KR101495217B1 - Standby power reduction type electric range - Google Patents

Abstract

The present invention relates to a standby power reduction type electric range. The standby power reduction type electric range comprises: a noise filter unit which removes noises of a power line; a first induction MICOM associated with a first induction heating source; a first rectification unit which rectifies a commercial power outputted from the noise filter unit; a first DC-DC conversion unit which converts a rectified voltage of the first rectification unit to supply an operation voltage to the first induction MICOM; a switching unit which connects the first rectification unit to the noise filter unit; a main MICOM which controls the switching unit; a main rectification unit which is connected to the noise filter unit to rectify the commercial power outputted from the noise filter unit; and a main DC-DC conversion unit which converts a rectified voltage of the main rectification unit to supply an operation voltage to the main MICOM. Thus, a standby power can be reduced.

Description

[0001] Standby power reduction type electric range [0003]

The present invention relates to a standby power reduction type electric range, in which a plurality of PCB-related standby power for driving each of a plurality of induction heating sources is reduced and power supply interference is prevented through ground separation related to a plurality of induction heating sources, To an electric range in which a heating source can be stably driven.

Although an electric range having a highlight as a heat source has been popular, interest in an electric range using an induction heating system is increasing.

A block diagram of an electric range equipped with a plurality of induction heating sources employing such an induction heating method is shown in Fig. 1, a conventional electric range includes an AC power source 110, a noise filter 120, a first induction PCB 130, a second induction PCB 140, and a third induction PCB 150 .

The first induction PCB 130 includes a first rectifying part 132, a first DC-DC converting part 134 and a first micom part 136. The second induction PCB 240 includes a second rectifying part 132, DC converter 144 and the second microcomputer 146. The third PCB 250 includes a first rectifying unit 252, a second DC-DC converting unit 154, And a third microcomputer unit 156.

1, each rectifying section, each DC-DC converting section, and each of the microcomputers is connected to the noise filter section 120 at all times. Therefore, there is a problem that the consumption of standby power is increased by a plurality of rectifying sections connected to the noise filter section 120, a DC-DC converting section, and a micom section. In addition, the microcomputer unit must be integrally connected to the microcomputer unit rather than being separately implemented. In this case, since the ground level is changed by the operation of each microcomputer unit, a malfunction occurs in the microcomputer unit.

In order to solve the above-described problems, it is an object of the present invention to provide an electric range capable of reducing standby power generated by connection of a plurality of PCBs for driving each of a plurality of induction heating sources.

It is another object of the present invention to provide an electric range in which power source interference can be prevented through ground separation related to a plurality of induction heating sources and the induction heating source can be stably driven.

In order to achieve the above object, an electric range according to an embodiment of the present invention includes a noise filter unit for removing noise of a power supply line, a first induction micom unit associated with a first induction heating source, A first DC-DC converter for converting a rectified voltage of the first rectifier to supply an operating voltage to the first induction microcomputer, and a second DC- A main microcomputer for controlling the switching unit; a main rectifier connected to the noise filter unit to rectify a commercial power output to the noise filter unit; And a main DC-DC converting unit for converting the rectified voltage of the rectifying unit to supply the operating voltage to the main microcomputer unit.

The switching unit may include a relay as an element for switching.

The main microcomputer is connected to the first induction microcomputer through the first ground separation interface unit, and the main microcomputer controls the first induction microcomputer unit and the main microcomputer unit, Can be provided.

The first ground separation interface unit may include a photocoupler for ground separation.

The electric range includes a first induction PCB on which the first induction micom unit, the first rectification unit and the first DC-DC conversion unit are disposed, and a second induction PCB on which the main microcomputer, the main rectification unit, the main DC- And a main PCB on which the first ground separation interface unit is disposed.

According to another aspect of the present invention, there is provided an electric range including a noise filter unit for removing noise from a power supply line, a first induction micom unit associated with a first induction heating source, and a rectifier for rectifying a commercial power output from the noise filter unit. A first DC-DC converting unit for converting a rectified voltage of the first rectifying unit and supplying an operating voltage to the first induction micom unit, and a second rectifying unit for connecting the first rectifying unit to the noise filter unit A second induction microcomputer associated with the second induction heating source, a main microcomputer for controlling the switching unit, a second rectifying unit for rectifying the commercial power output from the noise filter unit, And a second DC-DC converting unit for converting the rectified voltage of the rectifying unit to supply the operating voltage to the second inductive micom unit and the main microcomputer unit, It can generate.

