KR19980051451A - Microwave Temperature Sensor Mounting Structure - Google Patents

Abstract

The present invention relates to an improvement in the mounting structure of the infrared sensor for measuring the temperature of the food during heating by detecting the infrared rays from the food located inside the cavity during automatic cooking of the microwave oven.

The present invention provides two cavity sensor holes formed on the upper surface of the cavity, a belt installed to pass through the two cavity sensor holes, and an infrared sensor attached to one outer surface of the belt and a sensor attached to the belt between the two cavity sensor holes. It consists of a belt drive device for reciprocating movement, wherein the belt drive device comprises a stepping motor as a drive source and a reduction gear for transmitting the power of the motor to the drive pulley of the belt.

In the temperature sensor mounting structure of the present invention, the infrared sensor can detect the temperature by changing its position according to the position or size of the food, thereby increasing the detection area, and also steam or other generated during heating of the food. There is an advantage that can prevent contamination of the infrared sensor from contaminants.

Description

Microwave Temperature Sensor Mounting Structure

1 is a longitudinal sectional view showing a schematic structure of a conventional microwave oven.

Figure 2 is a longitudinal sectional view showing a temperature sensor mounting structure of the present invention microwave oven.

Figure 3 is a perspective view showing a temperature sensor mounting structure of the present invention microwave oven.

Figure 4 is a plan view of the power transmission system for belt transfer of the present invention the temperature sensor mounting structure.

5 is an exploded perspective view showing the belt driving unit separated from the temperature sensor mounting structure of the present invention.

* Explanation of symbols for main parts of the drawings

10. Cavities l0a, 10b. Cavity Sensor Hall

11.Following pulley 12. Driving pulley

13. Belt 14. Infrared Sensor

15. Motor Bracket 16. Motor

17. Reduction Gear

The present invention relates to a temperature sensor for detecting a heating state of food in a cavity when performing an automatic cooking menu of a microwave oven, and more specifically, to form two cavity sensor holes on the upper surface of the cavity and to be installed outside the cavity sensor hole. The temperature sensor of the microwave oven is installed so that the sensing sensor can move back and forth between the two cavity sensor holes to expand the sensing area of the sensor and to prevent the contamination of the sensor by water vapor and the malfunction caused by cold temperature rise. It's about structure.

In general, when performing automatic cooking in a cooking or heating menu using a microwave oven, the heating state (temperature) of the food being heated in the cooking chamber is sensed by using an infrared sensor installed around the cavity. The microcomputer controls the driving of the magnetron based on the result obtained by comparing the detected value with the preset temperature for each menu stored in the micom, and the cooking object is heated or cooked to a predetermined temperature. Looking at the structure and control system of a conventional microwave oven based on the longitudinal cross-sectional view of the conventional microwave oven of Figure 1 as follows.

As shown in the drawing, the conventional microwave oven is equipped with a turntable 2 on which the food to be cooked F is placed on the bottom surface of the cavity 1, and on one side of the cavity 1 into the cavity 1. The magnetron 3 which supplies electromagnetic waves, and the air duct 5 which flows the wind which generate | occur | produced in the blowing fan 4 and the blowing fan 4 along the upper surface outer side of the cavity 1 are provided.

In addition, an infrared sensor 6 which detects an infrared ray i coming from the food F being heated and detects the temperature of the food F is directly above the cavity sensor hole 1a formed on the upper surface of the cavity 1. ), And the detected value detected by the infrared sensor 6 is input to the microcomputer 7 in which a signal amplifier, a signal storage device and a reference value setting device are built.

The microcomputer 7 receives the detected value of the infrared sensor 6 and compares the temperature change of the food F being heated to compare the control signal to an output control device 8 that controls the driving of the magnetron 3. The automatic cooking is performed by sending.

However, the conventional infrared sensor 6 is mounted on the upper side of the cavity 1 in a fixed state, and also has a narrow viewing angle, so that the food F located inside the cavity 1 is turned off of the turntable 2. When placed at a point outside the center or small in size, it has a problem that it does not properly detect the infrared rays from the food (F).

