JP2020024054A - Range hood - Google Patents

Abstract

To provide a range hood which can be used in a gas cooker and an IH cooker and can perform air volume control suitable for each cooker.SOLUTION: A range hood 100 has an exhaust fan, is installed above a cooker, and has: a gas/IH selecting switch 132 for selecting a cooker from a gas cooker and an IH cooker; and a control unit 136 which controls the exhaust gas 116 so that its air volume varies between the gas cooker and the IH cooker based on setting of the gas/IH selecting switch 132.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a range hood.

  Various range hoods that can control the amount of exhaust air have been proposed (for example, Patent Documents 1 and 2).

JP 2013-228114 A JP 2018-105517 A

  Such a range hood is applicable to both a gas cooker and an IH (Induction Heating) cooker (see, for example, paragraph 0014 of Patent Document 1 and paragraph 0019 of Patent Document 2).

  However, since the gas cooker and the IH cooker have different heating methods, the gas cooker and the IH cooker have different effects on the surrounding environment. For this reason, if air volume control is performed without distinguishing between a gas cooker and an IH cooker, there has been a problem that efficiency is deteriorated and proper exhaust cannot be performed.

  Therefore, an object of the present invention is to provide a range hood that can be used for both a gas cooker and an IH cooker, and that can perform air volume control suitable for each cooker.

  According to another aspect of the present invention, there is provided a range hood having an exhaust fan, the range hood being installed above a cooker, wherein the cooker is a gas cooker or an IH cooker. And a control unit that controls the exhaust fan so that the gas cooker and the IH cooker have different air volumes based on the setting of the select switch.

  According to the present invention, the amount of exhaust air differs between the case where the range hood is used for the gas cooker and the case where the range hood is used for the IH cooker. It is possible to exhaust odor and oily smoke generated during cooking efficiently and efficiently.

It is a perspective view showing the example which installed the range hood concerning an embodiment in a gas cooker. It is a perspective view showing the example which installed the range hood concerning an embodiment in an IH cooker. It is the side view which penetrated the inside in order to show the internal configuration of the range hood concerning an embodiment. It is a front view of operation panel 120 with which a range hood is provided. It is a block diagram of a control system of the range hood of the embodiment. FIG. 7 is a table diagram showing a correspondence relationship between a threshold temperature (temperature range) and an exhaust air volume in the air volume control example 1; FIG. 9 is a table diagram showing a correspondence relationship between a threshold temperature (temperature range) and an exhaust air volume in an air volume control example 2. FIG. 11 is a table diagram showing a correspondence relationship between a threshold temperature (temperature range) and an exhaust air volume in an air volume control example 3;

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to only the following embodiments. Each drawing is exaggerated for convenience of explanation. Therefore, the dimensional ratio of each component in each drawing is different from the actual one. In the drawings, the same elements will be denoted by the same reference symbols, without redundant description in the specification.

  FIG. 1 is a perspective view illustrating an example in which the range hood according to the present embodiment is installed in a gas cooker. FIG. 2 is a perspective view showing an example in which the range hood according to the present embodiment is installed in an IH cooker. FIG. 3 is a side view showing the inside of the range hood according to the present embodiment in order to show the internal configuration thereof.

  The range hood 100 of the present embodiment is installed above the gas cooker 200 as shown in FIG. 1, or is installed above the IH cooker 300 as shown in FIG. That is, the range hood 100 of the present embodiment can be installed in both the gas cooker 200 and the IH cooker 300. Range hood 100 sucks in odors and oily smokes including odor, smoke, oil, etc. generated during cooking by gas cooker 200 or IH cooker 300 and exhausts them to the outside. FIGS. 1 and 2 show an example of installation along the wall surface 600, but they may be installed along the wall surface. For example, it can be installed in an island kitchen.

  The gas cooker 200 shown in FIG. 1 has three gas burners 210 (also referred to as a gas stove) as heat sources on a top surface 250 of the gas cooker 200. Although not shown, a gas grill may be provided. In this case, the top surface 250 has an outlet (not shown).