The electric range may further include a ground separation interface unit for separating the first induction microcomputer from the ground of the main microcomputer unit and a ground connection interface unit for connecting the ground of the second induction microcomputer unit and the main microcomputer unit. .

The ground separation interface unit may include a photocoupler for ground separation.

The electric range includes a first induction PCB having the first induction microcomputer, the first rectifying unit, and the first DC-DC converting unit, and the second induction microcomputer, the second rectifying unit, and the second DC- A second induction PCB on which a conversion section is disposed, and a main PCB on which the main microcomputer section, the ground separation interface section, and the ground connection interface section are disposed.

A ground line may be provided between the second induction PCB and the main PCB to supply a power supply line for supplying the operation voltage generated by the second DC-DC converter to the main PCB and a ground line.

According to the above-described configuration, the present invention can reduce the standby power generated due to the connection of the plurality of PCBs for driving each of the plurality of induction heating sources.

The present invention can prevent power supply interference and ground the induction heating source stably through ground separation associated with a plurality of induction heating sources.

In addition, according to the present invention, the ground and the ground of the main microcomputer are grounded by any one power source and ground associated with a plurality of induction heating sources, and the manufacturing cost can be reduced while stably driving the induction heating source.

1 is a block diagram of an electric range equipped with a plurality of induction heating sources employing a conventional induction heating method.
2 is a block diagram of a standby power reduction type electric range according to an embodiment of the present invention.
FIG. 3A is a circuit diagram showing a transmission part of the ground separation interface unit shown in FIG. 2. FIG.
3B is a circuit diagram showing a receiving part of the ground separation interface unit shown in FIG.
4 is a block diagram of a standby power reduction type electric range according to another embodiment of the present invention.
5A is a circuit diagram showing a transmission part of the ground connection interface unit shown in FIG.
5B is a circuit diagram showing a receiving part of the ground connection interface unit shown in FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a standby power reduction type electric range according to the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, it is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the technical scope of the present invention. Will be.

2 is a block diagram of a standby power reduction type electric range according to an embodiment of the present invention.

2, the standby power reduction type electric range includes an AC power source unit 210, a noise filter unit 220, a first induction PCB 230, a second induction PCB 240, a main PCB 250, And a switching unit 270.

The first induction PCB 230 includes a first rectifying part 232, a first DC-DC converting part 234, and a first induction micom 236.

The AC power source of the AC power source unit 210 is supplied to the first rectification unit 232 through the noise filter unit 220. The first rectification unit 232 rectifies and smoothes the AC power that has passed through the noise filter unit 220. For this purpose, the first rectifier 232 may be a bridge diode.

The first DC-DC converting unit 234 converts the smoothed DC voltage from the first rectifying unit 232 into the operating voltage required for the first induction micom 236. The first DC-DC converting unit 234 may further generate a reference voltage necessary for the first induction PCB 230 in addition to the operating voltage required for the first induction micom 236.

The first induction micom 236 is related to the driving of the first induction heating source (not shown). The first induction heating source is operated by a first induction driving unit (not shown) as a working coil, and the induction driving unit is controlled by a first induction micom 236. The first induction microcomputer 236 receives a control signal from the main microcomputer 258.

The second induction PCB 240 includes a second rectifier 242, a second DC-DC converter 244, and a second induction microcomputer 246.

The AC power source of the AC power source unit 210 is supplied to the second rectification unit 242 through the noise filter unit 220. The second rectifying unit 242 rectifies and smoothes the AC power having passed through the noise filter unit 220. To this end, the second rectifier 242 may be a bridge diode.

The second DC-DC converting unit 244 converts the smoothed DC voltage from the second rectifying unit 242 into the operating voltage required for the second inductive micom unit 246. The second DC-DC converting unit 244 may further generate a reference voltage necessary for the second induction PCB 240 in addition to the operating voltage required for the second induction micom 246.

The second inductive micom 246 is related to the driving of the second induction heating source (not shown). The second induction heating source is operated by a second induction driving unit (not shown) as a working coil, and the induction driving unit is controlled by a second induction micom 246. The second induction microcomputer 246 receives a control signal from the main microcomputer 258.

The main PCB 250 includes a main rectifier 252, a main DC-DC converter 254, a user interface 256, a main microcomputer 258, a first ground separation interface 260, And an interface unit 262.