Of course, in order to solve the above problems, the size of the cavity sensor hole hl formed on the upper surface of the cavity is increased, and the infrared sensor 6 is positioned at a point farther from the cavity sensor hole la to enlarge the viewing angle of the sensor. In this case, the cavity sensor hole 1a may be enlarged to increase the leakage of electromagnetic waves through the sensor hole 1a. Thus, the detection value of the infrared sensor 6, which is sensitive to noise, may be increased. It is different from the infrared temperature of the actual food (F), causing another problem that the measurement error occurs.

In addition, the conventional infrared sensor 6 is formed in the upper portion of the cavity sensor hole (la) formed on the upper surface of the cavity, so that water vapor exiting the cavity sensor hole (la) at the time of heating or immediately after the heating (F) of the sensor In addition, there is also a problem that the performance of the infrared sensor (F) is degraded due to contamination of the sensor due to sticking to the window or oil sticking out from the food (F).

In addition, in the conventional infrared sensor 6 mounting structure, when the food F inside the cavity 1 is bulky or located at the center of the turntable 2, the food F and the infrared sensor 6 are separated between the food F and the infrared sensor 6. The interval of the heat is reduced, contaminants caused by the water vapor or oil are aggravated, and the heat of the food F in a heated state is transmitted to the infrared sensor 6 side thereof, so that the temperature around the mounting portion of the infrared sensor 6 is increased. There is a disadvantage that the detection degree of the sensor is reduced.

Accordingly, the present invention is to solve the above-mentioned problems that are pointed out in the infrared sensor mounting structure of the conventional microwave oven, the two cavity sensor holes formed on the upper surface of the cavity and installed above the two cavity The purpose is to provide an infrared sensor mounting structure of a microwave oven that is configured to reciprocate between sensor holes to expand the detection area of the infrared sensor and to prevent contamination of the infrared sensor and deterioration of the sensor due to food heat. I put it.

The infrared sensor mounting structure of the microwave oven of the present invention consists of a structure in which two cavity sensor holes formed on the upper surface of the cavity, an infrared sensor reciprocating between the two cavity sensor holes, and a reciprocating driving device of the infrared sensor are organically combined. have.

At this time, the infrared sensor reciprocating drive device is a belt that is installed to pass through the upper portion of the two cavity sensor holes attached to the infrared sensor on one outer surface, drive pulleys and driven pulleys installed at both ends of the belt, and to drive the driving pulley It consists of a motor.

Matters relating to the above objects, technical configurations, and effects according to the present invention will be clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

First, Figure 2 is a longitudinal cross-sectional view of the microwave oven equipped with an infrared sensor mounting structure of the present invention, as shown in the upper surface of the cavity 10, two cavity sensor holes (10a) (10b) at regular intervals And the driving pulley 11 and the driven pulley 12 are installed at both outer sides of the cavity sensor holes 10a and 10b and parallel to the two cavity sensor holes 10a and 10b. 11) 12, the belt 13 is coupled between, the infrared sensor 14 is attached on one outer surface of the belt (13).

At this time, the infrared sensor 14 should be designed such that the sensor window is located directly above the two cavity sensor holes 10a and 10b by the movement of the belt 13.

On the other hand, Figure 3 is a perspective view of a microwave oven to which the temperature sensor mounting structure of the present invention is applied, Figure 4 is a plan view of a power transmission system of the temperature sensor mounting structure of the present invention, Figure 5 is a reciprocating transfer drive of the temperature sensor of the present invention As an exploded perspective view of the driven pulley 12, as shown, the driven pulley 12 is fixed on the fixed shaft 12a fixed to the upper surface of the cavity 1, the drive pulley 13 is on the upper side of the corner of the cavity 10 Is installed on the motor bracket 15 formed separately in the drive pulley 13 is formed integrally with the reduction gear 17 receives the rotational driving force from the motor 16 mounted on the lower portion of the motor bracket 15 to the motor It is fixed on the bracket 15.