  On the other hand, the IH cooker 300 shown in FIG. 2 has three IH cooking heaters (hereinafter simply referred to as IH heaters 310) as heat sources on the top surface 350 of the IH cooker 300. Although not shown, a grill with an electric heater may be provided. In this case, the top surface 350 has an outlet (not shown).

  As shown in FIG. 3, range hood 100 has a temperature sensor 400 for detecting the temperature of top surface 500 of the cooking appliance on the lower surface on the front side on the left side of the center. As the temperature sensor 400, for example, a monocular or compound-eye infrared sensor or an infrared camera can be used. When a compound-eye infrared sensor or infrared camera is used, the temperature distribution of the top surface 500 can be detected together with the temperature. The position of temperature sensor 400 is not particularly limited as long as it can detect the temperature of top surface 500. FIG. 3 is a diagram for explaining the range hood 100. In FIG. 3, the gas cooker 200 and the IH cooker 300 are shown as the top surface 500 of the cooker 500 without distinction (hereinafter, referred to as the cooker top 500). Similarly, when the top surface is described without distinction between the gas cooker 200 and the IH cooker 300, the top surface 500 is used.)

  Range hood 100 is provided with an exhaust unit 110 at an upper portion thereof. The exhaust unit 110 exhausts odor and oily smoke from the cooker. The exhaust part 110 exhausts the oil smoke sucked from the intake port 112 into the exhaust port 114 into an intake port 112 for sucking oil smoke from the cooker, an exhaust port 114 communicating with the outside, and a passage connecting the intake port 112 and the exhaust port 114. An exhaust fan 116 is provided. The exhaust fan 116 is driven by a fan motor 115.

  Further, the range hood 100 has a disk 119 for capturing oil in oil smoke. The disk 119 is driven by a dedicated disk motor 118. The disk 119 is a filter that captures oil from oil smoke by rotating.

  Range hood 100 includes an operation panel 120 for instructing the operation of range hood 100 on an upper front side thereof.

  FIG. 4 is a front view of the operation panel 120 included in the range hood 100. The operation panel 120 has an operation switch 121, an air volume switch 122, an automatic air volume switch 123, a timer switch 124, an illumination switch 125, and a constant ventilation switch 126. The operation switch 121 operates the range hood 100. When the operation switch 121 is pressed during the stop, the operation is started at the air volume (mode) at the time of the previous stop, and the operation switch 121 is stopped when pressed during the operation.

  The air volume switch 122 manually switches the exhaust air volume of the exhaust fan 116 between low, medium, and high. The mode in which the operation is manually switched is referred to as a manual mode.

  The air volume automatic switch 123 switches to an automatic mode. In the automatic mode, the exhaust air volume of the exhaust fan 116 and the rotation speed of the disk 119 are optimized according to the temperature of the top surface 500 detected by the temperature sensor 400.

  The timer switch 124 is a switch for setting the time for rotating the exhaust fan 116 after cooking is completed.

  The lighting switch 125 turns on / off a lighting fixture (not shown) that illuminates the upper surface of the cooker.

  The constant ventilation switch 126 operates / stops the constant ventilation by manually rotating / stopping the exhaust fan 116.

  FIG. 5 is a block diagram of a control system of the range hood 100 of the present embodiment. Range hood 100 has a fan motor 115, an exhaust fan 116, a disk motor 118, a disk 119, an operation panel 120, a control device 130, and a temperature sensor 400. The fan motor 115, the exhaust fan 116, the disk motor 118, the disk 119, the operation panel 120, and the temperature sensor 400 are as described above.

  Control device 130 is incorporated in range hood 100. The control device 130 includes a gas / IH selection switch 132, a threshold temperature storage unit 134, a control unit 136, and a timer 137.

  The gas / IH selection switch 132 selects whether the type of cooker in the kitchen in which the range hood 100 is installed is the gas cooker 200 or the IH cooker 300. The gas / IH selection switch 132 may be provided on the operation panel 120. The gas / IH selection switch 132 is operated by an operator when installing the range hood 100 on the site, or by a user (user) before the use of the range hood 100 is started.

