KR101006802B1 - Electric hob and method for controlling the same - Google Patents

Abstract

The present invention relates to a cooking appliance and a control method thereof. In this invention, the temperature of a heating source drive part is measured, and the drive level of a heating source is adjusted based on the measured said temperature, and the temperature of the casing space provided with the said heating source is prevented from raising excessively.

Cooking equipment, heating source, control method

Description

Electric hob and method for controlling the same

The present invention relates to a cooking appliance, and more particularly, to an electric hob and a method of controlling the electric hob for cooking food using electricity.

An electric hob is a cooking apparatus which heats food using an induction heating heater or an electric resistance heater. The electric hob is provided with at least one heating source for heating food and a heating source driving unit for driving the heating source.

In the process of performing the heating operation of the heating source, the temperature of the casing space provided by the heating operation of the heating source is increased, and thermal damage to internal components provided in the casing space may occur.

The present invention relates to a cooking appliance, and more particularly, to a cooking appliance and a control method thereof such that the temperature inside the cooking appliance does not exceed a predetermined temperature.

According to an embodiment of the present invention for achieving the above object, the present invention, the casing to form an appearance; A heating source provided in the inner space of the casing; A heating source driver for driving the heating source to an input driving temperature; A detector for monitoring a temperature of the heating source driver; And when the driving temperature of the heating source is equal to or less than an allowable driving temperature set according to the temperature of the heating source driving unit, the heating source driving unit is controlled to drive the heating source to a current driving temperature, and the driving temperature of the heating source is And a control unit which controls the heating source driving unit to drive the heating source to the allowable driving temperature when the temperature exceeds the allowable driving temperature set according to the temperature of the heating source driving unit.

According to the electric hob according to this embodiment as proposed, the temperature of the casing space is excessively increased, it is possible to prevent the internal components such as the conducting wire provided in the casing space from being damaged.

In addition, since the heating operation of the heating source is controlled by indirectly detecting the temperature of the casing space in a relatively high temperature atmosphere and indirectly detecting the temperature of the casing space, damage of the temperature sensing sensor due to the high temperature can be prevented. There is an advantage.

1 is a perspective view showing a disassembled top plate in an electric hob according to an embodiment of the present invention.

Referring to FIG. 1, an electric hob 1 according to an embodiment of the present invention includes a casing 10 forming a bottom surface and an edge, a top plate 20 forming an upper surface, and an inside of the casing 10. The heating source 30 and the control box 40, and at least one conductive wire 70 for supplying power to the heating source 30 and the control box 40 is included.

The casing 10 is formed of a flat hexahedron having an upper surface open, and the casing 10 is formed with a casing space 11 in which the heating source 30 and the control box 40 may be provided.

The top plate 20 forms an upper surface of the electric hob 10 by shielding the opened upper surface of the casing 10. In addition, a cook zone 21 in which a cooking vessel is seated and heated is formed at a position of the top plate 20 corresponding to the heating source 30, and a user input signal at a position corresponding to the control box 40. A control panel 22 is formed to allow input to the control box 40.

The heating source 30, by applying heat to the cooking vessel through the cook zone 21 so that the food contained in the cooking vessel is cooked. The heating source 30 may be, for example, a radiant heater.

The control box 40 extracts a signal input through the control panel 22 and controls the heating operation of the heating source 30 according to the signal or an internal algorithm.

On the other hand, during the heating operation of the heating source 30, the temperature of the casing space 11 is raised, the casing space 11 is formed in a high temperature atmosphere, the temperature of the casing space 11 is When the predetermined temperature is exceeded, the conductive wire 70 may be damaged by high temperature.

Hereinafter, the structure which controls the heating operation of the said heating source 30 is demonstrated in detail so that the temperature of the said casing space 11 may not exceed predetermined temperature.

2 is a block diagram of an internal circuit of an electric hob according to an embodiment of the present invention, Figure 3 is a view showing the configuration of the control unit and the relationship between the control unit and the sensing unit and the heating source driving unit.

