KR960011458B1 - Weight measuring apparatus in microwave oven - Google Patents

Abstract

The apparatus comprises a weight sensor(3) outputting a frequency signal by sensing the weight of a food and a micom(10) processing the weight of the food by receiving the frequency output signal of the weight sensor with a frequency input terminal(CNTR). The micom(10) comprises a one period counter(15), a control part(11), a first timer(12), a second timer(13), a latch part(14) and a weight judging part(16).

Description

Microwave Frequency Input Weight Sensor

1 is a block diagram of a frequency input weight sensing apparatus of a conventional microwave oven.

2 is a configuration diagram of a frequency input weight sensing apparatus of a microwave oven according to the present invention.

3 is an internal functional block diagram of a microcomputer according to FIG.

4 is a control flow chart of the weight of the microcomputer according to FIG.

* Explanation of symbols for the main parts of the drawings

3: weight sensor 10: microcomputer

11: control unit 12, 13: timer

14 latch portion 15 one cycle counter

16: weight determination unit 17: weight reference value storage unit

S-flag: Start flag

The present invention relates to a frequency input weight sensing device of a microwave oven, and in particular, by using the microcomputer frequency input terminal (CNTR) to input the frequency signal of the weight sensor with a fine resolution to read the weight, and the accuracy of the weight detection The present invention relates to a frequency input weight sensing device of a microwave oven for improving the utilization of a microcomputer.

In general, in a microwave oven, for automatic cooking, the weight of food is sensed, and the automatic cooking is performed by setting a heating time in proportion to the weight.

By the way, there are a number of microwave weight sensing devices are known, and the weight is detected and generated as a frequency signal proportional to the weight, the microcomputer reads the frequency signal to convert the weight, and displays this as well as cooking data Frequency input weight sensing devices to be utilized are known.

Such a frequency input weight sensing device transmits the weight of the food placed on the tray downward through the tray motor shaft for rotating the tray, and changes the distance between the movable electrode pressed by the tray motor shaft and the movable electrode. A capacitive weight sensing device comprising a fixed electrode having a capacitance changed by the known electrode is known. In the case of the capacitive weight sensing device, a frequency signal is oscillated in accordance with a capacitance variable in proportion to the weight of the food. Ecom receives the weight sensing frequency signal and reads the weight. The weight is displayed and used as automatic cooking data.

FIG. 1 is a block diagram of a frequency input weight sensing device of a conventional microwave oven. The weight sensor 3 detects the weight of food and generates a frequency signal accordingly as shown therein, and the frequency of the weight sensor 3. A frequency-to-voltage converter 4 for converting a signal into a voltage, and a microcomputer that receives the voltage of the frequency-to-voltage converter 4 as digital data through an analog / digital conversion terminal (A / D) and reads the weight thereof ( 2), and the microcomputer 2 receives and uses the oscillation frequency of the oscillator 1 as a reference clock signal.

The frequency input weight sensing apparatus of the conventional microwave oven firstly, in the weight sensor 3, when food to be cooked is placed in a tray position installed inside the cavity, the weight of the food to be cooked is detected and the corresponding frequency signal is detected. Will be generated.

Subsequently, a frequency signal proportional to the weight of the food product oscillated by the weight sensor 3 is input to the frequency-voltage converter 4 and converted into a voltage, and the frequency-voltage converter 4 voltage is converted into a microcomputer 2. Is input to the analog / digital conversion terminal (A / D).

Accordingly, the microcomputer 2 receives digital data through an analog / digital conversion terminal (A / D) and reads the weight.

However, assuming that the weight sensor 3 detects a weight of 0 to 2 kg, 2000 steps are required for displaying in 1 g units, 1000 steps are required for displaying in 2 g units, and 400 steps are required for displaying in 5 g units. It is necessary.

Since the analog / digital conversion terminal (A / D) employed in the microcomputer 2 usually includes an 8-bit analog / digital converter, the resolution of the input value is limited to 2 ⁸ = 256 types.

Therefore, if 0-2 kg is divided into 256 and displayed in 7.8 g units, the accuracy is lowered. That is, the weight difference less than 7.8g cannot be distinguished and processed, and its precision falls.

In addition, since the frequency-voltage converter is required, the configuration is complicated, and one of the analog / digital input terminals (A / D) of the microcomputer needs to be used for weight sensing, thereby limiting the application range of the microcomputer.

Disclosure of Invention The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to provide a frequency input weight sensing apparatus of a microwave oven that receives a weight sensing frequency signal directly through a frequency input terminal of a microcomputer and reads the weight with finer resolution. have.

The object of the present invention is to detect the weight and output the weight signal as a frequency signal, and the frequency output signal of the weight sensor is directly input to the frequency input terminal (CNTR) and counted at 2 ¹⁶ resolution to read the weight. By constructing a microcomputer, the object of improving the resolution of the weight detection value and improving the precision of the weight detection is achieved.

