JP4505519B2 - Electromagnetic cooker - Google Patents

Description

  The present invention relates to an electromagnetic cooker, and more particularly to an electromagnetic cooker having a cooling housing for cooling a heating coil and a semiconductor circuit device.

  An electromagnetic cooker is highly safe because it uses a heating coil (electromagnetic induction coil) to form an eddy current at the bottom of the pan without using a flame, thereby heating the pan itself. Moreover, the electromagnetic cooker is a very excellent cooking utensil because it has high thermal efficiency and can save the time and cost required for cooking. For this reason, electromagnetic cookers are becoming more and more popular in recent years, with momentum surpassing conventional gas cookers.

  A conventional electromagnetic cooker will be described in detail below with reference to FIGS. 1 and 10. In FIG. 1, the electromagnetic cooking device 1 generally includes a top plate 5 made of glass or the like, a grill portion 6, a dial-type thermal power adjustment portion 7, and a display portion 8. A cooling housing (housing) 110 is formed in the electromagnetic cooker 1 as indicated by a broken line in FIG.

  As shown in FIG. 10, the cooling housing 110 has an upper surface covered by the top plate 5. In general, an electromagnetic induction coil or a heating coil 112 and a large current are supplied to the inside of the cooling housing 110. A semiconductor circuit device 114 such as a series of power modules, a cooling motor 116 for cooling the heating coil 112 and the power module 114 by air, and a cooling fan (blower unit) 117 are provided. The heating coil 112 is supported by a partition wall 120 via a spring 118, and a gap 122 is formed between the heating coil 112 and the partition wall 120 at a constant interval. The semiconductor circuit device 114 is mounted on two wiring boards 115 and is electrically connected to the heating coil 112 (not shown). The cooling motor 116 and the cooling fan 117 are designed to be driven according to the heat generated by the heating coil 112 and the power module 114.

  The cooling housing 110 has a suction port 124 for taking in air from the outside and a discharge port 126 for discharging air to the outside. In addition, the partition wall 120 has a communication hole 130 provided directly below the center of the heating coil 112. When the cooling fan 117 rotates, the air taken in from the suction port 124 becomes an air flow and flows along the power module 114 and the wiring board 115 as indicated by the arrows to cool them. Similarly, this air flow passes through the communication hole 130, flows in parallel along the heating coil 112, flows through the gap 122 between the heating coil 112 and the partition wall 120, and exhausts heat generated from the heating coil 112.

  However, in the cooling housing 110 of the electromagnetic cooking device 1 having such a structure, it is not easy to sufficiently exhaust heat generated from the heating coil 112, and the amount of air flowing through the gap 122 between the heating coil 112 and the partition wall 120 is not easy. By increasing, the normal operation of the electromagnetic cooker 1 was guaranteed. That is, in order to ensure a sufficient cooling function, it is necessary to increase the size of the cooling fan 117 and the cooling motor 116 or increase the number of rotations thereof. Therefore, the space occupied by the cooling motor 116 and the cooling fan 117 is inevitably increased, and it is difficult to reduce the noise (rotational noise) due to these high-speed rotations.

  Accordingly, the present invention has been made to solve such problems, and is an electromagnetic cooker that reduces the size of the cooling fan 117 and the cooling motor 116 while maintaining the cooling function, and further substantially reduces noise from the cooling motor 116. It aims at constructing.

  The electromagnetic cooker according to the present invention includes a heating coil, a blower, a first chamber disposed below the heating coil, and a lower portion of the first chamber, and stores a circuit unit therein. And an upper plate constituting the upper surface of the first chamber has a plurality of openings, is a lower surface of the first chamber, and constitutes an upper surface of the second chamber The lower plate has an introduction port that communicates the second chamber and the first chamber, and an air flow sent out from the blower is introduced into the second chamber along the circuit portion. After flowing, it is introduced into the first chamber in the vertical direction to the lower plate through the introduction port, and is ejected in the vertical direction to the heating coil through the opening. Is.

  According to the electromagnetic cooker according to the present invention, the cooling effect by the impinging jet is much higher than the cooling effect by the airflow flowing parallel to the heating coil, so the air volume necessary for exhausting a certain amount of heat is reduced. It is possible to remarkably reduce the size, and it is possible to reduce the size of the air blowing unit such as the cooling fan and the cooling motor, and to extremely reduce the noise generated from the air blowing unit.

