KR920004036B1 - Gravity detection apparatus and method thereof - Google Patents

Abstract

The apparatus includes a rotating shaft (27) laterally supported by a supporting frame (26). A lever (28) is pivoted by being driven by the descending motion of a shaft (25d) which is coupled with the shaft (27), and which moves up and down within a certain movement range. A compression coil spring (29) elastically and upwardly supports the lever (28), and the deflection of the spring (29) is converted to an electrical resistance. The signals thus generated are supplied to an A/D converter (34) and to a microprocessor (35) to measure the weight of the cooking stuff.

Description

Food weight sensing device and weight sensing control method of microwave oven

1 is a schematic longitudinal sectional view showing the structure of a conventional apparatus.

2 is a plan view showing the configuration of a conventional apparatus.

3 is an enlarged longitudinal sectional view showing the structure of a conventional apparatus.

4 is an enlarged longitudinal sectional view showing a piezoelectric element which is a main component of a conventional apparatus.

5 is a graph of output voltage of a piezoelectric element, which is a main configuration of a conventional apparatus.

6 is a longitudinal sectional view showing the configuration of the apparatus of the present invention.

7 is a side view showing the configuration of the apparatus of the present invention.

8 and 9 are perspective and specific views of a volume variable resistor which is a main component of the device of the present invention.

10 is a weight sensing control block diagram of the apparatus of the present invention.

11 is a schematic view for explaining the operation of the device of the present invention.

(A) and (b) of FIG. 12 are graphs showing food heating characteristics and thawing heating characteristics according to the weight sensing control method of the present invention.

13 and 14 are side views showing another embodiment of the device of the present invention.

15 is a flowchart illustrating a weight sensing control method of the present invention.

* Explanation of symbols for main parts of the drawings

21: heating chamber 21a: bottom plate

22: rotary table 23: base

25: motor 25d: shaft

26: support 27: center of rotation axis

28: lever 29: compression coil spring

30, 30 ': variable potentiometer 31: rotating shaft

The present invention relates to a cooking weight sensing device and a weight sensing control method of a microwave oven, and are particularly suitable for scale function, no-load operation, automatic defrosting and automatic cooking, and simple and reliable by using a variable potentiometer. The present invention relates to a food weight sensing apparatus and a weight sensing control method of a microwave oven.

Conventionally, various types of apparatuses for sensing the weight of a food placed on a rotating table of a microwave oven are known. US Patent No. 4,683,967 (name: weighing apparatus) will be described as an example.

As shown in Figs. 1 to 3, the rotary table 2 is rotatably provided in the heating chamber 1, which is a space for heating food, and the rotary table 2 has three arms 3a. ) And a supporter 3 composed of a roller 3b adhering to the distal end of the arm 3a and a connecting portion 3c of the center portion.

A motor 5 is fixed to the bracket 4 fixed to the bottom surface of the bottom plate 1a of the heating chamber 1, and the motor 5 is coupled to the support 3 by a coupling 6. The rotary table 2 supported by the support 3 is rotated by the driving of the motor 5, in which the roller 3b of the support 3 is rotated along the same trajectory 7 and the roller ( 3b) is self-rotating separately from the arm 3a.

On the rotational track 7 of the roller 3b, the piezoelectric element device 8 is configured such that the weight of the food placed on the rotary table 2 is transmitted and detected through the roller 3b.

In the piezoelectric element device 8, as shown in FIG. 4, the shock absorber 8b is fixed to an inner portion of the case 8a provided on the lower surface of the front plate 1a, and the base 8c The sensing unit 8d and the protective film 8e are sequentially attached and fixed to the upper surface, and a ball 8f is interposed between the lower side of the case 8a and the protective film 8e, and the ball 8f The upper surface of the corresponding bottom plate 1a has a structure in which a film or a tape 8g is bonded.

On the other hand, a waveguide 10 for transmitting microwaves is provided in the upper portion of the heating chamber 1, and a magnetron 9 for oscillating microwaves is fixed to the rear end of the waveguide 10.

In the figure, reference numeral 11 denotes a case, and 12 denotes a door.

In the conventional device configured as described above, when the magnetron 9 is oscillated, the microwaves are diverged into the inside of the heating chamber 1 through the waveguide 10, and at the same time, the coupling 6 is driven by the driving of the motor 5. The rotary table 2 is rotated by rotating the support 3 connected by

At this time, the roller 3b of the support 3 moves along the same trajectory 7 while receiving the load of the rotary table 2 and the food placed on the rotary table 2, as shown in FIG. 4. The weight is transmitted to the ball 8f while passing through the film or the tape 8g of the piezoelectric element device 8, and the ball 8f is transferred to the sensing unit 8d again to output as shown in FIG. Generate voltage (V).