The AC power supply of the AC power supply unit 210 is supplied to the main rectification unit 252 through the noise filter unit 220. The main rectifying unit 252 rectifies and smoothes the AC power that has passed through the noise filter unit 220. For this purpose, the main rectifying unit 252 may be a bridge diode.

The main DC-DC converting unit 254 converts the smoothed DC voltage from the main rectifying unit 252 into an operating voltage required for the main microcomputer 258. [ The main DC-DC converting unit 254 can further generate a required reference voltage from the main PCB 250 in addition to the operating voltage required for the main microcomputer 258. [

The user interface unit 256 is an interface unit for receiving a key input from a user and displaying information according to a key input or the like so that the user can check it.

The main microcomputer unit 258 is connected to the user interface unit 256 and receives key input from the user and displays information according to key input or the like so that the user can confirm the key input. When it is necessary to operate the first induction heating source or the second induction heating source according to a user's key input, the main microcomputer unit 258 controls the first induction micom 236 and the second induction micom 246 The control signal can be output to each of the first and second input /

The first ground separation interface unit 260 electrically connects between the main PCB 250 and the first induction PCB 230 while allowing transmission and reception of control signals between the main PCB 250 and the first induction PCB 230. [ It separates and isolates the ground.

The second ground separation interface unit 262 electrically connects the main PCB 250 and the second induction PCB 240 while allowing control signals to be transmitted and received between the main PCB 250 and the second induction PCB 240. It separates and isolates the ground.

The switching unit 270 includes a first switching part 272 and a second switching part 274.

The first switching part 272 includes a switching element that is switched to supply the AC power through the noise filter part 220 to the first induction PCB 230 and the second switching part 274 includes the second switching part 274, And a switching element that is switched to supply AC power having passed through the noise filter unit 220 to the induction PCB 240.

The switching elements of the first switching part 272 and the second switching part 274 are turned on and off by the switching driving signal provided by the main microcomputer 258. [ As the switching element, a relay is preferable.

The first induction PCB 230 and the second induction PCB 240 are connected to the first switching part 272 and the second switching part 274 by the first switching part 272 and the second switching part 274, Is turned on, the consumption of standby power can be reduced.

FIG. 3A is a circuit diagram showing a transmission part of the ground separation interface unit shown in FIG. 2, and FIG. 3B is a circuit diagram showing a reception part of the ground separation interface unit shown in FIG.

3A, the transmission part 300 of the ground separation interface unit, that is, the first ground separation interface unit 260 or the first ground separation interface unit 262 includes a capacitor C1 302, a transistor Q1 304 A photo-coupler PT1 306, and a resistor R1 308. [ Thus, when the control signal outputted from the main microcomputer 258, for example, IH DUTY, is high level, the transistor Q1 304 is turned on, so that current flows through the resistor R1 308 and flows through the resistor R1 308 The light emitting element of the photocoupler PT1 306 emits light and the light receiving element connected to the signal line SIG_I1 310 is turned on. When the light receiving element of the photocoupler PT1 306 is turned on, a low level is supplied to the first induction micom 236 or the second induction micom 246 by the signal line SIG_I1 310. [

3B, the receiving part 350 of the ground separation interface part includes a transistor Q2 352, a photocoupler PT2 354, a resistor R2 356, a resistor R3 358, a resistor R4 360, C2 (362). Thus, a detection signal, for example, IH ON / OFF FB inputted from the first induction microcomputer 236 or the second induction microcomputer 246 is supplied to the transistor Q2 352 by the signal line SIG_O1 364 . If IH ON / OFF FB is at the high level, the transistor Q2 352 is turned on, so that the current flows through the resistor R2 356 and the current flowing through the resistor R2 356 causes the light emitting element of the photocoupler PT2 354 The light receiving element is turned on. Therefore, a low level of the detection signal IH ON / OFF FB is provided to the main microcomputer unit 258.

On the other hand, the receiving part 350 is provided with two operating voltages. That is, the operation voltage AVREF generated by the first DC-DC converter 234 is supplied to drive the light emitting element of the photocoupler PT2 354, and the on / off state of the light receiving element of the photocoupler PT2 354 The operating voltage vref generated by the main DC-DC converting section 254 is supplied to detect the state.

When the standby power reduction type electric range according to the embodiment of the present invention is implemented, since the DC power source and the ground of all the PCBs are separated, stable operation can be performed. However, in practice, each PCB has a rectifying part and a DC- Also, the first ground separation interface unit 260 must have a plurality of transmission parts and a plurality of reception parts, and the second ground separation interface unit 262 is also the same. Therefore, it is necessary to consider not only stable operation but also reduction of production cost.