  Embodiments of an electromagnetic cooker according to the present invention will be described below with reference to the accompanying drawings. In the description of each embodiment, terminology indicating directions (for example, “upward”, “downward”, “right side”, “left side”, etc.) is used as appropriate for easy understanding. And these terms do not limit the invention.

Reference Example 1
Reference Example 1 of the electromagnetic cooking device will be described in detail below with reference to FIGS. In FIG. 1, the electromagnetic cooking device 1 generally includes a top plate 5 made of glass or the like, a grill portion 6, a dial-type thermal power adjustment portion 7, and a display portion 8. A cooling housing (housing) 10 is formed in the electromagnetic cooker 1 as indicated by a broken line in FIG. In embodiment described below, although the cooling housing 10 was arrange | positioned above the electromagnetic cooker 1, the arrangement position is arbitrary and does not limit this invention.

  As shown in FIG. 2, the cooling housing 10 has an upper surface covered with a top plate 5, and an electromagnetic induction coil or heating coil 12 is roughly provided inside the cooling housing 10 for supplying a large current thereto. A semiconductor circuit device 14 such as a series of power modules, a cooling motor 16 and a cooling fan (also referred to as an air blower) 17 for air-cooling the heating coil 12 and the power module 14 are provided. The heating coil 12 is supported by a partition wall 20 via a spring 18, and a gap 22 having a constant interval is formed between the heating coil 12 and the partition wall 20. The power module 14 is mounted on two wiring boards 15 and is electrically connected to the heating coil 12 (not shown). The cooling motor 16 and the cooling fan 17 are designed to be driven according to the heat generated by the heating coil 12 and the power module 14.

The cooling housing 10 has a suction port 24 for taking in air from the outside and a discharge port 26 for discharging air to the outside. The partition wall 20 of the reference example 1 has a plurality of minute openings or jet blowout holes 30 as shown in FIG. When the cooling fan 17 rotates, the air taken in from the suction port 24 becomes an air flow and flows along the power module 14 and the wiring board 15 as indicated by the arrows to cool them. This airflow further forms a jet through the jet blowout holes 30.

  Here, the jet refers to a flow of air discharged at a predetermined flow rate from a minute opening such as the jet blowout hole 30. When such a jet impinges in a direction substantially perpendicular to the surface of the heating coil 12, convective heat transfer occurs from the hot surface of the heating coil 12 to a cooler air stream and is cooled by the impinging jet. The cooling effect by the collision jet (collision jet effect) generally depends on the flow velocity V of the jet and the collision distance H from the jet blow hole 30 to the surface of the heating coil 12, and the flow velocity V is the opening area of the jet blow hole 30. It depends on S and the static pressure P in the cooling housing 10. Therefore, when the static pressure P in the cooling housing 10 is constant, a jet having a desired collision jet effect can be obtained by adjusting the opening area S and the collision distance H.

It is known that the impact jet effect by the jet is remarkably higher than the cooling effect by the airflow flowing in parallel along the surface of the heating coil 12. In order to confirm this, a comparative experiment was conducted to obtain the graph shown in FIG. FIG. 3 shows, in a solid line, the relationship between the total air volume (air flow) ejected from the plurality of jet blow holes 30 per unit time in the cooling housing 10 of Reference Example 1 and the heat transfer coefficient due to the collision jet effect. At this time, the collision distance H from the jet blowout hole 30 to the surface of the heating coil 12 was 20 mm, and the jet blowout holes 30 were formed in a circular shape having a diameter of 15 mm. Similarly, FIG. 3 shows the relationship between the amount of air flowing from one communication hole 130 per unit time in the conventional cooling housing 110 described above and the heat transfer coefficient due to the airflow flowing in parallel along the surface of the heating coil. Is indicated by a broken line. As is clear from FIG. 3, when the total air volume is the same, the heat transfer rate when cooling is performed using the jets ejected from the plurality of jet blowout holes 30 is the heat transfer by the airflow flowing from one communication hole 130. Much higher than the rate (easy to exhaust heat). That is, according to the plurality of jet blowout holes 30 of the present invention, the heat transfer rate is higher if the total air volume is constant as compared with the conventional case. In other words, the same heat transfer coefficient can be obtained with a smaller air volume. it can.