2 and 3, the electric hob 1 according to the embodiment of the present invention includes a heating source 300 for heating a cooking vessel, a heating source driving unit 200 for driving the heating source 300, and A sensing unit 400 sensing a temperature of the heating source driving unit 200, a control unit 500 controlling the heating source driving unit 200 based on the temperature detected by the sensing unit 400, and And a power supply unit 100 for supplying power to the heating source driving unit 200 and the control unit 500.

The power supply unit 100 is typically an AC power source of 220V-60Hz from the outside, the AC power is supplied to the heating source driving unit 200, so that the heating operation of the heating source 300 is performed.

On the other hand, a DC converter 101 is provided between the power supply unit 100 and the control unit 500. The DC converter 101 converts the AC power supplied from the power supply unit 100 into DC power and supplies the DC power to the controller 500.

The heating source driver 200 may be, for example, an insulated gate bipolar transistor (IGBT) or a triode AC switch (TRIAC), and supply power to the controller 500. And repeating the control to control the driving level of the heating source 300.

Here, the driving level of the heating source 300 refers to a plurality of stages in which the driving temperature of the heating source is preset in each step, and as the driving level of the heating source 300 increases, The drive temperature is also increased. As the driving temperature of the heating source 300 increases, the temperature of the casing space 11 in which the heating source 300 is provided also increases, and the casing space 11 is formed in a high temperature atmosphere as a whole. The driving level of the heating source 300 may be set by a user or may be set according to an internal algorithm of the electric hob 1.

In the process of operating the heating source 300 by the heating source driver 200, when the driving level of the heating source 300 is high, the driving level of the heating source 300 is relatively low. The amount of power supplied from the heating source driver 200 to the heating source 300 is increased. That is, when the driving level of the heating source 300 increases, the absolute amount of the current supplied to the heating source 300 through the heating source driving unit 200 increases. Therefore, due to the resistance of the heating source driver 200 and the current applied to the resistance, the temperature of the heating source driver 200 itself becomes higher than when the driving level of the heating source 300 is low.

When the driving level of the heating source 300 is raised, the temperature of the casing space 11 and the heating source driving unit 200 is also raised, the temperature of the heating source driving unit 200 and the casing space 11 There is a proportional relationship between the temperatures of. At this time, the temperature of the heating source driving unit 200 is formed to be lower than the temperature of the casing space 11 which is a space where the heating source 300 generates heat.

In addition, a heat sink (not shown) is included in the heating source driver 200 to dissipate heat generated by the driving of the heating source 300, and the heat sink is formed of, for example, a metal material.

On the other hand, the detection unit 400 detects the temperature of the heating source driving unit 200 and transmits a signal relating to the temperature to the control unit 500, or in contact with the heat sink of the heating source driving unit 200 , To be positioned in close proximity.

The control unit 500 controls the heating source driving unit 200 to operate the heating source 300 at an input driving level or an allowable driving level, and includes a receiving unit 501, a determination unit 502, and a storage unit. 503 and a transmitter 504.

The receiving unit 501 receives a signal related to the temperature of the heating source driving unit 200 detected by the detecting unit 400, and the signal is input to the determining unit 502.

The storage unit 503 stores a plurality of reference temperature bands for the heating source driver 200 and allowable driving levels of the heating source 300, and stores a plurality of reference temperatures for the heating source driver 200. A band and an allowable driving level of the heating source 300 are input to the determination unit 502. The plurality of reference temperature bands are divided at predetermined intervals between one predetermined temperature and another predetermined temperature. In addition, the storage unit 503 stores the allowable driving level of the heating source 300 so as to correspond to each other for each reference temperature band of the heating source driving unit 200. At this time, the maximum value of the driving level of the heating source 300 is allowed in the reference temperature band of the heating source driving unit 200 in a range in which damage to components installed in the casing space 11 can be prevented. This is stored at the allowable driving level of the heating source 300.