  The threshold temperature storage unit 134 stores a threshold temperature for selecting an exhaust air volume of the exhaust unit 110 in association with each temperature area of the top surface 500 detected by the temperature sensor 400. As for the threshold temperature stored in the threshold temperature storage unit 134, the exhaust air volume is set for each of a plurality of temperature regions. The temperature range set as the threshold temperature is the same whether the gas cooker 200 or the IH cooker 300 is used. On the other hand, the exhaust air volume corresponding to those temperature ranges differs depending on whether the gas cooker 200 or the IH cooker 300 is used.

  The control unit 136 controls the exhaust fan based on the setting selected by the gas / IH selection switch 132 such that the air flow is in the automatic mode corresponding to the threshold (temperature range) of the threshold temperature storage unit 134. The control unit 136 also controls the rotation speed of the disk 119.

  The timer 137 counts a set time.

  Next, an example of controlling the air volume of the range hood will be described.

(Example 1 of air volume control)
FIG. 6 is a table diagram showing a correspondence relationship between the threshold temperature (temperature range) and the exhaust air volume in the air volume control example 1.

  As shown in FIG. 6, the threshold temperature ranges are a low temperature range, a medium temperature range, and a high temperature range. As for the exhaust air volume, the air volume for the gas cooker becomes stronger as Gs1 <Gs2 <Gs3, and the air volume for the IH cooker becomes stronger as Hs1 <Hs2 <Hs3 corresponding to these temperature ranges. The exhaust air volume differs depending on whether the gas cooker 200 or the IH cooker 300 is used.

  In a low temperature range, Gs1> Hs1. That is, the minimum air volume Gs1 for the gas cooker is set to be larger than the minimum air volume Hs1 for the IH cooker. In this low temperature range, the minimum air volume Hs1 for the IH cooker may be the air volume 0 (that is, the exhaust fan is stopped). This is because the IH cooker 300 does not require exhaust when the temperature is low at the beginning of cooking and there is almost no odor or oily smoke. As a result, the exhaust fan 116 can be stopped, so that there is no noise and the energy saving effect can be improved. In addition, since the gas cooker 200 burns gas even if the temperature of the top surface 250 is low, it is not preferable to stop the exhaust (that is, stop the exhaust fan).

  In the middle temperature range, Gs2 <Hs2. That is, the air volume Gs2 for the gas cooker is made smaller than the air volume Hs2 for the IH cooker. This is because in the case of the gas cooker 200, the surroundings of the gas burner 210 are warmed by the combustion of the gas, and a certain amount of upward airflow is generated. On the other hand, in the case of the IH cooker 300, even though the amount of heat applied to the cookware is almost the same as that of the gas, the surrounding temperature does not rise as much as the gas cooker 200. For this reason, in the middle temperature range, since the IH cooker 300 has a lower airflow than the gas cooker 200, it is preferable to make the air flow Hs2 larger than the air flow Gs2 of the gas cooker 200. Accordingly, even in the IH cooking device 300, when odor or oily smoke is generated, the exhaust can be reliably performed without relying on the upward airflow.

  In a high temperature range, Gs3 = Hs3. That is, both the air volume Gs3 for the gas cooker and the air volume Hs3 for the IH cooker are set to the maximum air volume as the exhaust performance of the exhaust fan 116. This is because when the temperature is high in both the gas cooker 200 and the IH cooker 300, a large amount of odor or oily smoke may be generated, and therefore, the gas is exhausted at the maximum air volume as the exhaust performance of the exhaust fan 116. That's why.

  With such control, both when the range hood 100 of the present embodiment is installed in the gas cooker 200 and when installed in the IH cooker 300, an appropriate air volume is obtained according to the characteristics and temperature of the cooker. Therefore, the efficiency of collecting odors and oil smoke can be improved, and an energy saving effect can be obtained.

