KR930011808B1 - Relay circuit of microwave oven - Google Patents

Abstract

This circuit uses a micro processor and a latch to control several relays effectively. This system comprises an operation guarantee means which connects to the central arithmetic unit, a data latch section which transfers series data to parallel data, a relay connecting section, a relay section (15) which posseses several relays for the operation of the subjected relays and a microprocessor (60).

Description

Relay drive circuit of high-performance electric and microwave oven controller

1 is a relay drive circuit diagram of a conventional electric and electronic oven range controller.

2 is a relay drive circuit of the high-performance electric and electronic range controller of the present invention.

3 is a detailed circuit diagram of FIG.

4a and b are operational flowcharts of a microprocessor according to the present invention.

5 is a timing chart of a data latch unit for driving releases RL7, RL10, and RL15 as an example.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a relay driving circuit of a high performance electric and electronic oven range controller, and more particularly, to a driving circuit of a high function electric and electronic oven range controller that is adapted to efficiently control a plurality of relays using a microprocessor and a latch. It is about.

The present invention is a high-performance electric and microwave oven which has many functions such as an automatic door lock, an oven lighting device, a grill device, and an air circulation device inside the oven while having both the microwave oven and the electric oven range. As a driving circuit of the controller which can be applied to the above, in order to control the high-performance electric and electronic oven range as described above, the controller related to the present invention is essentially equipped with a large number of relays. However, when a large number of relays operate at the same time instantaneously, there is a risk of damage to the oven range itself as well as other electric devices using the same power supply due to a sudden load change. Therefore, in order to control a large number of relays and to perform various other control, the output port of the microprocessor used for the control of the relay should be used to the minimum, and the ON / OFF operation of the relay should not be made suddenly at the same time.

As the relay driving circuit of the related art, as illustrated in FIG. 1, the output port PO1 to PO4 of the microprocessor U1 has a transistor Q1 having the emitter grounded through the resistors R1 to R4. Are connected to the base terminals of ˜Q4, respectively, to control ON / OFF operations of the transistors Q1 to Q4, and the collectors of the transistors Q1 to Q4 are connected to the coil terminals of the relays RL1 to RL4, respectively. The remaining coil terminals of the relays RL1 to RL4 are connected to the power supply VD, and diodes D1 to D4 are connected to both ends of the coils of the relays in order to discharge the reverse current caused by the relay coils, and the switch terminals of the relays. Is configured to be connected to the external controllers E1 to E4, respectively. The operation process includes the resistance R1 and the transistor Q1 when the high level is output from the output port PO1 of the microprocessor U1. By the current flowing through the base-emitter Since the transistor is Q1 saturated and the potential difference between the emitter and the collector is eliminated, the current from the power supply VD flows across the coil of the relay RL1, and the relay RL1 magnetized by this current. The iron core inside closes the switch, and power is applied to the external controlled device E1.

On the other hand, when the low level is output from the output port PO1 of the microprocessor U1, the transistor Q1 is turned off and at the same time, the relay RL1 is opened and at this time, the internal coil of the relay RL1 is opened. Induced current generated in the first pass through the diode (D1) to prevent the transistor Q1 is destroyed. In addition, the transistors Q2, Q3, Q4 and the relays RL2, RL3, RL4 controlled by the output terminals PO2, PO3, PO4 of the microprocessor are also controlled by the same method as described above.

The relay driving circuit by the conventional microprocessor having the configuration as described above requires a large number of microprocessor output ports when the number of relays to be controlled is large, preventing various uses of the output port according to the multifunction of the controller. In addition, there is a possibility that the operation of a large number of relays at the same time may cause instability of the power supply and damage other electrical equipment.

The present invention has been made in view of the problems of the prior art, by using a shift register to minimize the output port of the microprocessor necessary for relay control, and to prevent sudden fluctuations in power that may be caused when a large number of relay operations To provide a relay drive circuit of a high-performance electric and electronic oven range controller composed of a microprocessor configured to operate with a constant delay time.

