KR20170067998A - An induction range - Google Patents

Abstract

[0001] The present invention relates to an induction range, and more particularly, to an induction range having a cooling device capable of cooling a tempered glass, the induction range comprising: a body provided with a working coil; And a tempered glass provided on the upper side of the working coil 200 while cooling channels 100, 110 and 120 are formed in the inside of the heating coil 200. Even if the temperature of the tempered glass can not be visually confirmed after cooking, There is a strong point that the risk of burns can be prevented because the cooling can be performed, and the cooling flow path has a circulation structure, so that there is no need to additionally supply unnecessary cooling water or the like, which is economical advantage.

Description

An induction range

The present invention relates to an induction range, and more particularly, to an induction range having a cooling device capable of cooling the tempered glass.

The induction range is a cooking appliance that does not consume oxygen compared to the gas range and does not emit waste gas and prevents indoor air pollution and room temperature rise.

The induction range is an energy-efficient and highly stable technology because it adopts indirect heating method that induces heat to the object itself.

The operation principle of the induction range will be briefly described. When alternating current flows through a coil under the heating target, which is a cooking material contained in the cooking vessel, an alternating magnetic field is formed according to the Amper circuit principle.

This alternating magnetic field concentrates on the material to be heated with a high magnetic permeability and forms an eddy current in the heating target according to the Faraday's law of induction. The eddy current and the resistance of the heating target cause the heat to be generated and the food is cooked.

While the induction range is activated and the food is cooked, the cooking vessel receives heat from the object to be heated and is heated together.

Therefore, after the cooking is completed, the temperature of the tempered glass itself becomes considerably high due to the heat received from the cooking container.

The top plate of the induction range is usually formed of tempered glass or the like, but there is no visual change in the tempered glass during heating.

Accordingly, there is a problem that when the conventional induction range is used, there is a high risk of burning by touching a hand in a state in which the temperature state of the heated tempered glass can not be visually recognized.

(Patent Document 1) KR944001 B1

(Patent Document 1) KR1288551 B1

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide an induction range for preventing the risk of burning of tempered glass by cooling tempered glass heated after cooking have.

According to an aspect of the present invention, And a tempered glass disposed above the working coil 200 with cooling channels 100, 110 and 120 formed therein.

The main body is provided with at least one cooling fluid supply unit communicating with the cooling passages (100, 110, 120), and the pumps (310, 320) are connected to the cooling fluid supply unit to supply the cooling fluid to the cooling passages (100, 110, 120). And an inductance range including the inductance range.

The cooling fluid supply unit includes a first cooling fluid supply unit 410 connected to one side of the cooling flow channels 100, 110, and 120; And a second cooling fluid supply part (420) connected to the other side of the cooling flow paths (100, 110, 120), the pump including: a first pump (310) connected to the first cooling fluid supply part (410); And a second pump 320 connected to the second cooling fluid supply part 420 so that the cooling fluid flowing through the cooling flow paths 100, 110 and 120 flows through the first cooling fluid supply part 410 and the second cooling fluid supply part 420, And an induction range which is circulated between the induction motor and the induction motor.

A plurality of working coils (200) are formed on the main body as many as the number of cooking vessels to be stacked on the main body at a time, and the cooling channels (100, 110, 120) And may provide an induction range in which the cooling fluid is provided to the cooling flow paths 100, 110, and 120 at positions corresponding to the working coil 200 to which electricity is applied, of the working coil 200.

In addition, the main body further includes a sensor and a control unit connected to each other so as to be able to transmit signals, wherein a cooking vessel, which is placed on the tempered glass from the sensor after the power is supplied to the working coil 200, The control unit controls the cooling fluid to supply the cooling fluid to the cooling passages 100, 110, and 120. [0033] FIG.

The present invention as described above has the following effects.

First, even if the temperature of the tempered glass can not be visually confirmed after cooking, it is possible to cool the tempered glass, thereby preventing the risk of burn.

Second, since the cooling channel has a circulation structure, unnecessary supplementary cooling water or the like is unnecessary, which is economically advantageous.

Third, since the cooling channel can be independently driven according to the number of working coils, it is possible to prevent unnecessary cooling of the tempered glass part, thereby making it possible to rapidly heat the other working coil parts when they are being cooked.

Fourthly, since the tempered glass portion can be automatically cooled through the cooling channel in the portion corresponding to the cooked working coil, more efficient cooling can be performed.

1 is a top view of an induction range according to a preferred embodiment of the present invention.
2 is a side sectional view of an induction range according to a preferred embodiment of the present invention.
3A and 3B show a first flow path and a second flow path, respectively, according to a preferred embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, the definitions of these terms should be described based on the contents throughout this specification.