It has been found that it is necessary to ensure a heat transfer coefficient of about 25 W / m ² K in order to cool the heating coil 12 to a safe temperature in terms of specifications under the standard driving conditions of the electromagnetic cooking device 1. Therefore, according to the prior art, an air volume of about 0.03 m ³ / s is required to obtain the above heat transfer coefficient, whereas according to the present invention, an air volume of about 0.01 m ³ / s is required. In other words, the total air volume supplied to the heating coil 12 can be reduced to about 1/3. Since a predetermined heat transfer coefficient can be obtained with a conventional air volume of about 1/3, the cooling motor 16 and the cooling fan 17 can be reduced in size, or the rotational speed can be substantially reduced. Furthermore, the noise by the cooling motor 16 and the cooling fan 17 can be made extremely small by reducing the rotation speed.

  2 and FIGS. 4A to 4D rectify the airflow flowing from the left side to the right side to form a vertical jet on the surface of the heating coil 12 or the top plate 5. It is preferable to have the rectifying unit 32 so as to facilitate the process. The rectifying unit 32 shown in FIG. 4 (a) has an inclined part 32a that tapers uniformly upward, and the rectifying unit 32 shown in FIG. 4 (b) extends from the lower surface of the partition wall 20 to a substantially central part. It has the inclination part 32b which tapers uniformly toward the upper direction, and the vertical part 32c extended in the perpendicular direction from this center part. As shown in FIG. 4C, the rectifying unit 32 may be a curved portion 32d that curves with an arbitrary curvature instead of the inclined portion 32b in FIG. 4B. Moreover, the rectification | straightening part 32 may be the rectification | straightening part 32 of arbitrary shapes which rectify | straighten the airflow which flows from the left side to the right side more effectively, as shown in FIG.4 (d).

  Further, each of the jet blowout holes 30 formed in the partition wall 20 has been described as having a circular shape as shown in FIG. 5 in a planar shape, but is not limited to this, and is an elliptical shape or an arbitrary polygonal shape. However, it has the same effect. Furthermore, the jet blowout holes 30 may be arranged radially in the radial direction, or can be formed at any arrangement position such as a staggered pattern. Moreover, you may arrange | position the jet blow-out hole 30 according to the shape and heat generation density of the heating coil 12. FIG.

Reference Example 2
Reference Example 2 of the electromagnetic cooker will be described below with reference to FIG. The electromagnetic cooker 1 according to the reference example 2 has the same configuration as that of the reference example 1 except that a chamber having an inlet and a plurality of jet blowout holes is provided instead of the partition wall, so that the contents overlap. Description of is omitted.

In FIG. 6, the chamber 40 of the cooling housing 10 according to the reference example 2 supports the heating coil 12 like the partition wall 20 of the cooling housing 10 according to the reference example 1 . Further, the chamber 40 has a feed port 42 of the airflow provided adjacent to the cooling fan 17, the upper plate 44 of the deployed chamber 40 so as to face the heating coil 12, the reference example 1 Similar to the partition wall 20, a plurality of jet blowout holes 30 are formed.

In the electromagnetic cooker 1 configured as described above, a part of the air flow sent out by the cooling fan 17 flows along the power module 14 and the wiring board 15 and air-cools them. A part of the airflow is introduced into the inlet 42 of the chamber 40 and is ejected through the plurality of jet outlets 30 to form a jet. As in Reference Example 1 , when the jet collides with the surface of the heating coil 12, a jet collision effect is obtained, and the surface of the heating coil 12 is efficiently cooled.

As described above, according to the reference example 2, when a part of the air flow is introduced into the chamber 40, the static pressure P in the chamber 40 increases more than the static pressure P in the cooling housing 10, and the reference example 1 It is possible to form a jet having a higher flow velocity V. Thus, since the electromagnetic cooker 1 having a higher jet collision effect can be configured, the cooling motor 16 and the cooling fan 17 can be further downsized or the number of rotations can be further reduced. Furthermore, since the number of rotations can be suppressed to a lower level, the noise caused by the cooling motor 16 and the cooling fan 17 can be substantially reduced.

Jet outlet hole 30 of Reference Example 2, similarly as in Reference Example 1, have any planar shape, it may have a rectifying section 32 as shown in FIG.

  Since the airflow introduced into the chamber 40 is ejected from the jet blowout holes 30 arranged from the left side to the right side in FIG. 6, the static pressure P in the chamber 40 is recovered toward the downstream side, and the airflow flows in. It is lowest in the vicinity of the mouth 42 and gradually increases toward the downstream side. Therefore, when the jet blowout holes 30 having the same opening area S are uniformly formed, the flow velocity V of the jet ejected through the jet blowout holes 30 on the downstream side is larger than the flow velocity V on the upstream side. As described above, when a difference occurs in the flow velocity V of the jet depending on the position where the jet blowout hole 30 is disposed, the cooling effect due to the expected jet collision varies. Therefore, it is preferable that the jet outlet hole 30 on the downstream side has an opening area S smaller than the jet outlet hole 30 on the upstream side so that the jet collision effect is made uniform over the entire surface of the heating coil 12. Alternatively, it is preferable that the arrangement density of the jet outlets 30 is made coarser on the downstream side than on the upstream side, and the heating coil 12 is cooled uniformly regardless of the portion (position).

