The present invention relates to a cooker, and more particularly to a cooker which uses a carbon heater and a controlling method for the same.
A cooker is an electric appliance which heats foods using a radiative heat source and/or a convective heat source and/or a high frequency heat source. Generally, a sheath heater is used as the radiative heat source. However, there is a disadvantage in that it takes a long time to cook foods because power of the sheath heater is low. Also, there is a problem in that the efficiency of heating is substantially reduced, since it takes a long time to cook food by using the sheath heater.
Embodiments provide a cooker, which is configured to heat foods more promptly, and a controlling method for the same.
Embodiments provide a cooker, which is configured to heat foods more efficiently, and a controlling method for the same.
In one embodiment, a cooker including: a cavity in which food is accommodated; a carbon heater which has a wavelength bandwidth of 1.5 ˜2.5 μm where a radiant energy is maximum into the cavity in order to heat the food; a cover that covers the carbon heater from the outside; and a cover provided between an inside of the cavity and the carbon heater that transmits the radiant energy of the carbon heater into the cavity.
In another embodiment, a cooker including: a cavity; a first heater which provides radiant energy at a predetermined wavelength bandwidth used to radiatively heat food accommodated in the cavity; a second heater which provides radiant energy at a wavelength bandwidth different from the radiant energy of the first heater, used to radiatively heat the food; and a cover provided between an inside of the cavity and the first heater for transmitting the radiant energy of the first heater into the cavity.
In further another embodiment, a controlling method of a cooker having a carbon heater and at least one heater, a wavelength bandwidth where a radiant energy is maximum of the carbon heater is different from that of the heater, wherein the carbon heater and the heater are independently operated so that an operating time of the carbon heater and of the heater at least partly overlap.
The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features will be apparent from the description and drawings, and from the claims.
Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. However, it is to be pointed out that the embodiments do not limit the scope of the invention, but on the contrary it has to be understood that many modifications, additions, variations or substitutions may be resorted to the invention, without altering its spirit or departing from its scope of protection, as it is defined in the appended claims.
Referring to
More particularly, the heater, as a grill heater, includes a sheath heater 5, a carbon heater 6 and a halogen heater 7. And, the carbon and halogen heaters 6, 7 are protected by a heater cover 8 at the outside of the cavity 2. Here, a ceramic heater may substitute for the halogen heater 7, or it may also be used together with the halogen heater.
The sheath heater 5, carbon heater 6 and halogen heater 7, as a grill heater, heat foods inside the cavity 2 by using a radiant heating method. The heaters are different from each other in material and heating method. Hereinafter, the heaters will be explained.
First, the sheath heater is formed by compressing a metal protective tube in a state where insulating wires are wired on the metal protective tube in precise intervals and magnesia is filled therein. Therefore, the sheath heater is stable against physical impact from the outside and is able to be bent or processed to various shapes. The sheath heater has been used as a conventional main heater because it has excellent thermal efficiency, mechanical strength, a resistance to vibration and external impact, and excellent durability.
Also, the carbon heater is configured such that carbon wires composed of carbon fibers of specific crystal structure are used as a heating element and they are filled in a quartz glass element and are graphitized. Therefore, the carbon heater has an advantage in that the resistance stability, in particular the age-based resistance stability, is excellent when the carbon wires emit heat as being electrically coupled. There are advantages in that the carbon wire heating element has excellent up-and-down temperature characteristics and good high-temperature durability as well as the flexibility of solid carbon material is excellent when being made of a plurality of fiber bundles and the processing into various structures and shapes can be easily made. Therefore, the heater in which the carbon heater is inserted into a clean support element such as a quarts glass element of high purity together with non-oxidic has more excellent characteristics, since particles are not generated.
The halogen heater, which is a kind of incandescent lamp, is a lamp which suppresses any evaporation of tungsten constituting a filament by injecting halogen material into a glass sphere. In particular, the halogen lamp is made of a quartz glass pipe, which has good heat resistance, of high purity, and halogen element for preventing the degradation of luminous flux and the change of color temperature is inserted into the quartz glass pipe.
Also, the ceramic heater has a construction such that a heating element for forming resistant heat generated by current conduction is embedded into an electrically insulated ceramic having Si3N4 or AlN as a main component. Also, for example, the heating element is formed of a conductive ceramic consisting of silicates, carbonate, boride or nitride such as W, Mo, or a high melting point metal wire such as Wi, W—Re, Mo.
The respective electric heater, used as the grill heater, has a specific temperature range due to construction thereof and characteristic of the heating element. In detail, the sheath heater is adequately adapted to the temperature range of about 800° C., the ceramic heater is adequately adapted to the temperature range of about 1000° C., the halogen heater is adequately adapted to the temperature range of about 2000° C., and the carbon heater is adequately adapted to the temperature range of about 1200° C. If the working temperature of the electric heaters is above the adequate temperature, the heater, in particular the heating element is damaged and the power consumption is increased.
Hereinafter, the characteristics of the grill heater will be explained in detail with reference to the accompanying drawings.
Referring to
Next, referring to
Also, referring to
On these grounds, the carbon heater is optimally used as the grill heater.
Meanwhile, Table 1 described below shows a surface temperature of the respective heater, a temperature increase of the food to be cooked, and the cost of power consumption.
Referring to Table 1, in the case of a carbon heater, a temperature increase of main food is higher than the other heaters. After all, this is to certify that correspondent energy is used for cooking because energy of effective wavelength range is abundant. Further, if food is cooked in a short time, the cooking time will be shortened, and therefore the heating efficiency and energy consumption efficiency of the cooker is expected to be improved.
Meanwhile, as described above, the carbon heater can be used as the most adequate grill heater, however the carbon heater has a working temperature range to some degree, so that the state of food may be differentiated as to how to set up the working temperature range.