FIG. 1 is a top view of an induction range according to a preferred embodiment of the present invention, and FIG. 2 is a side sectional view of an induction range according to a preferred embodiment of the present invention.

As shown in FIG. 1, at least one working coil 200 may be provided in the induction range according to the preferred embodiment of the present invention so that a plurality of cooking vessels can be raised and cooked.

A working coil 200 is installed in the main body of the induction range.

The working coil 200 is also disposed under the tempered glass g, also referred to as a hot plate.

In other words, the tempered glass g is provided on the upper side of the working coil 200 with the cooling flow passage formed therein.

The main body is provided with at least one cooling fluid supply portion communicating with the cooling flow passage.

The pump is connected to a cooling fluid supply to provide cooling fluid to the cooling flow path.

More specifically, the cooling fluid supply unit includes a first cooling fluid supply unit 410 connected to one side of the cooling channel, and includes a second cooling fluid supply unit 420 connected to the other side of the cooling channel.

The pump may include a first pump 310 connected to the first cooling fluid supply unit 410 and a second pump 320 connected to the second cooling fluid supply unit 420.

The cooling fluid may be provided with water, cooling water or other refrigerant, and does not exclude air or cooling gas.

The pump may be a water pump or an air pump.

The cooling fluid is circulated between the first cooling fluid supply part (410) and the second cooling fluid supply part (420) connected to the cooling flow path.

More specifically, a first pump 310 is connected to the first cooling fluid supply unit 410 and a second pump 320 is connected to the second cooling fluid supply unit 420, .

A working coil 200 may be disposed between the first pump 310 and the first cooling fluid supply 410 and between the second pump 320 and the second cooling fluid supply 420.

The cooling passage 100 includes a first cooling passage portion 101 communicating with the first cooling fluid supply portion 410 and a second cooling passage portion 105 communicating with the second cooling fluid supply portion 420 The first cooling passage portion 101 and the second cooling passage portion 105 are fluidly connected to the main cooling passage portion 103.

The main cooling channel portion 103 is a flow path passing through the upper end of the working coil 200 from the tempered glass g.

In other words, the main cooling passage portion 103 passes the upper end of the working coil 200.

The cooling fluid flows sequentially from the first cooling fluid supply part 410 to the first cooling flow path part 101, the main cooling flow path part 103 and the second cooling flow path part 105 by the first pump 310 The cooling fluid is supplied from the second cooling fluid supply part 420 to the second cooling fluid supply part 420 by the second pump 320 after the tempered glass g is cooled, The tempered glass g can be once again cooled by sequentially passing through the first cooling channel portion 105, the main cooling channel portion 103 and the first cooling channel portion 101. [

Thus, the cooling fluid is a structure capable of circulating through the cooling passage until the tempered glass g is cooled.

The cooling fluid of the first cooling fluid supply part 410 and the second cooling fluid supply part 420 may be exchangeable.

Although not shown, the first pump 310 and the second pump 320 may be provided with any one of the induction ranges to circulate the cooling fluid in another preferred embodiment of the present invention.

The main cooling channel portion 103 can be formed by being biased toward the upper surface of the tempered glass g, that is, the upper surface on which the cooking vessel p is mounted.

Next, the shape of the main cooling passage portion 103 will be described in more detail with reference to Fig.

The structure of the cooling passage according to a preferred embodiment of the present invention is shown in FIG.

A first guide protrusion 111, a second guide protrusion 112 and a third guide protrusion 113 are formed on the cooling flow path, respectively, between the first pump 310 and the second pump 320, .

A second guide protrusion 112 is formed between the first guide protrusion 111 and the third guide protrusion 113 and between the first guide protrusion 111 and the second guide protrusion 112, And a first flow path 110 is formed between the second guide protrusion 112 and the third guide protrusion 113.

Of course, the first flow path 110 is formed on the left and right sides of the first guide projection 111 and the first flow path 110 is formed on the right and left sides of the third guide projection 113.

The first guide protrusion 111 and the third guide protrusion 113 are bent to have a predetermined curvature and the second guide protrusion 112 is a straight protrusion.

The first guide protrusion 111 has a curved shape bent in a direction away from the center of the second guide protrusion 112 and the third guide protrusion 113 is bent in a direction away from the center of the second guide protrusion 112 And has a curved surface shape.

In other words, the first guide protrusion 111 and the third guide protrusion 113 can have a symmetrical shape with the second guide protrusion 112 as a center.