Reference Example 3
A reference example 3 of the electromagnetic cooker will be described below with reference to FIG. Compared to the electromagnetic cooker 1 according to the reference example 2 , the electromagnetic cooker 1 according to the reference example 3 has an introduction port provided adjacent to the cooling fan. Since it has the same structure except the point formed in a board, description is abbreviate | omitted about the overlapping content.

As shown in FIG. 7, the chamber 40 of the electromagnetic cooking device 1 according to Reference Example 3 supports the heating coil 12 as in Reference Example 2 . The chamber 40 includes an upper plate 44 in which a plurality of jet blowout holes 30 are formed, and further includes a lower plate 46 provided with an introduction port 45 communicating with a space in which the power module 14 and the wiring board 15 are disposed. Have. As described above, the introduction port 45 of the reference example 3 is provided substantially at the center position of the chamber 40 below the substantially central portion of the heating coil 12.

In the cooling housing 10 configured as described above, the air flow sent out by the cooling fan 17 flows along the power module 14 and the wiring board 15 as indicated by the arrows to cool them. Further, a part of the air flow enters the chamber 40 through the introduction port 45 and is ejected through the plurality of jet blowout holes 30 to form a jet. Thus, as in Reference Example 1 , when the jet collides with the surface of the heating coil 12, a jet collision effect is obtained, and the surface of the heating coil 12 is efficiently cooled.

In the reference example 3 , the air flow entering the chamber 40 passes through the introduction port 45 arranged at the substantially central position thereof. Therefore, unlike the reference example 2 , the static pressure P in the chamber 40 is centered on the introduction port 45. It is formed symmetrically. Thus, the heating coil 12 is preferably cooled symmetrically about its central portion.

Embodiment 1 FIG .
Embodiment 1 of the electromagnetic cooking device according to the present invention will be described below with reference to FIGS. 8 and 9. The cooling housing 10 according to the first embodiment is different from the reference example 3 in that a second chamber in which the power module and the wiring board are stored is formed in addition to the first chamber for forming the jet flow. Since it has the same structure except for, description is abbreviate | omitted about the overlapping content.

As shown in FIG. 8, the cooling housing 10 according to the first embodiment includes a first chamber 40 for forming a jet as in Reference Example 3, and a second chamber for storing the power module 14 and the wiring board 15. 50. The first chamber 40 includes an upper plate 44 in which a plurality of jet blowout holes 30 are formed, and a lower plate 46 in which an introduction port 45 is formed. The second chamber 50 has a second introduction port 52 and communicates with the introduction port 45 of the first chamber 40.

In summary, the electromagnetic cooking device 1 according to the first embodiment includes the first chamber 40 having the inlet 45 and the plurality of jet blowout holes 30, and the heating coil 12 disposed above the first chamber 40. . The electromagnetic cooker 1 further includes a second introduction port 52, a second chamber 50 that communicates with the introduction port 45 of the first chamber 40, a second chamber 50, and the heating coil 12. A semiconductor circuit device (circuit unit) 14 that supplies current to the second inlet 52 and a blower unit such as a cooling fan 17 for sending an air flow to the second introduction port 52.

In the electromagnetic cooker 1 configured as described above, the air flow sent out from the blower fan 17 is introduced from the second introduction port 52, flows along the power module 14 and the wiring board 15, and cools them. The airflow introduced into the second chamber 50 enters the inlet 45 of the first chamber 40 without being directly discharged from the outlet 26 of the cooling housing 10, and the jet blowout hole of the first chamber 40. A jet is formed through 30. And a jet flow collides with the heating coil 12, and the heating coil 12 is cooled efficiently. That is, the flow path of the airflow in the first embodiment is limited to one (one system) flow path that flows through the second chamber 50, the first chamber 40, and the jet blowout hole 30.