An inventor of the invention could find that a wavelength where the radiant energy emitted from the carbon heater is maximized is 1.5˜2.5 μm through a plurality of experimental tests as long as the carbon heater is adequately operated. Accordingly, it is preferable that the carbon heater is selected to be used and is operated to have a wavelength of 1.5˜2.5 μm where the radiant energy is maximum, and a carbon heater 6 applied to a cooker 1 according to this embodiment is operated to have maximum radiant energy at the predetermined wavelength range.
Hereinafter, a controlling method of a cooker according to the first embodiment will be explained in detail with reference to the accompanying drawings.
The controlling method of the cooker according to this embodiment is a controlling method of the cooker, wherein food is cooked more promptly and are good to eat, and unevenly heated regions of the food are eliminated.
As described above, the cooker according to this embodiment has various kinds of grill heaters, since food can be heated in the most adequate way. For example, a heating method of the sheath heater 5, carbon heater 6 and halogen heater 7 will be explained.
Referring to
And then, after the food is done to a degree by operating the carbon heater 6, the sheath heater 5 is operated to heat the surface of the food, thereby changing the color thereof, i.e. browning the food.
Meanwhile, it is also possible to operate all of the heaters at the same time; however, this may disturb an operational stability of the cooker and cause an electric accident because the heaters consume a lot of electricity, and thus this is not preferable. Merely, in order to realize the most adequate operational state, it is preferable that one heater is turned off after the other heater has been activated.
Hereinafter, a cooling method of a heater of the cooker according to the first embodiment will be explained in detail with reference to the accompanying drawings.
Referring to
According to this construction, air flow formed by a fan, which is separately installed in the cavity 2, is introduced into the heater cover 8 via the through-hole 81. And, the air sucked into the heater cover 8 via the through-hole 81 is heated by the carbon heater 6 and is supplied into the cavity 2.
According to the first embodiment, the carbon heater capable of cooking food to be grilled in the most suitable way is provided, and also the other kind of grill heater is further installed to accomplish the cooking more rapidly. By means of this construction, it is possible to considerably reduce the cooking time of food and there is an advantage in that energy efficiency is increased. Also, as the controlling method of the cooker is controlled in accordance with the heating state of food, there is an advantage in that food can be cooked more rapidly and efficiently.
Further, as the structure where the carbon heater 6 is installed is optimally proposed, there are advantages in that contaminants are prevented from being attached to the carbon heater 6 by means of a convection current around the carbon heater and the durability of the carbon heater is improved by the formation of the cover 82.
In the first embodiment, there is a problem in that the thermal efficiency of the cavity is reduced as external air is introduced into the cavity. In order to resolve this problem, a second embodiment proposes a structure that external air is blocked from entering into the cavity and an inner space of the heater cover 8 is cooled by a cooling channel which is independent from the cavity. However, except for the above, this embodiment is the same as the first embodiment, and therefore detailed description of this embodiment will be omitted.
Referring to
Therefore, external air introduced through any one of the through-holes 81 is returned to the outside after cooling off the carbon heater 6. Accordingly, there is little risk that thermal efficiency is decreased as the external air is introduced into the cavity 2. Also, there is no risk that smoke in the cavity 2 is prevented from introducing into the heater cover 8 by the ceramic glass cover 83. Therefore, the carbon heater 6 maintains its uncontaminated state for a long time.
However, in case the ceramic glass cover 83 is applied, it should be considered that radiant energy is apt to be absorbed by the ceramic glass cover 83.
The inventor of the invention measures the transparency of radiant energy against the glass ceramic cover according to the respective grill heater in order to verify this, the result is illustrated in
Referring to
For this reason, it is understandable that the carbon heater 6 is adequately used without the reduction in thermal efficiency, even though the glass ceramic cover 83 is applied. As a comparative example, in case the halogen heater is used, the overall transmissivity is high but the energy absorbed in the object to be cooked is low, and therefore this is not preferable.
Hereinafter, a cooker according to a third embodiment will be explained in detail with reference to the accompanying drawings.
Referring to
The operation of the third embodiment having the configuration as described above will be explained below.
In case the cooling of the carbon heater 6 is required as the cooker is operated, the fan 87 is rotated. By the rotation of the fan 87, the air inside of the cavity 2 is introduced via the intake hole 89, and the air discharged from the fan 87 is introduced into the first cover 85 after flowing through the space between the first and second covers 85, 86. And, the air introduced into the first cover 85 is discharged into the cavity 2.
According to the embodiment as described above, the air inside of the cavity 2 is circulated with the outside thereof, and therefore there is no loss in quantity of heat. Accordingly, heating efficiency is improved and energy consumption efficiency is increased. Also, even though this is not illustrated, contaminants may be preferably prevented from being attached on the carbon heater 6 by installing a filter at any point of a path, through which the air is circulated.
Hereinafter, a cooker according to a fourth embodiment will be explained in detail with reference to the accompanying drawings. However, this embodiment is almost the same as the first embodiment, and therefore the explanation of the non-described parts may be referred to the first embodiment.
Referring to
According to embodiments, the following effects are expected.
First, according to embodiments, a plurality of heaters, in particular carbon heaters, are used to cook food efficiently and rapidly.
Second, according to the embodiments, another heater having a radiant energy of a wavelength different from the carbon heater is used such that food is cooked more efficiently and rapidly.
Number | Date | Country | Kind |
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10-2008-0000552 | Jan 2008 | KR | national |
10-2008-0087605 | Sep 2008 | KR | national |
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PCT/KR2008/007811 | 12/30/2008 | WO | 00 | 12/24/2009 |
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WO2009/091145 | 7/23/2009 | WO | A |
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