(Example 2 of air volume control)
FIG. 7 is a table showing the correspondence between the threshold temperature (temperature range) and the exhaust air volume in Example 2 of the air volume control.

  Also in the air volume control example 2, the temperature ranges that serve as threshold values are a low temperature range, a medium temperature range, and a high temperature range. As for the exhaust air volume, the air volume for the gas cooker becomes stronger as Gs1 <Gs2 <Gs3, and the air volume for the IH cooker becomes stronger as Hs1 <Hs2 <Hs3 corresponding to these temperature ranges. The exhaust air volume differs depending on whether the gas cooker 200 or the IH cooker 300 is used.

  In the air volume control example 2, as shown in FIG. 7, the air volumes Gs1 to Gs3 for the gas cooker are always larger than the air volumes Hs1 to Hs3 for the IH cooker in all temperature ranges.

  This is because the gas cooker 200 generates gas with combustion, and in order to exhaust the gas, it is necessary to exhaust the gas to a necessary ventilation amount from a safety aspect. On the other hand, the IH cooker 300 does not generate gas. For this reason, the required ventilation volume is not determined, and there is no problem even if the exhaust air volume is reduced.

  Further, since the gas cooker 200 generates more heat than the IH cooker 300, the user often feels discomfort from the heat unless the heat is exhausted. Conversely, since the IH cooker 300 generates less heat than the gas cooker 200, even if the air volume is reduced, the heat is less likely to cause discomfort.

  By adopting such control, when the range hood 100 of the present embodiment is installed in the gas cooker 200, it is possible to reliably exhaust air and use it in a comfortable space for the user. When installed in the IH cooker 300, noise can be suppressed and an energy saving effect can be obtained.

  In the second example of the air volume control, for example, the minimum air volume Hs1 for the IH cooker may be set to the air volume 0 (the exhaust fan 116 is stopped). A part of the air volume may be the same for the gas cooker and the IH cooker. That is, a temperature range where Gs> Hs and a temperature range where Gs = Hs may coexist. For example, only the air volume in the low temperature range is the same (Gs1 = Hs1) and the air volume in the other temperature ranges is larger for the gas cooker than for the IH cooker (Gs2> Hs2, Gs3> Hs3), or only for the middle temperature range. Are the same (Gs2 = Hs2) and the air volume in the other temperature ranges is made larger for the gas cooker than for the IH cooker (Gs1> Hs1, Gs3> Hs3), or only the air volume in the high temperature range is the same (Gs3 = Hs3). The air volume in other temperature ranges may be larger for the gas cooker than for the IH cooker (Gs1> Hs1, Gs2> Hs2).

(Example 3 of air volume control)
FIG. 8 is a table diagram showing the correspondence between the threshold temperature (temperature range) and the exhaust air volume in the air volume control example 3.

  Also in the air volume control example 3, the threshold temperature ranges are a low temperature range, a medium temperature range, and a high temperature range. As for the exhaust air volume, the air volume for the gas cooker becomes stronger as Gs1 <Gs2 <Gs3, and the air volume for the IH cooker becomes stronger as Hs1 <Hs2 <Hs3 corresponding to these temperature ranges. The exhaust air volume differs depending on whether the gas cooker 200 or the IH cooker 300 is used.

  In the air volume control example 3, as shown in FIG. 8, the air volumes Gs1 to Gs3 for the gas cooker are always smaller than the air volumes Hs1 to Hs3 for the IH cooker in all the temperature ranges.

  This is because the IH cooker 300 can heat only the cooking utensils on the IH heater 310, so that the temperature around the IH heaters 310 is hard to rise. Airflow is weak. For this reason, if exhaust is not performed at a certain air volume, the efficiency of collecting odor, oily smoke, and the like may deteriorate. On the other hand, when the same amount of heat as that of the IH cooker 300 is to be applied to the cookware, the surrounding air is warmed by the gas burner 210 and the upward airflow is stronger than that of the IH cooker 300. Therefore, even if the air volume is reduced, the efficiency of collecting odors, oily smoke, and the like can be increased by the upward airflow.