The cooling fluid can flow from left to right direction by the first pump 310 while cooling the tempered glass g and then flows from the right side to the left side by the second pump 320, (g), and continuous circulation is possible.

The second flow path 120 according to another embodiment of the present invention may be formed in a zigzag shape as shown in FIG. 3B. In FIG. 3B, it is sufficient that each cooling line is formed in a zigzag fashion from the first pump 310 to the second pump 320 without being constrained thereto.

The direction of the cooling fluid flowing on the second flow path 120 can be changed by the first pump 310 and the second pump 320.

Meanwhile, a plurality of working coils 200 according to a preferred embodiment of the present invention may be formed as many as the number of the cooking vessels p to be lifted at one time in the induction range main body as shown in FIG.

At this time, the cooling channel may be independently formed at each position corresponding to the position where the plurality of working coils 200 are installed in the tempered glass g.

Therefore, among the plurality of working coils 200 provided in the induction range, only the cooling flow path corresponding to the working coil 200 to which electricity is applied can be independently operated.

This is because it is possible to prevent the portion of the tempered glass (g) from being cooled in the portion where the cooking vessel (p) is not mounted, thereby improving the heating speed by the working coil 200 at the start of cooking, It is also to reduce waste of power.

According to another preferred embodiment of the present invention, the induction range main body may further include a sensor (not shown) and a control unit (not shown) connected to each other so as to transmit signals to each other.

The sensor (not shown) can confirm the presence or absence of the cooking container p placed on the upper end of the working coil 200 having a plurality of induction ranges.

In other words, in accordance with the working coil 200 installed in the induction range, a zone capable of cooking power, cooking power, and cooking power is formed in the tempered glass g. At this time, So that an independent cooling channel can be formed.

Further, the sensor (not shown) can confirm whether the cooking container (p) is placed in each of the fire power cooking, neutralizing power cooking and digestive power cooking zones of the tempered glass (g).

(Not shown) for measuring the temperature of each zone formed on the tempered glass g and more preferably by controlling the temperature of the tempered glass g in real time by transmitting the temperature of the tempered glass g to the controller (not shown) ) To perform cooling on the portion where the tempered glass (g) needs to be cooled.

When it is detected that the cooking container p placed on the tempered glass g from the sensor (not shown) is removed from the tempered glass g after the power is supplied to the working coil 200 and then stopped again, (Not shown) can control the cooling fluid to be provided as a cooling flow path.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the present invention can be changed.

100:
101: first cooling flow path portion
103: main cooling flow path portion
105: second cooling flow path portion
110: First Euro
111: first guide projection
112: second guide projection
113: Third guide projection
120: the second euro
200: Working coil
310: first pump
320: Second pump
410: first cooling fluid supply part
420: second cooling fluid supply part
g: tempered glass
p: cooking vessel

Claims (5)

A body provided with a working coil 200;
And a tempered glass provided above the working coil 200 with cooling channels 100, 110 and 120 formed therein.
Induction range.
The method according to claim 1,
In the main body,
At least one cooling fluid supply part communicating with the cooling flow paths (100, 110, 120)
Pumps 310 and 320 connected to the cooling fluid supply unit to supply cooling fluid to the cooling passages 100, 110 and 120; / RTI >
Induction range.
3. The method of claim 2,
The cooling fluid supply unit includes:
A first cooling fluid supply part 410 connected to one side of the cooling flow paths 100, 110 and 120;
And a second cooling fluid supply part (420) connected to the other side of the cooling flow paths (100, 110, 120)
The pump includes:
A first pump 310 connected to the first cooling fluid supply unit 410;
And a second pump 320 connected to the second cooling fluid supply unit 420,
Wherein a cooling fluid of the cooling passages (100, 110, 120) is circulated between the first cooling fluid supply part (410) and the second cooling fluid supply part (420)
Induction range.
The method according to claim 1,
A plurality of working coils 200 are formed,
The cooling channels (100, 110, 120)
Wherein the plurality of working coils are independently formed at respective positions corresponding to positions where the plurality of working coils are installed in the tempered glass,
Wherein the cooling fluid is provided to the cooling flow paths (100, 110, 120) corresponding to the working coil (200) to which electricity is applied, of the working coils (200)
Induction range.
The method according to claim 1,
The main body further includes a sensor and a control unit connected to each other so as to transmit signals,
If it is detected that the cooking container placed on the tempered glass is removed from the tempered glass after the power is supplied to the working coil 200 and then stopped again,
Wherein,
And controls the cooling fluid to be supplied to the cooling passages (100, 110, 120)
Induction range.

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