The film or tape (8g), and the protective film (8e) serves as a protector for preventing foreign substances and contamination, and the shock absorber (8b) serves to help measure the weight in a more stable state.

The rotary table 2 rotated by the driving of the motor 5 as described above takes about 10 seconds in one rotation when a conventional 6 rpm motor is used, and three rollers in one rotation of the rotary table 2 ( 3b) passes through the piezoelectric element device 8 one time at a time, thereby generating three output voltage peak values, and the average value of the three measurements is usually used for weighing. The peak value V has a proportional characteristic.

However, in the conventional apparatus as described above, the rotary table 2 must be rotated in order to measure the weight, and 10 seconds, which is one rotation time of the rotary table 2 of the measurement time, have been difficult. When the food is placed eccentrically on the rotary table 2 when the weight is measured, the load value of the roller 3b is changed, and thus an error occurs even if the measured value is averaged three times.

In addition, the piezoelectric element has a disadvantage in that it cannot be used in a microwave oven with a principle because it cannot be used in a high temperature region of 250 ° C. or higher. If there is a problem such as not able to detect the weight accurately in the sensing unit (8d).

The present invention was devised to solve the above-mentioned conventional problems, and the present invention will be described in detail below with reference to the accompanying drawings.

6 is a longitudinal cross-sectional view showing the configuration of the food weight sensing apparatus of the microwave oven according to the present invention. As shown in the drawing, a rotating table on which the food M is placed on the lower part of the heating chamber 21 as in the related art. (22) is provided so as to be rotatable.

The rotary table 22 has a projection 22a formed on a lower surface thereof, and a bending portion 23a protrudes downwardly on the outer circumferential portion of the base 23, and the rotary table 22 is formed on the outer circumferential edge of the base 23. As the projection 22a of the 22 is seated, the rotary table 22 is stably placed on the base 23.

The motor bracket 24 is welded and fixed to the middle surface of the lower surface of the heating chamber 21, and the motor 25 is fixed to the lower surface of the motor bracket 24.

When the applied voltage is applied to the terminal portion 25a, the motor 25 shifts the driven gear 25c through the drive gear 25b to rotate the shaft 25d fixed to the driven gear 25c, usually about 6 rpm. The shaft 25d is inserted into and fixed in the fixing bushing 23b formed at the lower center of the base 23 through the middle of the motor bracket 24 and the bottom plate 21a. It can be made to elevate to a predetermined height δ of ˜10 mm.

As a result, the rotary table 22 mounted on the base 23 is rotated by the shaft 25d rotated by the driving force of the motor 25.

On the other hand, a support 26 having an N-shaped cross section is fixed to one side of the bottom face of the bottom plate 21a by a usual method such as welding, and the support 26 is rotated in the lateral direction as shown in FIG. The central shaft 27 is arranged in the horizontal direction, and the hinge portion 28a of the lever 28 having a predetermined length is inserted into the rotation center side 27 so that the center shaft 27 can rotate about the rotation center side 27. Is installed.

The lower end of the compression coil spring 29 is fixed to the upper surface of the support 26 opposite to the lower side of the shaft 2d, and the upper end thereof is a lever 28 having a predetermined distance (∫) from the rotation center side 27. ) Is fixed to one side end so that the lever 28 always has a rotational force in the counterclockwise direction.

In addition, as shown in FIG. 7, the volume-type variable resistor 30 is fixed to a side wall of the support 26 by a conventional method such as crimping or screwing, and the volume-type variable resistor 30 is As shown in FIG. 8, a conventional one composed of a rotating shaft 31, a metal contact piece 32, a resistor 33, and several terminals A, B, and C is used.

An extension extending from the rotation shaft 31 of the volume-type variable resistor 30 at the end of the connecting shaft 28b formed at the other end of the lever 28 with a rotation center axis 27 and a predetermined interval ∫ '. The end of the shaft 31 'is fixed so that the rotating shaft 31 of the volume-type variable resistor 30 can be rotated by the rotation of the lever 28.