  With such control, when the range hood 100 of the present embodiment is installed in the IH cooker 300, it is possible to improve the collection efficiency of odor and oily smoke, and when it is installed in the gas cooker 200, the air volume is increased. By reducing the noise, noise can be suppressed and an energy saving effect can be obtained.

  In the air volume control example 3, a part of the air volume may be the same for the gas cooker and the IH cooker. That is, a temperature range where Gs <Hs and a temperature range where Gs = Hs may coexist. For example, only the air volume in the low temperature range is the same (Gs1 = Hs1) and the air volume in the other temperature ranges is smaller for the gas cooker than for the IH cooker (Gs2 <Hs2, Gs3 <Hs3), or only for the middle temperature range. Are the same (Gs2 = Hs2) and the air volume in the other temperature range is made smaller for the gas cooker than for the IH cooker (Gs1 <Hs1, Gs3 <Hs3), or only the air volume in the high temperature range is the same (Gs3 = Hs3). The air volume in the other temperature range may be smaller for the gas cooker than for the IH cooker (Gs1 <Hs1, Gs2 <Hs2).

  The three control examples have been described above. As described above, in each control example, whether to use the gas flow rate for the gas cooker or the air flow rate for the IH cooker is determined by selecting the gas / IH selection switch 132. This will be set when the range hood is installed (or at the start of use).

  Next, control of the disk 119 will be described. As for the control of the disk 119, similarly to the exhaust fan 116, the number of rotations (rotational speed) is changed in accordance with the temperature detected by the temperature sensor 400. That is, control is performed so that the rotation speed of the disk 119 is changed simultaneously with the change in the air volume. In this case, the threshold temperature (temperature range) for changing the air volume and the threshold temperature (temperature range) for changing the rotation speed of the disk 119 are set to be the same. For example, in a low temperature range where the possibility of generating oil smoke is low (the exhaust air volume of the exhaust fan 116 is minimized or stopped), the rotation of the disk 119 is set to the minimum speed or the stop in both the gas cooker 200 and the IH cooker 300. I do. In the medium temperature range, the rotation of the disk 119 is set to a rotation speed (medium speed) higher than the minimum speed. In the high temperature range, the disk 119 is set to the highest rotational speed. The oil component in the smoke increases as the cooking temperature increases. Therefore, the higher the temperature range (the higher the detection temperature of the temperature sensor 400), the more the oil component in the smoke can be captured and removed by rotating the disk 119 at a higher speed.

  In addition to the control of the disk 119, for example, separately from the threshold temperature (temperature range) for controlling the air volume by the exhaust fan 116, the rotational speed of the disk 119 is multi-stepped or steplessly based on the temperature detected by the temperature sensor 400. You may change it. Also in this case, it is preferable that the higher the detected temperature, the higher the rotation speed. In addition to the air volume control by the exhaust fan 116, when the detected value of the temperature sensor 400 is equal to or more than a specified value, the disk 119 may be set to a constant rotation speed.

  Further, the control of the disk 119 may be such that the disk 119 is always rotated at a constant rotation speed regardless of the temperature range or the temperature detected by the temperature sensor 400. In this case, the control unit 136 also rotates the disk 119 at a constant speed when the exhaust fan 116 is rotating, and also stops the disk 119 when the exhaust fan 116 is stopped (simply turning on the operation switch). Alternatively, the disk 119 may be rotated / stopped in conjunction with / off).

  Of course, in the control of the disc 119, the rotation speed of the disc 119 may be changed between the gas cooker 200 and the IH cooker 300. That is, in the gas cooker 200 and the IH cooker 300, the rotation speed of the disk 119 is also changed in accordance with the air volume setting for each cooker described above.