4 is a block diagram of a standby power reduction type electric range according to another embodiment of the present invention.

As shown in FIG. 4, the standby power reduction type electric range includes a first induction PCB 230, a second induction PCB 240 and a main PCB 400.

The first induction PCB 230 includes a first rectifying part 232, a first DC-DC converting part 234, and a first induction micom 236.

The AC power source of the AC power source unit 210 is supplied to the first rectification unit 232 through the noise filter unit 220. The first rectification unit 232 rectifies and smoothes the AC power that has passed through the noise filter unit 220. For this purpose, the first rectifier 232 may be a bridge diode.

The first DC-DC converting unit 234 converts the smoothed DC voltage from the first rectifying unit 232 into the operating voltage required for the first induction micom 236. The first DC-DC converting unit 234 may further generate a reference voltage necessary for the first induction PCB 230 in addition to the operating voltage required for the first induction micom 236.

The first induction micom 236 is related to the driving of the first induction heating source. The first induction heating source is operated by a first induction driving unit as a working coil, and the induction driving unit is controlled by a first induction micom unit 236. The first induction microcomputer 236 receives a control signal from the main microcomputer 258.

The second induction PCB 240 includes a second rectifier 242, a second DC-DC converter 244, and a second induction microcomputer 246.

The AC power source of the AC power source unit 210 is supplied to the second rectification unit 242 through the noise filter unit 220. The second rectifying unit 242 rectifies and smoothes the AC power having passed through the noise filter unit 220. To this end, the second rectifier 242 may be a bridge diode.

The second DC-DC converting unit 244 converts the smoothed DC voltage from the second rectifying unit 242 into the operating voltage required for the second inductive micom unit 246. The second DC-DC converting unit 244 may further generate a reference voltage necessary for the second induction PCB 240 in addition to the operating voltage required for the second induction micom 246.

The second induction microcomputer 246 is related to the driving of the second induction heating source. The second induction heating source is operated by a second induction driving unit with a working coil, and the induction driving unit is controlled by a second induction micom 246. The second induction microcomputer 246 receives a control signal from the main microcomputer 258.

The main PCB 400 includes a user interface unit 410, a main microcomputer 420, a ground separation interface unit 430, and a ground connection interface unit 440.

The main PCB 400 shown in FIG. 4 does not include the main rectification unit 252 and the main DC-DC conversion shown in FIG. 2, so that the main microcomputer 420, that is, the main PCB 400 is supplied with the DC voltage provided by the second DC-DC converter 244 of the second PCB. A power line for supplying an operating voltage generated by the second DC-DC converting unit 244 to the main PCB 400 and a ground line between the second induction PCB 240 and the main PCB 400, A ground line is provided. If the operating voltage of the main microcomputer 420 is different from the operating voltage of the second induction microcomputer 246, the regulator IC may further include a regulator IC.

The user interface unit 410 is an interface unit for receiving a key input from a user and displaying information according to a key input or the like so that the user can check it.

The main microcomputer unit 420 is connected to the user interface unit 410 and receives key input from the user and displays information according to the key input or the like so that the user can check it. When it is necessary to operate the first induction heating source or the second induction heating source according to a key input of the user, the main microcomputer unit 420 controls the first induction micom 236 and the second induction micom 246 The control signal can be output to each of the first and second input /

The ground separation interface unit 430 electrically isolates the main PCB 400 and the ground of the first induction PCB 230 while allowing control signals to be transmitted and received between the main PCB 400 and the first induction PCB 230 So as to insulate it.

The ground connection interface unit 440 allows transmission and reception of control signals between the main PCB 400 and the second induction PCB 240 and also allows the main PCB 400 and the second induction PCB 240, to be.

The power supply switching unit 450 includes a switching element that is switched to supply AC power that has passed through the noise filter unit 220 to the first induction PCB 230. The switching elements of the power switching unit 450 are turned on and off by a switching driving signal provided from the main microcomputer 420. As the switching element, a relay is preferable.

FIG. 5A is a circuit diagram showing a transmission part of the ground connection interface unit shown in FIG. 4, and FIG. 5B is a circuit diagram showing a reception part of the ground connection interface unit shown in FIG.