In detail, as described above, the temperature of the heating source driving unit 200 and the temperature of the heating source 300 and the casing space 11 are in proportion to each other. In other words, the temperature of the casing space 11 and the heating source driver 200 is increased or decreased in proportion to the increase or decrease of the temperature of the heating source 300. In the related art, the heating source driver 200 detects an internal temperature of the casing space 11 and operates the heating source 300 within a range in which the internal temperature of the casing space 11 does not reach a predetermined temperature. ) Was controlled. However, the internal temperature of the casing space 11 may exhibit a deviation depending on the sensing position, that is, the distance from the heating source 300. Therefore, there is a disadvantage that the control of the heating source 300 according to the internal temperature of the casing space 11 is incorrect.
In this embodiment, in order to solve this problem, by controlling the operation of the heating source 300 so that the temperature of the heating source driving unit 200 does not reach a predetermined temperature, the heating source casing space 11 The temperature of) is controlled so as not to reach the temperature at which the damage of the components installed therein is of concern. To this end, the maximum value of the allowable driving level of the heating source 300 is set to the allowable driving level of the heating source 300 according to the temperature of the heating source driving unit 200. The driving temperature of the heating source 300 corresponding to the allowable driving level of the heating source 300 is referred to as the maximum driving temperature.

The determination unit 502 extracts a reference temperature band of the heating source driving unit 200 stored in the storage unit 503 and an allowable driving level of the heating source 300 corresponding thereto, and extracts the extracted reference. The allowable driving level of the heating source 300 corresponding to the temperature of the heating source driving unit 200 is determined by comparing the temperature band with the temperature of the heating source driving unit 200.

In more detail, the determination unit 502 searches for a reference temperature band including a temperature of the heating source driving unit 200 among a plurality of reference temperature bands. Next, the determination unit 502 extracts an allowable driving level corresponding to the found reference temperature band, and whether the current driving level of the heating source 300 exceeds the allowable driving level of the heating source 300. Determine whether or not.

In this embodiment, a relatively low allowable driving level corresponds to a high reference temperature band as compared to a low reference temperature band. This means that when the temperature of the heating source driver 200 corresponds to a relatively high reference temperature band, a relatively low allowable driving level is set so that the heating source 300 is allowed to operate at the heating source 300. This is to operate at the following operating level, so that the temperature of the heating source driving unit 200 does not exceed a predetermined temperature.

Next, when the driving level of the heating source 300 exceeds the allowable driving level of the heating source 300, the determination unit 502 determines that the driving level of the heating source 300 is the heating source. A signal is transmitted to the heating source driver 200 through the transmitter 503 so as to be set to an allowable driving level of 300.

On the contrary, when the driving level of the heating source 300 is less than or equal to the allowable driving level of the heating source 300, the determination unit 502 may be configured to maintain the driving level of the heating source 300. The signal is transmitted to the heating source driver 200 through 503.

In this embodiment, the heating source 300 is provided with at least one. When the heating source 300 is provided in plural, each of the heating source driving units 200 connected to the plurality of heating sources 300 and controlling the heating source 300 are independent of each other. By controlling the heating source 300.

Hereinafter, the control method of the electric hob according to the time series order will be described in detail.

4 is a flowchart illustrating a method of controlling an electric hob according to an embodiment of the present invention.

Referring to FIG. 4, first, an on operation of the heating source 300 is performed. In operation S1, the control unit 500 controls the heating source driving unit 200 to control the heating source 300. ) Is operated at the operation level set by the user.

Next, the detector 400 detects the temperature of the heating source driver 200 (S2).

Next, the controller 500 determines the allowable driving level of the heating unit 200 by comparing the detected temperature of the heating source driving unit 200 with the previously stored reference temperature band.

In detail, the control unit 500 extracts an allowable driving level of the heating source 300 corresponding to each of the plurality of reference temperature bands and the plurality of reference temperature bands stored in the storage unit 503, and the heating source. The temperature of the driving unit 200 is compared with the plurality of reference temperature bands. The reference temperature band including the temperature of the heating source driver 200 is searched to determine an allowable driving level of the heating source 300 corresponding to the reference temperature band.

After the allowable driving level of the heating source 300 is determined, the controller 500 determines whether the driving level of the heating source 300 that is operated exceeds the allowable driving level of the heating source 300. (S4)

When the driving level of the heating source 300 is less than the allowable driving level of the heating source 300, the step of maintaining the current driving level of the heating source 300 and measuring the temperature of the heating source driving unit (S2) to determining whether the driving level of the heating source 300 exceeds the allowable driving level of the heating source 300 (S4) is repeatedly performed.