  Next, the manual mode will be described. In the case of the manual mode, the control unit 136 controls the exhaust fan 116 in accordance with the operation of the air volume switch 122. Also in the manual mode, similarly to the automatic mode, the air flow rate for the gas cooker is set to Gs1 <Gs2 <Gs3, and the air flow rate for the IH cooker is set to Hs1 <Hs2 <Hs3.

  Also in the manual mode, the same control as in the above-described air volume control examples 1 to 3 is performed.

  That is, similarly to the air volume control example 1, by operating the air volume switch 122, Gs1> Hs1 for "low", Gs2 <Hs2 for "medium", and Gs3 = Hs3 for "high". Furthermore, the air volume Hs1 for the IH cooker in the case of “weak” may be the air volume 0 (that is, the exhaust fan is stopped).

  Similarly to the air volume control example 2, by operating the air volume switch 122, the air volume Gs1 to Gs3 for the gas cooker is changed from the air volume Hs1 to Hs3 for the IH cooker in any of “weak”, “medium”, and “strong”. May be increased. Further, in this control, the air volume Hs1 for the IH cooker in the case of "weak" may be the air volume 0 (that is, the exhaust fan is stopped).

  In the manual mode, when "weak" is selected by an instruction from the user and the setting is such that the minimum air volume Hs1 for the IH cooker is equal to the air volume 0 (the exhaust fan 116 is stopped), even if the temperature of the cooking utensil increases, the temperature remains unchanged. The air volume 0 will continue. Therefore, in the case of such a setting, it is preferable that the timer 137 further switches the mode from the manual mode to the automatic mode after a lapse of a predetermined time. As a result, even if the user selects the "weak" operation, the mode is switched to the automatic mode after that, and when the temperature reaches the temperature at which odor or oil smoke is generated, the operation is started and the odor or oil smoke is exhausted. Can be. The predetermined time may be determined at the stage of designing the range hood 100, or may be set later by the user. For example, depending on the output of the IH heater 310, the mode is switched to the automatic mode in about 1 to 5 minutes, which is the time required for boiling 500 ml of water. The time counting by the timer 137 starts when "weak" is selected by the user.

  Of course, if “weak” is selected and the exhaust fan 116 is stopped, and if “medium” or “strong” is selected even before the end of the predetermined time period, the control unit 136 Starts the operation so that the exhaust fan 116 has the air volume set as “medium” or “strong”. In this case, when “medium” or “strong” is selected, “weak” (the exhaust fan 116 is stopped) is not selected, so that even if a predetermined time has elapsed by the timer 137, the automatic mode is set. Does not switch (measurement may be stopped when "medium" or "strong" is selected). Then, when "weak" is selected next, the timer 137 starts counting the predetermined time from the beginning.

  Further, in the manual mode, similarly to the air volume control example 3, by operating the air volume switch 122, the air volume Gs1 to Gs3 for the gas cooker is changed to the air volume for the IH cooker in any of "low", "medium", and "strong". It may be set to be smaller than Hs1 to Hs3.

  The setting may be changed between the automatic mode and the manual mode. For example, the settings for the IH cooker include setting the minimum airflow Hs1 = airflow 0 in the automatic mode, and setting the minimum airflow at which the exhaust fan 116 can operate in the “weak” manual mode (in this case, the manual airflow mode in the manual mode). There is no need to switch from "weak" to automatic mode).

  In the manual mode control, the rotation speed of the disk 119 may be changed according to “weak”, “medium”, and “strong”. For example, when “weak” is selected, the rotation speed of the disk 119 is set to the minimum speed (or stop). When "medium" is selected, the rotation speed of the disk 119 is set to a medium speed higher than the minimum speed. When “strong” is selected, the rotation speed of the disk 119 is set to the maximum speed. Also, in the manual mode, the rotation speed may always be constant regardless of which one of "Low", "Medium", and "High" is selected. "May be a constant rotation speed. Further, in the manual mode, the air volume is arbitrarily selected by the user (in this case, any of “weak”, “medium”, and “strong”), but the control of the disk 119 is performed in the automatic mode described above. As described above, the temperature may be constantly changed according to the temperature detected by the temperature sensor 400.