5A, a transmission part 500 of the ground connection interface part 440 includes a capacitor C11 502 and a transistor Q11 504. Accordingly, when the control signal outputted from the main microcomputer 420, for example, IH DUTY, is high level, the transistor Q11 504 is turned on, so that the low level is outputted to the second induction microcomputer 246 ).

5B, the receiving part 550 of the ground connection interface part 440 includes a transistor Q12 552, a resistor R11 554, a resistor R12 556, and a capacitor C12 558. [ A detection signal input from the second inductive micom 246 by the signal line SIG_O11 560, for example, IH ON / OFF FB, is supplied to the transistor Q12 552. [ If IH ON / OFF FB is at the high level, the transistor Q2 552 is turned on, so that the low level of the detection signal IH ON / OFF FB is provided to the main microcomputer unit 420. [

The embodiments of the present invention described above are merely illustrative of the technical idea of the present invention, and the scope of protection of the present invention should be interpreted according to the claims. 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 and scope of the invention as defined by the appended claims. It should be interpreted that it is included in the scope of right.

210: AC power supply unit 220: Noise filter unit
230: first induction PCB 232: first rectification part
234: first DC-DC converting section 236: first induction microcomputer section
240: second induction PCB 242: second rectification part
244: second DC-DC converting section 246: second induction microcomputer section
250: main PCB 252: main rectification part
254: main DC-DC converting unit 256: user interface unit
258: main induction microcomputer 260: first ground separation interface part
262: second ground separation interface section
270: switching part 272: first switching part
274: Second switching part 400: Main PCB
410: user interface unit 420: main induction microcomputer
430: Ground separation interface unit
440: Ground connection interface part
450: Power switching unit

Claims (10)

A noise filter unit for removing noise of the power supply line,
A first induction microcomputer associated with the first induction heating source,
A first rectifying section for rectifying a commercial power output from the noise filter section,
A first DC-DC converting unit for converting a rectified voltage of the first rectifying unit to supply an operating voltage to the first induction micom unit;
A switching unit for connecting the first rectifying unit to the noise filter unit,
A main microcomputer for controlling the switching unit,
A main rectifying unit connected to the noise filter unit for rectifying a commercial power output to the noise filter unit,
And a main DC-DC converter for converting a rectified voltage of the main rectifier to supply an operating voltage to the main microcomputer. The method according to claim 1,
Wherein the switching unit includes a relay as an element for switching. 3. The method according to claim 1 or 2,
Further comprising a first ground separation interface unit for grounding the first induction microcomputer and the main microcomputer,
Wherein the main microcomputer provides a control signal to the first induction microcomputer through the first ground separation interface unit. The method of claim 3,
Wherein the first ground separation interface unit includes a photocoupler for ground isolation. 5. The method of claim 4,
A first induction PCB having the first induction microcomputer, the first rectifying unit, and the first DC-DC converting unit;
And a main PCB having the main microcomputer, the main rectifier, the main DC-DC converter, and the first ground separation interface. A noise filter unit for removing noise of the power supply line,
A first induction microcomputer associated with the first induction heating source,
A first rectifying section for rectifying a commercial power output from the noise filter section,
A first DC-DC converting unit for converting a rectified voltage of the first rectifying unit to supply an operating voltage to the first induction micom unit;
A switching unit for connecting the first rectifying unit to the noise filter unit,
A second induction microcomputer associated with a second induction heating source,
A main microcomputer for controlling the switching unit,
A second rectifying section for rectifying a commercial power output from the noise filter section,
And a second DC-DC converting unit for converting a rectified voltage of the second rectifying unit to supply an operating voltage to the second induction micom unit and the main microcomputer unit. The method according to claim 6,
A ground separation interface unit for grounding the first induction microcomputer and the main microcomputer,
Further comprising: a ground connection interface unit to which the ground of the main microcomputer unit is connected to the second induction microcomputer unit. 8. The method of claim 7,
Wherein the ground separation interface unit includes a photocoupler for ground separation. 9. The method of claim 8,
A first induction PCB having the first induction microcomputer, the first rectifier, and the first DC-DC converter,
A second induction PCB on which the second induction microcomputer, the second rectifier, and the second DC-DC converter are disposed;
And a main PCB having the main microcomputer, the ground separation interface, and the ground connection interface. 10. The method of claim 9,
And a ground line is provided between the second induction PCB and the main PCB to supply a power supply line for supplying an operation voltage generated by the second DC-DC converter to the main PCB and a common ground between the second induction PCB and the main PCB. Electric range.

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