In order to achieve the above object, the relay driving circuit of the high-performance electric and microwave oven controller according to the present invention has an emitter connected to a power supply (-VD) through a resistor (R6) at an output port (MO1) of the central calculation unit (60). An operation guarantee portion 12 connected to the base end of the transistor Q5 being connected and connected to the power supply (-VD) as a resistor R5, and the other output port MO3, of the central operation portion 60; MO4) is connected to the Din and CLK terminals of the shift register U3, whose power terminals V + and V- are connected to ground and -VD power, respectively, and the other output port MO2 of the central operation unit 60. Is connected to the En terminal of the latch U4 having the power terminals V + and V- connected to ground and -VD power, respectively, and the data output port of the shift register U3 is the data bus line SL1 to SL11. Is connected to the data input port In of the latch U4 through the output port 01 to 011 of the latch U4. The data latch unit 13 is connected to the anode input terminals of the photocouplers PC1 to PC11 through the terms R7 to R17, and the cathode terminals of the photocouplers PC1 to PC11 are connected in common to the collector of the transistor. And the emitter terminals of the photocouplers PC1 to PC11 are all connected to the ground line of the relay in common, and the collector terminals of the photocouplers PC1 to PC11 are connected to one terminal of the relay. One end of the relay is connected to the collector of the photocouplers PC1 to PC11, and one end of the internal coil is connected to the other end of the relays RL5 to RL15 connected to the relay power supply VR. The relay unit 15 is configured to be connected to the relay power supply VR as the diodes D5 to D15 in the state.

Hereinafter, an operation process of the present invention will be described with reference to the accompanying drawings.

2 shows a block diagram of a relay driving circuit according to the present invention, and FIG. 3 shows a detailed circuit diagram of FIG.

The internal operation sequence of the central operation unit 60 is as shown in the attached 4a, b diagram. When the program is started, it is first checked whether the user has selected the cooking function (step 100), if NO, the initial state is returned, and if it is YES, in the next step 200, the relay to be increased according to the cooking function (coding) is selected. To enable interrupt entry (step 300). When the interrupt is executed (step 301). The counter 1 is incremented (step 302), and it is checked whether the clock state is "high" (step 303). If the result of the check is NO, the relay code to be increased is shifted right (step 304), and then it is checked whether the first bit is # 1 (step 305). If the check result in step 305 is NO, switch Din to Fellows (step 307), and then proceed to step 308, if the check result in step 305 is YES, check Din. Transition to, then switch the CLK state to ＂high (step 308) and return. In the step 302, it is checked whether the clock state is "high", and if it is YES, the CLK state is switched to the low (step 309), and then it is checked whether or not the counter = 11. (Step 301). If the check result of step 310 is NO, it returns to the initial state. If the check result is YES, interrupt entry is disabled (step 311), and then it returns to the initial state. According to the above procedure, the central operation unit 60 sends a square wave signal having a shape as shown in FIG. 5 through the output port MO4 to the CLK input terminal of the shift register 43 to generate the negative edge of each square wave. The shift register M3 shifts the serial signal, which is sent to the output port MO3 of the central operation unit 60, by one bit.

By the above-described method, the central operation unit 60 transfers 11 bits of ON / OFF state data of the relays RL5 to RL15 to the shift register U3 in parallel data form. When this operation is completed, the central operation unit 60 is completed. ) Outputs the high signal to the En terminal of the latch U4 using the output port MO2 to latch the relay ON / OFF data held by the shift register U3 through the data service SL1 to SL11. U4). The 11-bit serial relay ON / OFF data transferred from the central operation unit 60 to the data latch unit 13 by the above method is converted into parallel data in the data latch unit 13 to the relay connection unit 14. Delivered. In addition, the microprocessor U2, which is the central computing unit 60, transmits the signal to the operation guarantee unit 12 as a high level signal that the current state is normal through the output port MO1. Accordingly, the transistor Q5 of the operation guarantee unit 12 senses this signal through the resistor R6, and when the signal is at the high level, the transistor Q5 is saturated and connected to the collector of the transistor Q5. -VD power is transmitted to the cathode (K) terminal of the photocoupler internal light emitting element of the relay coupler 14, so that the relay connector 14 receives the parallel relay ON / OFF data from the data latch unit 13 The relay unit 15 can be linked.

On the other hand, when the output port MO1 of the microprocessor U2, which is the central operation unit 60, is at the low level, the transistor Q5 of the operation guarantee unit 12 is turned off, and the -VD power supply is connected to the relay. By preventing it from being delivered to the cathode (K) terminal of the photocouplers in (14), a malfunction of the relay is prevented in an abnormal state.

Signals of the operating unit 12 and the parallel relay ON / OFF data of the data latching unit 13 transmitted to the relay connecting unit 14 through the above-described process may include light emitting device terminals of the photocouplers in the relay connecting unit 14 ( AK), when -VD power is transmitted from the operation guarantee unit 12, and when the parallel relay ON / OFF data is in a high state, the light emitting element AK of the corresponding port coupler is activated to receive light in the same port coupler. The device CE is turned on, and the operation of the relay connection unit 14 causes the power supply VR to be energized to the coil of the corresponding relay of the relay unit 15, so that the internal iron core of the relay magnetized by the coil closes the switch. Power is applied to both ends of the external controlled device.