  According to the embodiment described above, when the range hood 100 is used for the gas cooker 200 and when the range hood 100 is used for the IH cooker 300, the exhaust fan 116 is controlled so that the exhaust air volume is different. As a result, the amount of exhaust air suitable for each cooker can be obtained, and the odor and oil smoke generated during cooking can be exhausted efficiently and without waste.

  The embodiment of the present invention has been described above, but the present invention is not limited to the above embodiment. For example, in the embodiment, the range hood 100 having the automatic mode has been described, but the present invention is also applicable to a range hood having no automatic mode and only the manual mode.

  Further, in the embodiment, the example of the range hood 100 provided with the rotating filter (disc 119) for removing oily smoke has been described, but the present invention is also applicable to a range hood having no rotating filter (disc).

  Further, in the embodiment, in the case of both the gas cooker 200 and the IH cooker 300, the air flow is described as having three stages. However, the air flow may be set at two stages, or may be set at four or more stages. Further, the air volume may be changed steplessly. Also in these cases, the air volume is different between the gas cooker 200 and the IH cooker 300 as in the embodiment. In other words, the gas cooker 200 may be larger than the IH cooker 300 at all air flows regardless of the air flow stage, and conversely, the gas cooker 200 may be more IH at all air flows. You may make it less than the cooker 300. Further, the air volume of the gas cooker 200 and the IH cooker 300 may be different for each temperature range and each stage.

  Further, in the embodiment, the example of the range hood that exhausts air to the outside is shown, but the present invention is also applicable to an indoor circulation type range hood.

  Further, the present invention can be implemented in various forms based on the technical idea described in the claims, and it goes without saying that they are also within the scope of the present invention.

100 range hood,
116 exhaust fan,
119 disc (rotating filter),
120 operation panel,
122 air volume switch,
123 air volume automatic switch,
130 control device,
200 gas cookers,
210 gas burner,
300 IH cooker,
310 IH heater,
400 temperature sensor,
250, 350, 500 Top.

Claims (11)

A range hood having an exhaust fan and installed above the cooker,
A selection switch for selecting whether the cooker is a gas cooker or an IH cooker;
A control unit that controls the exhaust fan so that the gas cooker and the IH cooker have different air volumes based on the setting of the selection switch;
A range hood having   2. The range hood according to claim 1, wherein the control unit increases the air volume when the gas cooker is selected by the selection switch than when the IH cooker is selected. 3.   2. The range hood according to claim 1, wherein the control unit reduces the air volume when the gas cooker is selected by the selection switch as compared to when the IH cooker is selected. 3.   3. The range hood according to claim 1, wherein the control unit sets a minimum air volume when the IH cooker is selected by the selection switch to be smaller than a minimum air volume when the gas cooker is selected. 4.   The range hood according to claim 4, wherein the minimum air volume is in a state where the exhaust fan is stopped. Having a temperature sensor to detect the temperature of the top surface of the cooker,
The range hood according to any one of claims 1 to 5, wherein the control unit changes an air volume of the exhaust fan in accordance with a temperature detected by the temperature sensor. A temperature sensor that detects the temperature of the top surface of the cooker,
A timer for measuring a predetermined time,
The control unit, when the stop of the exhaust fan is selected by an instruction from a user, changes the air flow rate of the exhaust fan in accordance with the temperature detected by the temperature sensor after measuring a predetermined time by the timer. The range hood according to claim 5.   The range hood according to any one of claims 1 to 7, further comprising a rotating filter.   The range hood according to claim 8, wherein the control unit rotates the filter when controlling the air volume of the exhaust fan to a minimum air volume.   The range hood according to claim 8, wherein the control unit stops the rotation of the filter when controlling the air volume of the exhaust fan to a minimum air volume. It has a temperature sensor that detects the temperature of the top surface of the cooker,
The range hood according to any one of claims 8 to 10, wherein the control unit changes a rotation speed of the filter in accordance with a temperature detected by the temperature sensor.