Accordingly, when the shaft 25d is lowered by the predetermined length δ, the lever 28 rotates clockwise around the rotational center axis 27, and is connected to the connecting shaft 28b of the lever 28. Since the extended shaft 31 'formed on the rotary shaft 31 of the volume variable resistor 30 is fixed, the rotary shaft 31 rotates.

×100)이 증가하게 된다.When the rotary shaft 31 rotates, the volume-type variable resistor 30 comes into contact with the resistor 33 by the metal contact piece 32 fixed to the tip of the rotary shaft 31, as shown in FIG. As the resistance value (

X 100) is increased.

In this case, the resistance value may be classified into D, E, F, and G types as shown in the drawing. In the present invention, the resistance value is greatly changed even with a small change in rotation angle, so that a large signal is obtained. It is preferable to select the fluorine-type variable resistor 30 to change.

Accordingly, as shown in FIG. 10, when the input voltage Vin is applied to the terminals A, B, and C within the range of 5V to 10V, the weight of the food M is measured. According to (W), an output voltage Vout can be obtained from terminals A and B, and the output voltage Vout is converted into a digital signal through the A / D converter 34 and input to the microcomputer 35. The microcomputer 35 is connected to the control panel 36 and the magnetron 37 can be controlled to construct a system for controlling heating.

If described in more detail the effect of the cooking weight sensing apparatus of the microwave oven according to the present invention configured as described above.

만큼 회동하게 된다.FIG. 11 is a schematic diagram for explaining the operation of the present invention. As shown therein, when a food is not placed on the rotating table, the food having a weight of W is placed on the rotating table in a state where δ = 0. When released, the compression coil spring 29 has the formula W = kδ (k: spring constant) in accordance with the hook law. At the same time, when one side end of the lever 28 moves δ- (b) by δ, the axis of rotation of the variable rheostat 30 is moved by the principle of the lever 28.

Will rotate as much.

=0.5kg/mm이내인 압축코일스프링(29)을 사용하며, ∫'=(2∼3)×∫, 즉, δ'=(2∼3)∫인 지렛대(28)를 사용하면, 볼륨식가변저항기(30)의 회전축(31)은 45°정도의 회전각도를 갖게되면, 제 8 도에서 C형의 볼륨식가변저항기(30)를 선택할 경우, 약 40%의 저항변화를 갖게된다.By using the above-described principle, in the present invention, the δ is the maximum 10mm, the weight (W) is within the maximum 5kg (cooking (M) + rotary table 22 + base 33 + shaft 25d) electrons Based on the range, the spring constant K =

When using a compression coil spring 29 within = 0.5 kg / mm, and using a lever 28 with ∫ '= (2-3) × ∫, ie, δ' = (2-3) ∫, When the rotating shaft 31 of the variable resistor 30 has a rotation angle of about 45 °, when the volume type variable resistor 30 of type C is selected in FIG. 8, the rotation shaft 31 has a resistance change of about 40%.

Also, in FIG. 10, when 10 V is applied to the input voltage Vin between the terminals A, B, and C, the output voltage Vout is approximately 4 V (=) proportional to the resistance at the terminals A and B. 10V x 40%) is shown.

Therefore, when the output voltage Vout is transmitted to the microcomputer 35 through the A / D converter 34, the microcomputer 35 normally uses 8 bits, so that the resolution becomes as follows.

Therefore, it is possible to discriminate 4V: 5kg = 0.015V: a a ≒ 19g, that is, 20g units.

If more than 8-bit microcomputer 35 is used it is possible to obtain a more precise discriminating power.

In other words, using 12bit,

Therefore, 4V: 5kg = 0.00098: b b ≒ 1.2g, that is, 1g unit is possible.

On the other hand, the weight (W) of the food (M) detected as described above is the control panel as shown in Figure 10 for use as a no-load operation prevention function, automatic cooking function, automatic thawing function, scale function, etc. 36 and the microcomputer 35 are connected to control the magnetron 37 oscillating high frequency in the microcomputer 35 as shown in FIG.

On the other hand, Figure 15 is a flow chart for explaining the cooking weight sensing control method of the microwave oven according to the present invention, as shown in this, when the power is turned on by applying power, the standby state While waiting for key input, the weight sensor receives a signal and measures the initial weight WO (normally no load).

When the user presses a cooking function selection key such as manual cooking, automatic cooking, automatic thawing, and scale function with or without food on the turntable, the weight sensing device measures W1 (weight). When the user presses the start button to turn on the cooking function, W1-W0 = W2 is calculated and if W2 is less than the reference value (usually close to 0), the controller recognizes no load and powers off for safety. If W1-W0> W2, there is a load, so the user selects the previously selected function.