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

2 is a configuration diagram of a frequency input weight sensing apparatus of a microwave oven according to the present invention, and FIG. 3 is an internal functional block diagram of a microcomputer according to FIG. 2, and as shown therein, the weight of food to be cooked in a microwave oven. The weight sensor 3 which detects and outputs the signal as a frequency signal, and the microcomputer 10 which receives the frequency output signal of the weight sensor 3 directly to the frequency input terminal CNTR and counts it with 2 ¹⁶ resolution to read out the weight. The microcomputer 10 includes a one cycle counter 15 that counts one cycle time for checking the frequency signal of the weight sensor 3 by counting a predetermined interrupt time (2 m sec), and The control unit 11 controls to receive and count the frequency signal of the weight sensor 3 through the frequency input terminal CNTR during one cycle counting time of the one cycle counter 15, and controls the control unit 11. Start by Flag (S-fla g) a first timer 12 which receives the frequency signal of the weight sensor 3 and counts the frequency, and a second timer 13 which receives the 255 carry signal of the first timer 12 and counts it; And a latch unit 14 for receiving and latching the count output values of the first timer 12 and the second timer 13 in 16 bits, and a weight reference value storage unit based on the latch value of the latch unit 14. It is configured to include the functional blocks of the weight determination unit 16 by reading the weight reference value of 17).

The operation and effects of the frequency input weight sensing apparatus of the microwave oven according to the present invention configured as described above are as follows.

4 is a control flowchart of the frequency input weight sensing apparatus of the microwave oven according to the present invention. As shown in the drawing, first, the microcomputer 10 determines whether it is in the weight sensing mode by starting cooking. If not in the weight sensing mode, the corresponding mode is performed. In the weight sensing mode, the first timer 12 and the second timer 13 are reset by the control of the controller 11, and the start flag (S-flag) is reset. Is turned on so that the frequency signal of the weight sensor 3 is input as the count clock signal of the first timer 12, and the one cycle counter 15 is turned on to count one cycle time.

Subsequently, the controller 11 waits until the count value of the one cycle counter 15 reaches one cycle time (about 400 m sec) for checking the frequency oscillated by the weight sensor 3.

At this time, the first timer 12 counts the frequency input from the weight sensor 3, and when more than 2 ⁸ , outputs one carry signal as a count clock signal of the second timer 13, and again zeros. The count is repeated from. That is, the first timer 12 counts up to 255 and starts counting again from zero. When the count value of the first timer 12 reaches 255, a rounding number is generated and the second timer 13 counts one. Done.

In this process, the weight detection frequency input by the first and second timers 12 and 13 is counted as 16 bits, and the count value of the one-period counter 15 is one cycle time for checking the frequency. When the count is completed by sec, the control unit 11 turns off the start flag, turns off the one-period counter 15, and simultaneously outputs a latch clock signal to the latch unit 14 to output the first timer. The count value of (12) and the second timer 13 are latched to the 16-bit value (0-2 ¹⁶ ).

Then, the weight determination unit 16 reads the weight reference value stored in the weight reference value storage unit 17 based on the latch value latched by the latch unit 14 to read the weight.

For example, when oscillating from 0 to 2 kg at 25KHz-35KHz (= 10KHz), 1g is distinguished in 5Hz units by 10K (= 10000) KZ ÷ 2k (= 2000) g = 5Hz / g Since the frequency can be read out at a resolution of 2 ¹⁶ = 65536 for 400 m sec, using this, it is possible to display 1 g per two count pulses, thus displaying up to about 10,000 g.

As described in detail above, according to the present invention, the weight frequency can be read with a very fine resolution compared with the conventional one, so that the fineness of the weight reading is improved, and the weight can be finely decomposed, so that the heating time can be set finely, and thus the There is an effect that can improve the precision of cooking.

Claims (2)

In a microwave oven having an automatic cooking function, a weight sensor 3 which detects a weight of food to be cooked and outputs it as a frequency signal, and directly inputs a frequency output signal of the weight sensor 3 to a frequency input terminal CNTR. It is composed of a microcomputer 10 for counting and reading the weight by 2 ¹⁶ resolution, the microcomputer 10 is counted by a predetermined interrupt time (2m sec) unit for checking the weight sensor 3 frequency signal 1 cycle counter 15 for counting 1 cycle time, and the frequency signal of the weight sensor 3 is received and counted through the frequency input terminal CNTR during 1 cycle count time of the 1 cycle counter 15. A first timer 12 which receives the frequency signal of the weight sensor 3 through the start flag S-flag under the control of the control unit 11, and counts the frequency; Receives 255 carry signals from 1 timer (12) A latch unit 14 for receiving and latching the second timer 13 to count, the count output values of the first timer 12 and the second timer 13 in 16 bits, and the latch value of the latch unit 14. 2. A frequency input weight sensing apparatus of a microwave oven, comprising: functional blocks of a weight determination unit (16) for determining a weight by reading a weight reference value of a weight reference value bottom part (17) based on the weight reference value. 2. The weight judging unit 16 according to claim 1, wherein the weight judging unit 16 which reads the weight reference value of the weight reference value storage unit 17 to determine the weight based on the latch value latched by the latch unit 14 at a 16-bit value is 0 to 0. When oscillating up to 2kg at 25KHz-35KHz (= 10KHz), 1g is distinguished by 5Hz by 10K (= 10000) HZ ÷ 2k (-2000) g = 5Hz / g, and the weight frequency is 2 ¹⁶ for 400m sec. A frequency input weight sensing device of a microwave oven, characterized by being capable of reading at a resolution of = 65536 and displaying up to about 10,000 g by displaying 1 g per two count pulses.