KR100214878B1 - Microwave oven - Google Patents

Abstract

The present invention relates to an infrared sensing device of a microwave oven. Infrared sensing apparatus according to the present invention comprises a sensor case having an infrared sensor and rotatably supported, a rotating means for rotating the sensor case for a predetermined period, and a control means for controlling the rotating and sensing positions of the rotating means. It is configured to include. The control means includes a switching device that operates when the one-way rotation of the sensor case is completed, and a microprocessor that controls the direction of the rotation means according to a signal of the switching device and stops the rotation means at the sensing position of the sensor case. do. The sensor case rotates like a holder having a switching protrusion, and the switching device is operated by the switching protrusion when the one-way rotation of the sensor case is completed, so that the rotation direction of the rotation means is controlled. The rotation means comprises a motor capable of forward and reverse rotation that returns the sensor case to the outermost stop position of the rotation section when the operation of the microwave oven is completed.

Description

Microwave Infrared Sensing Device

1 is a cross-sectional view showing the configuration of a conventional infrared sensor.

2 is a schematic view showing a change in the surveillance area of a conventional infrared sensor.

3 is a perspective view of an infrared sensor according to the present invention.

4 is a schematic view showing a change in the surveillance region according to the present invention.

5 is a front view of the infrared sensing device according to the present invention.

* Explanation of symbols for main parts of the drawings

102 sensor case 103 filter

104: frame 105: frame sidewall

107: frame stopper 110: holder

114: switching protrusion 120: micro switch

130: motor P1: stop position

P2: Starting position Pa: First sensing position

Pb: second sensing position

The present invention relates to an infrared sensing device of a microwave oven, and more particularly, to detect infrared rays generated from food heated in a cavity, a simpler, smaller size, and infrared rays which can protect a sensor from impurities generated during cooking. It relates to a sensing device. In the microwave oven, the infrared sensor detects the infrared rays generated from the object being cooked to determine the cooking degree of the object, and is used to determine the cooking state thereafter.

A conventional sensor device mounted on an infrared see-through hole formed on one side of a cavity of a microwave oven is shown in FIG. As shown in the drawings, a conventional infrared sensor includes an infrared sensor 2 for detecting infrared rays, a light condenser 4 for condensing infrared light on the infrared sensor, and a reflector for reflecting infrared light to the light condenser. 6) and an adjusting device for adjusting the reflector 6.

The adjusting device for adjusting the reflector is to change the monitoring area inside the cavity by adjusting the reflection angle of the reflector 6. The adjusting device includes a leaf spring (8) having the reflector (6) attached to the rear surface, a driving iron piece (10) attached to the leaf spring, a solenoid portion (14) for applying magnetic force to the driving iron piece, and It includes a control unit 18 for controlling the application of power to the solenoid unit 14, the components are mounted inside the outer case 20.

As shown in FIG. 2, the reflector 6 has its inclination changed by the adjusting device, and as the inclination changes, the cooking object placed on the turntable 11 inside the cavity is located. It accurately finds the location and detects the infrared rays. That is, when the reflector 6 has an inclination of the state A, the turntable 11 detects an infrared ray generating state of the object placed on the portion a, and when the reflector 6 has an inclination of the state B, the turntable The infrared generation state of the object placed in region b of (11) is detected. Since the inclination of the reflector 6 to be adjusted to each area is not known exactly where the user placed the object on the turntable 11, the correct position is determined by the reflector 6. You will find.

As described above, in the case of changing the monitoring area by the infrared sensor, the above-described adjusting device is used. For example, in the state where the reflector 6 is currently set to monitor the area a, and it is determined that the position where the object is raised is not the position a because no infrared rays are generated in the portion, the controller 18 causes the solenoid part ( Current is applied to 14). A magnetic field is formed in the solenoid portion 14 by the application of a current, and the driving iron piece 10 is pulled toward the solenoid portion 14 by this magnetic field. Then, the reflector 6 supported by the leaf spring 5 changes the inclination to the B position of FIG. 2 to move the monitoring area to the b position of the turntable 11. Therefore, the infrared rays generated from the object placed at the b position are incident through the see-through hole 1 of the sensor device, and the infrared sensor 2 detects this and the processing as described above is performed.

However, according to the structure of the conventional sensor device configured as described above, the following disadvantages are pointed out. It can be seen at a glance that the sensor device described above is quite complicated in structure. It can be seen that the configuration including the solenoid portion, a control unit for applying power to the power supply, and a structure for supporting the reflector so as to rotate for a certain period is complicated and requires many component parts. This configuration complexity leads to an increase in the production cost of the sensor device itself, and at the same time, as the assembly ability for production is inferior, productivity is limited. In addition, according to the structure as described above, since it is always open to the see-through hole 1, the reflector may be contaminated by steam or the like generated during cooking. Therefore, there is a disadvantage that a problem arises in the accurate detection of infrared rays when used for a long time.