When the driving level of the heating source 300 exceeds the allowable driving level of the heating source 300, the control unit 500 causes the heating source 300 to be the allowable driving level of the heating source 300. In order to operate, the heating source driving unit 200 is controlled. (S5)

Next, it is determined whether the heating source 300 is off (S6), and if the heating source 300 is not off, measuring the temperature of the heating source driver 200 again ( S2) is performed. On the contrary, when the heating source 300 is off, the control of the electric hob is terminated.

Within the scope of the basic technical spirit of the present invention as well as many other modifications are possible to those skilled in the art, the scope of the present invention should be interpreted based on the appended claims. .

According to the electric hob according to the present embodiment, the temperature of the casing space 11 is excessively increased so that internal components such as the conductive wire 70 provided in the casing space 11 are damaged. Can be prevented.

In addition, since the heating operation of the heating source 300 is controlled by indirectly sensing the temperature of the heating source driving unit 200 without directly sensing the temperature of the casing space 11 in a relatively high temperature atmosphere, There is an advantage that can prevent damage to the temperature sensor.

1 is a perspective view showing a disassembled top plate in an electric hob according to an embodiment of the present invention.

2 is a block diagram of the internal circuit of the electric hob according to an embodiment of the present invention.

3 is a diagram illustrating a configuration of a controller and a relationship between a controller, a detector, and a heating source driver;

4 is a flow chart showing a control method of an electric hob according to an embodiment of the present invention.

Claims (10)

A casing forming an appearance; A heating source provided in the inner space of the casing; A heating source driver for driving the heating source to an input driving temperature; A detector for monitoring a temperature of the heating source driver; And When the driving temperature of the heating source is equal to or less than an allowable driving temperature set according to the temperature of the heating source driving unit, the heating source driving unit is controlled to drive the heating source to the current driving temperature, and the driving temperature of the heating source is And a control unit which controls the heating source driving unit to drive the heating source at an allowable driving temperature when the heating source driving unit exceeds the allowable driving temperature set according to the temperature of the heating source driving unit. delete The method of claim 1, The heating source driving unit, the electric hob for driving the heating source in accordance with a predetermined drive level corresponding to the driving temperature in each step. delete The method of claim 1, The control unit, A receiver which receives measurement information regarding a temperature of the heating source driver from the detector; A storage unit for storing reference temperature bands of a plurality of heating source driving units set at predetermined intervals and information about an allowable driving temperature of heating sources corresponding to the plurality of reference temperature bands, respectively; The temperature of the heating source driver is compared with the plurality of reference temperature bands to determine the allowable driving temperature corresponding to the temperature of the heating source driver and to determine whether the driving temperature of the heating source exceeds the allowable driving temperature. Decision unit; And And a transmitter configured to transmit a signal to the heating source driver so that the driving temperature of the heating source is set to the allowable driving temperature when the driving temperature of the heating source exceeds the allowable driving temperature. The method of claim 3, wherein The heating source is provided in plurality in the casing, And the control unit controls the heating source driver corresponding to each of the plurality of heating sources, so that the allowable driving temperature of the heating source is individually determined. (A) a heating source driving unit, driving the heating source to the drive level of the temperature input step by step; (B) a sensing unit, sensing the temperature of the heating source driving unit; (C) determining, by the control unit, an allowable driving level of a predetermined heating source according to a temperature of the heating source driving unit; (D) the control unit determining whether the driving level of the heating source exceeds the allowable driving level determined by the control unit; And (E) controlling, by the control unit, the heating source driving unit to drive the heating source to the allowable driving level when the driving level of the heating source exceeds the allowable driving level. Control method. The method of claim 7, wherein In the step (C), The control unit may extract the allowable driving level of the heating source corresponding to each of the reference temperature bands of the plurality of heating source driving units and the reference temperature band of the heating source driving unit stored in the storage unit, and the temperature and the temperature of the heating source driving unit. And comparing the reference temperature bands to determine the allowable driving level of the reference temperature band that includes the temperature of the heating source driver. The method of claim 7, wherein While the heating source is performing a heating operation, the steps (B) to (E), the control method of the electric hob is performed sequentially sequentially. The method of claim 7, wherein In the step (E), when the drive level of the heating source exceeds the allowable drive level, the current hob control method of the heating source is maintained.

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