric lamp is directly electrically connected to the built-in conductor. The heater may be a filament lamp containing a screw cap or a filament lamp which can then be easily replaced.

The heater forming the heater part 2 in the present invention may be different from the light emitting heaters mentioned in the above examples. A heater is used which consumes a relatively small amount of energy, generally 1.0 to 20 W, preferably 1.2 to 10 W, and optimally

1.5 to 5 W. An example of a temperature measuring device in the heater part 2 is a thermistor, an IC temperature sensor and a thermocouple.

The plug 8 closing the top opening of the cartridge 1 is airtightly closed by close contact with the end of the inner edge of the top opening of the cartridge 1. A water level detector 10 which measures the level of hot water in the cartridge 1 is provided with part 3. a protective cover 15 so as to allow detection of the hot water level in the container. In the hot water detector 10, an electrode method based on changes in electrostatic capacity or electrical resistance between opposing electrodes corresponding to varying water volumes can also be used, or a pressure method based on pressure changes corresponding to different water volumes can be used.

In the electrical insulating vessel of FIG. 1, the electrical power is supplied from the outside to the heating part 2 via the cable 13. The invention is not limited to the present type, the inside of the housing 3 may be equipped with batteries instead of the electric cable 13 to solve the situation when it is difficult to provide the external source. for example. when using outdoors. The electrical insulating container containing the batteries can be used anywhere, can be taken out and placed anywhere. Secondary cells are preferred as batteries. Secondary cells include, for example, a nickel-cadmium battery, a nickel-hydrogen battery, and a lithium battery. A lithium battery generally has a high capacity and even a small battery is sufficient. The lithium battery is therefore particularly suited to the portable electrical thermal insulation container. The lithium battery ba should have contained a lithium metal compound as the active electrode positive material and a carbon alloy or lithium as the active electrode negative material.

The temperature value measured by the temperature measuring device and the water level value detected by the water level decoder 10 enter the control substrate 11. The control substrate 11 controls the output of the heater based on the input data and outputs information to turn the power, temperature and water levels on and off display 16, which may be of liquid crystal. The control substrate 11 may also prevent empty containers from overheating and may control the output of the heater to avoid electrical overload.

In various modifications of FIG. 2 and 3, the same reference numerals as used in FIG. First

In FIG. 2, the container 1 of the glass vacuum double container and the ceramic heater part 2 are placed in the housing 3 and the opening 3a of the container 3 is closed by the lid 4. The heater part 2 comprises its own heater 2a and a temperature measuring device 2b. The heating portion 2a and the water level detector 10 are disposed at the absorption end 9a of the through tube 9 that is in the container 1. Such an immersion type electrical heat insulating vessel can be manufactured using an easy-to-process single-mouth glass bulb.

In FIG. 3, the heater portion 2 and the water level detector 10 in the end portion, shown in dashed lines, are immersed in the reservoir from the upper portion, and the heater portion is positioned at the absorbent end of the through tube 9. This heater portion 2 comprises a lamp serving as a heater. The opening 3a of the cover of the container 3 is covered by the lid 4.

In FIG. 4 shows the temperature change curve 1 of the hot water in the vessel when the electrical thermal insulation vessel of FIG. 1, whose volume is 2.2 liters, poured 2 liters of hot water (whose temperature is 92 ° C) and the vessel was left at room temperature (25 ° C) without the heater turned on. The curve 2 shows the time change of the temperature of the hot water in the vessel when the electrical thermal insulation vessel of FIG. I, whose volume was 1.9 l, poured 1.5 l of hot water (temperature 92 ° C) and the vessel was left at room temperature (25 ° C) without the heater being switched on. Curve 3 shows the time variations in the temperature of the hot water in the vessel as in the case of the measurement of curve 1, but in this case a stainless steel electric heat insulating vessel for cooking was used.