In addition, since the overall size is large, the use of the outside of the cavity of the microwave occupies a lot of space, and at the same time, the sensing area may be different from the initial state due to the deterioration of the elasticity of the leaf spring for long term use. There is also a problem with the reliability of the product. The present invention has been made to solve the above problems, and an object thereof is to provide an infrared sensor device having a simple overall configuration and a small volume. Another object of the present invention is to provide an infrared sensor device that is reliable when used for a long time because it is not contaminated by the material inside the cooking chamber. It is still another object of the present invention to provide a small infrared sensor device as a whole.

Infrared detection device according to the present invention for achieving the above object is a sensor case that is equipped with an infrared sensor, rotatably supported, a rotation means for rotating the sensor case for a certain period, and the rotation and detection of the rotation means. And control means for controlling the position. The control means includes a switching device that operates when the one-way rotation of the sensor case is completed, and a microprocessor that controls the direction of the rotation means according to a signal of the switching device and stops the rotation means at the sensing position of the sensor case. do. The sensor case rotates like a holder having a switching protrusion, and the switching device is operated by the switching protrusion when the one-way rotation of the sensor case is completed, so that the rotation direction of the rotation means is reversed. The rotation means operates to return the sensor case to the outermost stop position of the rotation section when the operation of the microwave oven is completed, and more specifically, constitutes a motor capable of forward and reverse rotation.

Next, the infrared detection device according to the present invention will be described in detail based on the embodiment shown in the drawings. As shown in FIG. 3, the infrared sensing device according to the present invention includes a sensor case 102 in which an infrared sensor is embedded, a frame 104 rotatably supporting the sensor case, and the sensor case 102. It comprises a motor 130 for driving to a desired rotational position, and a switching device 120 for controlling the position for the rotation of the sensor case (102). The sensor case 102 has a built-in infrared sensor (not shown) for detecting infrared rays, and the infrared sensor detects infrared rays incident through the filter 103 mounted at the front thereof. The sensor case 102 is rotatably supported by the frame 104.

Referring to FIG. 5, the sensor case 102 is pivotally supported by being connected to the holder 110 and the shaft 106 with the sidewall 105 of the frame 104 interposed therebetween. 110 is rotatably supported like the sensor case 102 via the shaft 106. A holder stopper 112 for controlling the initial position or the end position of the sensor case 102 is protruded in the holder 110, and the sensing start position of the sensor case 102 is informed on the opposite side of the holder stopper 112. The switching protrusion 114 for giving is formed. On the outside of the side wall 105 of the frame 104, a frame stopper 107 is provided in a protruding state to collide with the holder stopper 112 to inform the end position, that is, the stop position.

And one side of the side wall 105, the micro switch 120 for obtaining a sensing angle of the sensor case 102 is mounted. The actuator 122 of the micro switch 120 is operated by the switching protrusion 114 described above. The sensor case 102 rotatably supported on the frame 104 is rotated by the motor 130. The fifth embodiment shows one embodiment in which the sensor case 102 is rotated by the motor 130. As shown, the drive gear 132 fixed to the end of the rotation shaft 134 of the motor 130 is a driven gear connected to the sensor case 102 through the shaft 106 to the side wall 105 of the frame 104. Is engaged with (106). Therefore, the forward and reverse rotation of the drive gear 132 is directly connected to the rotation of the sensor case. Next, the operation of the infrared sensing device according to the present invention configured as described above will be described. Although not shown, the filter 103 of the sensor case 102 incorporating an infrared sensor is provided at a position corresponding to the sensor see-through hole formed in the cavity of the microwave oven. Infrared sensor according to the present invention always stops when the sensing operation is completed

The filter 103 is located at (P ₁ ), and in this position, the filter 103 is spaced apart from the sensor see-through hole formed in the microwave cavity. Therefore, when the sensing operation is completed, such as the completion of cooking, the filter 103 ) Is returned to the stop position P ₁ , so that impurities in the cavity and residual water vapor do not adhere. The operation of the present invention in this position is explained. When cooking is started in a microwave oven and sensing is started to detect infrared rays generated from an object, the sensor case 102 at the stop position P ₁ is rotated counterclockwise. The counterclockwise rotation of the sensor case 102 is, of course, made by the rotation of the motor 130, and the control of the rotation operation of the motor 130 is performed by the microprocessor 140 of the microwave oven.