Referring to FIG. 5 as an embodiment of the present invention as described above, the operation of the relays RL7, RL10 and RL15 will be described. The central calculation unit 60 transmits the high signal to the output port MO1. 11 clock signals are sent to the CLK terminal of the shift register U3 in the data latch unit 13 to the output port MO4 while the operation guarantee unit 12 informs the operation guarantee unit 12 that the operation is normal. For each clock signal, 11 bits of serial relay ON / OFF data for turning ON the relay RL15 to the output port MO3 of the central processing unit 60 are sent to the Din terminal of the shift register U3 (Fig. 5A step A). ), The data latch unit 13 converts the data into parallel relay ON / OFF data as in the SL1 SL11, and the output port MO2 of the central calculation unit 60 is connected to the En terminal of the latch U4. When the signal is applied, the parallel relay ON / OFF data is transmitted to the relay connecting portion 4 through the latch U4 as shown in 01 to 011 of #A step # 5 of FIG. 5 so that the relay RL15 of the relay portion 15 is transferred. ON. In this state, after a slight time delay, the operation of turning on the relays RL15 and RL10 in the same manner as described above is performed as in step B-step of FIG. 5, and after a certain time delay, the relays RL15, RL10, The operation of turning on the RL7) is completed in the same manner as in " C-step " Therefore, sudden delay in power supply can be prevented by giving time delay to each relay and turning it on and off.

6 is a block diagram of a high-performance electric and microwave oven control device employing a relay driving circuit according to the present invention as an embodiment, the power supply unit 20 for supplying power to the control device, time, A fluorescent display unit 30 for indicating a temperature to a user, a switch / LED input / output unit 40 for accepting a switch input that can be input from the user and displaying the selected cooking function as an LED, and an internal temperature range of the oven during cooking The configuration of the temperature sensing unit 50 configured to detect the sensor through a sensor, a relay driver 10 for driving a heater, a lamp, a motor, and the like, and a central operation unit 60 having a function of collecting and controlling all the above operations. Have

As described above, the relay driving circuit of the high-performance electric and microwave oven controller according to the present invention can efficiently perform various functions by minimizing the output port of the microprocessor required for relay control by using a shift register. By turning on and off with time delay at each relay operation, it prevents the sudden change of power that can be caused when a large number of relays are operated simultaneously to prevent the damage of other electric equipment using the same power.

Claims (4)

A relay driving circuit of a high-performance electric and microwave oven control device having a central computing unit, comprising: operation guarantee means connected to said central computing unit and ensuring normal operation; A data latch means connected to the central operation unit, for converting serial data of the central operation unit into parallel data and outputting the parallel data to relay connection means; Relay connection means for collecting signals from the operation guarantee means and the data latch means; And a relay unit (15) having a plurality of relays for operating said relay by said relay connecting means. 2. The resistor (R5) of claim 1, wherein the operation guarantee means uses the one output port (MO1) of the microprocessor (U2) to indicate that the operation is normal as a high-level signal. Is connected to the power supply (-VD), the emitter is connected to the base of the transistor (Q5) connected to the power supply (-VD) through another resistor (R6), and to the relay connecting means through the collector of the transistor. A relay drive circuit of a high-performance electric and microwave oven control device, comprising: an operation guarantee unit (12) configured to apply (-VD). The method of claim 1, wherein the data latching means connects one output port MO2 of the microprocessor U2 to the latch enable terminal En of the latch U4, and the other output port MO3 to the shift register. Connect to the serial data input terminal (Din) of (U3), connect another output port (MO4) to the clock input terminal (CLK) of the shift register (U3), the data output terminal of the shift register (U3) (Ouit) is connected to the data input terminal (In) of the latch (U4) using the database (SL1 ~ SL11), the power supply (-VD) and ground to the shift register (U3) and latch (U4) A relay drive circuit for a high-performance electric and microwave oven control device, characterized by comprising a data latch unit 13 configured to apply a power supply terminal to the power supply terminals V- and V +. The method of claim 1, wherein the relay connecting means connects the collector terminal of the transistor of the operation guarantee unit 12 and the cathode (K) terminal of each light emitting device of the plurality of photocouplers (PC1 to PC11) in common, An anode (A) end of each light emitting element of the two port couplers is connected to the data output (01 011) of the latch through a resistor (R7 R17), respectively, and an emitter (E) end of each light receiving element of the plurality of photocouplers. Is connected in common to the relay power ground, and the collector (C) terminal of each of the light receiving elements of the plurality of photocouplers, each of the relay connection portion 14 configured to connect to the coil terminals of the relay (RL5 ~ RL15) Relay drive circuit for high-performance electric and electronic oven range controllers.