That is, in the case of the scale function, W1-W0 = W, that is, W is the weight of food, so display is performed.

In the case of the manual cooking function, the heating time is input in the same manner as in the operation of a conventional microwave oven, and heating is performed during the heating time.

In addition, when the automatic cooking function is selected, if the X, Y, Z food keys shown in (B) of FIG. 12 are selected, the heating time (t) is different because the heating time (t) is different depending on the dielectric constant. You must decide.

Therefore, if an experimental constant for food X, Y, Z is inputted in advance, the weight is automatically measured by heating time (t) = W × α (α is the experimental constant of X, Y, Z food). Therefore, automatic cooking is performed by automatically calculating the heating time. In this case, the heating is usually performed at full power, that is, at a high power, for a heating time t.

Also, if the auto thawing function is selected, it is the same as the auto cooking function, but it is thawed at low power to prevent local overheating and the heating time (t) = W × X (X: experiment according to beef, pork, chicken, fish Constant). When the heating is completed, it causes a heat transfer in the food and counts down while displaying the value for a standing time (S), that is, S = W × Y (Y is a constant value) to reach an equilibrium temperature. Therefore, auto thawing time (T) becomes T = t + s (t: heating time, s: waiting time).

13 and 14 show another embodiment of the present invention, as shown in FIG. 13, for fixing the volume-type variable resistor 30 'to the support 26 and the volume-type variable resistor 30'. Is fixed to one end of the lever 28 in the same manner as the volume variable resistor 30 fixed to the other end of the lever 28, the output voltage caused by _a pair of volume variable resistors 30 (30 _a ) The sum or average of (Vout) is transmitted to the A / D converter 34 or as shown in FIG. 14, the conventional linear potentiometer 40 is fixed to the lower surface of the support 26, and For driving the linear potentiometer 40, a rotating lever 41 having a "┏" shape may be used.

Other embodiments of the present invention as described above can also obtain the same operation as the embodiment of the present invention.

The present invention as described in detail above can measure the weight immediately without the need to rotate the rotary table in order to measure the weight of the food placed on the rotating table, even if the weight of the food is transferred to the shaft and the food is eccentric In addition to measuring more precisely, there is an effect that can be applied in an oven range in which a heater is used.

Claims (3)

The shaft 25d of the mutter 25 protrudes from the bottom plate 21a of the heating chamber 21, and the base 23 on which the rotary table 22 is mounted is fixed to the motor 25. In the microwave oven in which the rotary table 22 is rotated by driving of the rotating table 22, the rotary center shaft is fixed to the lower surface of the bottom plate 21a and fixed to the support 26 and the support 26 in the transverse direction. (27) and the lever 28, which is coupled to the rotation center shaft 27 and rotates by the lowering motion of the shaft 25d, which is lifted up and down by a predetermined height δ, and fixed to the lower surface of the lever 28. And a compression coil spring 29 for uplifting the lever 28 and one side wall of the support 26, and the displacement of the compression coil spring 29 is converted into electrical resistance by the rotational operation of the lever 28. It is composed of a volume-type variable resistor 30 to change the output signal (Vout) to the A / D converter (34) connected to the microcomputer 35 Food weight sensing device of the microwave oven, characterized in that. The method according to claim 1, wherein a separate variable volume variable resistor (30 ') is fixed to a predetermined portion of the inner wall of the support (26), and one side end of the lever (28) extending the variable variable resistor (30'). The process of connecting to the conventional method, so that the summed or averaged output signal (Vout) of the volume-type variable resistors (30, 30 ') is transmitted to the A / D converter (34). Water weight sensing device. When the power is on, it detects the initial weight (W0), inputs the cooking function key of manual cooking, automatic cooking, automatic thawing, and scale function to measure the weight (W1) on the rotating table, and turns on the cooking function. If W1-W0> W2 is measured and power off, W1-W0> W2 performs manual cooking, automatic cooking, auto thawing and scale function.If manual cooking function, it heats up for a certain time and scale function. In the case of cooking, the weight of the food is displayed, while in the case of automatic cooking, heating is performed at a high output for a certain heating time (t) according to each dish. After heating the low power, the microwave cooking weight sensing control method, characterized in that for controlling the display while waiting a predetermined waiting time (s).

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