When the sensor case 102 rotates counterclockwise to reach the sensing start position P ₂ shown in FIG. 3, the switching protrusion 114 of the holder 110 which is rotated together with the sensor case 102. Presses the actuator 122 of the microswitch 120. At this time, the microprocessor 140 inside the microwave receives a signal indicating that the sensing operation start position P ₂ is reached, and rotates the motor 130 in order to start the sensing operation. With the reverse rotation of the motor 130, the sensor case 104 starts to rotate in the clockwise direction and arrives at the first sensing position Pa. The sensing area by the first sensing position Pa becomes part a in FIG. 4.

That is, in this state, the filter 103 detects whether infrared rays are generated in a region of the turntable 111. At this time, the object of cooking is located in the portion, when infrared is detected, the sensor case 102 is stopped at the first detection position (Pa), and continuously detect the cooking state of the object while detecting the generation amount of infrared microwaves While transferring to the internal microprocessor 140, the subsequent cooking progress is determined. However, if the generation of infrared rays is not detected in the a position, it is determined that there is no object of cooking in the portion, the motor 130 is rotated in the same direction, while the sensor case 102 also rotates in the same clockwise direction The second detection position Pb is reached. In the second detection position Pb, the region to be monitored becomes a portion of the turntable 111 in FIG. In this state, the amount of infrared generation of the object is continuously detected and transmitted to the internal microprocessor 140, and the subsequent cooking progress is determined.

When the cooking is finished, the motor rotates in the same direction as the cooking ends, and the sensor case 102 also rotates clockwise. At this time, if the holder stopper 112 of the rotating holder 110 is in contact with the frame stopper 107, the sensor case 102 reaches the stop position P1 by detecting a signal applied to the motor 130 at this time. The sensor case 102 is stopped by recognizing that it has been performed, and the sensing operation according to the operation of the microwave is terminated. Here, although the sensing area by the sensor case 102 is divided into two on the turntable 111 and the sensing operation is performed at the two positions Pa and Pb, the sensing area is not limited thereto. It is also possible to divide the detection position of the case 102 by a static number and to detect the generation of infrared rays at each detection position. The classification of the sensing position should be determined in consideration of the size of the object to be cooked and the size of the detectable area of the infrared sensor.

As described above, the infrared detection device according to the present invention can expect the following effects. First, the sensor case with a built-in sensor according to the present invention is always returned to a predetermined position, that is, the stop position (P1) as the operation of the microwave oven is completed, at this stop position, the filter 103 is a sensor formed in the cavity It stops at the position completely different from a see-through hole, and after completion of cooking, it is not contaminated by steam or the like remaining in the cavity. Therefore, the filter can always be kept clean, there is an effect that enables the correct operation of the sensor. Substantially, the components constituting the infrared sensing device according to the present invention can be seen that the implementation is simpler than the conventional one.

This simplification of construction is expected to reduce the number of components and to facilitate the assembly process, which is advantageous in terms of production and economical effects, while also increasing productivity. In addition, since the overall volume of the infrared sensing device according to the present invention is smaller than the conventional one, there is an advantage that the spatial efficiency is increased even when mounted inside the microwave oven. And, if necessary, for example, if the water vapor and foreign substances generated in the object of cooking is particularly severe, there is also a convenience that can selectively prevent contamination of the filter by positioning the sensor case to the stop position.

Claims (7)

A sensor case in which an infrared sensor is embedded and rotatably supported; Rotating means for rotating the sensor case for a predetermined period; And a control means for controlling the rotation and the sensing position of the rotation means. According to claim 1, wherein the control means, Switching device that operates when the one-way rotation of the sensor case is completed; And a microprocessor for controlling the direction of the rotation means in accordance with the signal of the switching device and stopping the rotation means at the sensing position of the sensor case. According to claim 2, wherein the sensor case is rotated like a holder having a switching projection, the switching device is operated by the switching projection when the one-way rotation of the sensor case is completed, the rotation direction of the rotation means is controlled Infrared sensor of the microwave oven. The infrared sensor of claim 3, wherein the sensor case is rotatably supported by a frame, and the holder and the switching device are installed outside the side wall of the frame. The microwave detection apparatus according to claim 4, wherein the rotation means returns the sensor case to the outermost stop position of the rotation section when the operation of the microwave oven is completed. 6. The infrared sensing device of the microwave oven according to claim 5, wherein the return of the stop position of the sensor case is stopped by the holder stopper formed on the holder interlocked with the sensor case by the frame stopper formed on the frame. The infrared sensing device of the microwave oven according to any one of claims 1 to 6, wherein the rotation means is constituted by a motor capable of forward and reverse rotation of the sensor case.

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