As can be seen from FIG. 4, the stainless steel cooking vessel (curve 3) had a sharp drop in hot water temperature 2.5 hours after the start of the test as compared to the electrical insulation vessels of the present invention (curve 1 and curve 2). While the temperature drop shown on curve 3 then stabilized somewhat, the temperature nevertheless dropped more rapidly than in the containers of the present invention. In contrast, the temperature drop of the hot water in the containers of the present invention was gradual.

The electrical power W required for the heater of the invention to maintain an initial temperature (92 ° C) of hot water by activating the heater in the heater part 2 is obtained from the following equation (1):

_λ 4.1855 μ (cc) × ° (° C) _m

W (watt) = -------- i— ^L (ú t (min) where t is the time in minutes, μ is the volume of hot water in cm ³ and ΔΤ is the temperature drop in ° C compared to the initial value .

In the present invention, the electrical power (W) required for the heater should satisfy the equation (2) and the volume of hot water μ in cm ³ should be in the range of 300 cm ³ to 3500 cm ³ .

1.98 x 10 ' ³ μ <W <6.67 x ΙΟ ³ μ (2)

In the electrical thermal insulation vessel of the invention (μ = 2000 cm ³ ), the heating section required a power input of 2.6 W and curve 1 shows that 18 hours (t = 1080 minutes) from the start of the experiment the temperature dropped by ΔΤ = 20 ° C. comparison with the temperature at the start of the test. In an electrical thermal insulating vessel whose volume μ = 1500 cm ³ required 3.1 W for the heating section and curve 2 shows that the temperature dropped by ΔΤ = 31.5 ° C 18 hours (t = 1080 minutes) from the start of the experiment. compared to the temperature at the start of the test. In contrast, in a stainless steel electrical insulating vessel (μ = 2000 cm ³ ), heaters with much higher energy of 31 W, as shown in curve 3, were required to compensate for the rapid temperature drop (ΔΤ = 9 ° C).

FIG. 4, it is evident that a conventional stainless steel cooker with a cooker required more energy to maintain a constant high temperature, since the hot water cooled very quickly in the initial phase after pouring. In contrast, the electrical heat insulation vessel of the present invention consumed only about 3 W of energy to maintain a constant high temperature.

Fig. 5 shows changes in the temperature of the hot water in the vessel when a constant amount of energy is supplied to the electrical thermal insulation vessel of the invention, wherein in the electrical thermal insulation vessel of 2.5 liters, FIG. 1, 2 L of water (92 ° C) was maintained and the water temperature was maintained using a 3.5 W lamp. As a result, the temperature immediately increased slightly after the start of the test and was then maintained at a constant value (92 ° C) as shown in FIG. While the invention has been described in detail in relation to the thermal insulation of hot water, the invention can be utilized e.g. to keep the food warm.

The electrical heat insulating vessel of the present invention has excellent heat-retaining capability and can safely conserve hot water with a small amount of energy using a low-power heater. The lighting effect of the heater lamp makes it possible to observe the contents of the container, and another effect is a clear indication of the presence of the contents of the container, even in the dark.

The heat insulating container of claim 3, wherein the light-radiating heater is a lamp.

A heat insulating container according to claim 1, characterized in that the heater is located at the bottom of the container (1).

6. Thermal insulation marking the battery power.

7. The thermal insulation marking is lithium secondary.

Thermal insulating means marked with an electrical cable (13) for power supply.

vessel by vessel by vessel by vessel by

Claims (2)

PATENT CLAIMS An electrical heating heat insulating vessel comprising a container (1) comprising a glass vacuum double-walled inner and outer container (1a, 1b) housed in a housing (3) that surrounds the container (I), a lid (4) that closes the upper an opening (3a) of the housing (3) and a heater (2) disposed in the container (1), further comprising a control substrate (II) for controlling the output of the heater (2) and a water level detector (10) to provide a signal on the water level of the control substrate (11). 2. Thermal insulation marking kon 1 to 20 W.