In the first embodiment, the airflow that cools the heating coil 12 cools the power module 14 and the wiring board 15 in the second chamber 50 before being introduced from the inlet 45 of the first chamber 40. The temperature rises from room temperature, and the cooling effect on the heating coil 12 decreases. However, since the maximum allowable operating temperature of the heating coil 12 is higher than the maximum allowable operating temperature of the power module 14, the heating coil 12 should be cooled to a temperature range in which the heating coil 12 can operate even when a higher temperature airflow is used. Is possible. Thus, by integrating the flow path of the airflow, both the power module 14 and the heating coil 12 can be cooled with a smaller amount of airflow. Thus, the cooling motor 16 and the cooling fan 17 can be reduced in size, or the rotational speed can be substantially reduced. By reducing the rotational speed, noise caused by the cooling motor 16 and the cooling fan 17 can be made extremely small.

  In the above description, in particular, in FIG. 8, the introduction port 45 of the first chamber 40 is provided substantially at the center of the first chamber 40 below the substantially central portion of the heating coil 12. However, alternatively, as shown in FIG. 9, it may be provided at the end of the first chamber 40 located in the opposite direction to the cooling fan 17. Similarly, in the electromagnetic cooking device 1 configured as shown in FIG. 9, both the heating coil 12 and the power module 14 can be cooled with a smaller amount of air flow by unifying the air flow path. In this way, the cooling motor 16 and the cooling fan 17 can be reduced in size, or the number of rotations can be substantially reduced, and the noise caused by the cooling motor 16 and the cooling fan 17 can be extremely reduced.

It is a perspective view which shows an electromagnetic cooker. It is sectional drawing which showed the cooling housing of the electromagnetic cooker by the reference example 1, and was seen from the II-II line | wire of FIG. It is a graph for comparing the cooling effect by the jet blowout hole by the reference example 1 , and the conventional type communication hole. It is sectional drawing which shows the rectification | straightening part of a jet blowout hole. It is a top view which shows the planar shape of the jet blowout hole provided in the partition part, and the arrangement position with respect to a heating coil. It is sectional drawing similar to FIG. 2 which shows the cooling housing of the electromagnetic cooker by the reference example 2. FIG. It is sectional drawing similar to FIG. 2 which shows the cooling housing of the electromagnetic cooker by the reference example 3. FIG. It is sectional drawing similar to FIG. 2 which shows the cooling housing of the electromagnetic cooker by Embodiment 1 of this invention. It is sectional drawing similar to FIG. 2 which shows the cooling housing of the alternative electromagnetic cooker of Embodiment 1. FIG. It is sectional drawing which showed the cooling housing of the conventional electromagnetic cooker, and was seen from the II-II line | wire of FIG.

DESCRIPTION OF SYMBOLS 1 Electromagnetic cooker, 5 Top plate, 6 Grill part, 7 Dial type thermal power adjustment part, 8 Display part, 10 Cooling housing (housing), 12 Heating coil, 14 Semiconductor circuit device, 15 Wiring board, 16 Cooling motor, 17 Cooling fan, 18 spring, 20 partition, 22 gap, 24 inlet, 26 outlet, 30 jet outlet, 32 rectifier, 40 first chamber, 42 inlet, 44 upper plate, 45 inlet, 46 lower plate , 50 Second chamber, 52 Second inlet.

Claims (6)

A heating coil;
A blowing section;
A first chamber disposed below the heating coil;
A second chamber disposed below the first chamber and storing a circuit unit therein,
The upper plate constituting the upper surface of the first chamber has a plurality of openings.
A lower plate, which is a lower surface of the first chamber and constitutes an upper surface of the second chamber, has an inlet for communicating the second chamber and the first chamber;
The air flow sent out from the blowing section is introduced into the second chamber, flows along the circuit section, and then is introduced into the first chamber in a direction perpendicular to the lower plate through the inlet, An electromagnetic cooker characterized by being ejected in a substantially vertical direction to the heating coil through the opening.   The induction cooker according to claim 1, wherein the introduction port is provided substantially below the center of the heating coil.   The induction cooker according to claim 1, wherein the introduction port is provided at an end of the first chamber opposite to the air blowing unit.   The electromagnetic cooker according to claim 1, wherein each opening has an opening area that is smaller in the upper part than in the lower part.   2. The opening according to claim 1, wherein each opening includes an inclined portion having an opening area that is smaller in the upper part than the lower part and a vertical part in which the opening area does not change in the vertical direction above the inclined part. Electromagnetic cooker.   The electromagnetic cooker according to claim 1, wherein the plurality of openings are arranged in a staggered pattern or in a radial pattern in a radial direction.

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