In more detail, the motor shaft of the motor 16 mounted to the lower part of the motor bracket 15 by the fastening of the fastening bolt 18 protrudes to the upper part of the motor bracket 15 to form a motor gear at an upper end thereof. 19 is formed, and the motor gear 19 is in gear engagement with the reduction gear 17 formed on the motor bracket 15, so that the rotational driving force of the motor 16 is decelerated via the motor gear 19. The drive pulley 11 is rotated while being transmitted to the gear 17 and decelerating while increasing the torque. The drive pulley 11 and the reduction gear 17 formed as one body are fixed on the motor bracket 15 by a fixed side 1la which is inserted into the center portion thereof and fastened to the motor bracket I5.

The motor 16 as a driving source for enabling the reciprocating movement of the infrared sensor 14 of the present invention is preferably a stepping motor, and the stepping motor is configured such that the correct rotational speed is controlled by a control signal applied from the microcomputer. As the position and the mutual spacing of the cavity sensor holes 10a and 10b are calculated and input in advance in the number of gear teeth and the reduction ratio, the motor 16 driven by the control of the microcomputer is driven by the belt 13. The belt 13 is transported so that the infrared sensor 14 attached thereto is located directly above the two cavity sensors 10a and 10b.

Looking at the process of driving the infrared sensor 14 and the temperature sensing process by the infrared sensor 14 in the execution of the automatic cooking menu in the microwave oven equipped with a temperature sensor mounting structure of the present invention as follows.

When the food F is placed on the turntable 2 inside the cavity of the microwave oven and the auto cooking menu key is input, the rotation of the turntable 2 is started with the driving of the magnetron 3 to heat the food F. It begins. At this time, the infrared sensor 14 is located above any one of the two cavity sensor holes 10a and 10b, and the infrared sensor 14 detects the food F together with the operation of the microwave oven. The microcomputer 7 is input, and the microcomputer 7 compares the detected values of the initial operation, and determines whether the position where the food F is placed is the proper position of the infrared sensor 14 in the current state.

If it is determined that the current position of the infrared sensor 14 is not appropriate as a result of this determination in the microcomputer 7, the microcomputer 7 sends a control signal for driving the motor 16 so that the motor 16 is driven. The current position of the infrared sensor 14 is moved to another cavity sensor hole.

At this time, the motor l6 allows the infrared sensor 14 attached to the belt 13 to be accurately moved from the current cavity sensor hole to another cavity sensor hole by the drive control signal from the microcomputer 7. .

Next, after the infrared sensor 14 moves to the upper portion of the other cavity sensor hole by the driving of the motor 16, the temperature detection of the food F is performed at the position.

As described above, in the temperature sensor mounting structure of the present invention, the detection area is enlarged as the installation position of the infrared sensor 14 can be moved according to the state of the load (food) located in the cavity. Unlike in a microwave oven, since two cavity sensor holes are formed, contamination of the infrared sensor due to steam or oil generated from food during heating is much reduced. In particular, when the microwave oven is stopped, the infrared sensor 14 is stopped. By positioning it away from the cavity sensor holes 10a and 10b, contamination of the infrared sensor 14 can be prevented from vapors exiting the cavity sensor holes 10a and 10b immediately after the magnetron stops driving. Can be.

In the present invention, the cavity sensor hole (10a) (10b) is formed in the central portion of the cavity (10) which is directly affected by the heat from the food during the heating and cooking of the food or at a point deviating from the upper portion of the food. By positioning the infrared sensor, the temperature around the infrared sensor 14 is suppressed to increase, and the sensitivity of the sensor can be prevented.

Claims (3)

Two cavity sensor holes formed at regular intervals on the upper surface of the cavity, a belt installed to pass over the two cavity sensor holes, an infrared sensor fixed on the belt, and an infrared sensor fixed on the belt are connected between the two cavity sensor holes. Temperature sensor mounting structure of the microwave oven, characterized in that consisting of a belt drive for reciprocating movement. The method of claim 1, wherein the belt drive device is a stepping motor, and a reduction gear linked thereto. The temperature sensor mounting structure of the microwave oven, which is formed integrally with the reduction gear and consists of a driving pulley in which one side of the belt is wound on an outer circumferential surface and a driven pulley in which the other side of the belt is wound. 3. The temperature sensor mounting structure according to claim 2, wherein the driven pulley is installed on the upper surface of the cavity, and the drive gear and the motor are installed on the motor bracket fixed on the upper edge of the cavity.