JP2020143821A - Range hood - Google Patents

Abstract

To provide a range hood that enables a temperature sensor to be arranged while an operation panel position is kept as it is and that can detect a temperature above a cooker even when a temperature sensor position is not a central position.SOLUTION: A range hood 100 includes: a hood part 140; a control panel that comprises switches; and a temperature sensor 300 that comprises a detection part 310 for detecting a temperature above a cooker. The control panel is arranged in the center on the front side of the hood part. The temperature sensor is arranged on a bottom surface part 141 of the hood part in such a manner as to be displaced to either of right and left sides of the control panel. The detection part is arranged in the state of being inclined while being three-dimensionally twisted with respect to a horizontal plane.SELECTED DRAWING: Figure 9

Description

The present invention relates to a range hood.

There is a range hood with an automatic operation function that detects the upper temperature of the cooker by a temperature sensor provided in the hood and determines the air volume based on the detected temperature (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2012-137234

Such a range hood is provided with a temperature sensor in the center of the front side of the bottom surface of the hood portion. On the other hand, in general range hoods, the operation panel provided with switches is often provided in the center of the front surface of the hood portion so that the user can easily use it regardless of whether he or she is right-handed or left-handed. ..

Therefore, if you want to add an automatic operation function that determines the air volume based on the detected temperature by upgrading the general range hood, if you try to install a temperature sensor in the center of the front side of the bottom of the hood, the operation panel It will interfere. Therefore, there is a problem that a large design change is required and man-hours are required. Depending on the degree of design change, it may be necessary to change the mold, which causes a problem of high cost.

Therefore, the present invention provides a range hood in which the temperature sensor can be arranged while keeping the position of the operation panel as it is, and the upper temperature of the cooker can be detected even if the position of the temperature sensor is not in the center. The purpose is to provide.

The range hood of the present invention for achieving the above object includes a hood unit, an operation panel including switches, and a temperature sensor including a detection unit for detecting the upper temperature of the cooker. The operation panel is arranged in the center of the front side of the hood portion. The temperature sensor is arranged on the bottom surface of the hood portion so as to be offset to the left or right of the operation panel, and the detection portion is arranged so as to be three-dimensionally twisted and inclined with respect to the horizontal plane.

According to the present invention, the temperature sensor can be arranged while keeping the position of the operation panel as it is, and it is possible to detect the upper temperature of the cooker even if the position of the temperature sensor is not in the center.

It is a front view when the range hood of this embodiment is installed in a kitchen. It is a side view when the range hood of this embodiment is installed in a kitchen. It is a front view of the operation panel provided in the range hood of this embodiment. It is a perspective view which shows the temperature sensor and the sensor cover. It is a perspective view which shows the sensor cover separated from a temperature sensor, and further disassembled each component of a temperature sensor. It is a front view which shows the temperature sensor and the sensor cover. It is a side view which shows the temperature sensor and the sensor cover. It is a bottom view which shows a temperature sensor and a sensor cover. It is sectional drawing of the main part which shows the temperature sensor attached to the hood part, and the sensor cover. It is a perspective sectional view which shows by cutting out a part of a sensor cover. 11 (A) and 11 (B) are a front view and a side view showing an example of a monocular infrared sensor. It is a perspective view which shows an example of a compound eye type infrared sensor. It is a figure which shows typically the detection state of the upper temperature of a cooker by a temperature sensor. It is a figure which shows typically the detection area on the cooker when the temperature sensor is arranged in the hood part shifted from the center, and the detection part of a temperature sensor is arranged three-dimensionally twisted and inclined. It is a figure which shows typically the detection area of the temperature sensor when the separation distance between a hood part and a cooker is the minimum permissible distance. It is a figure which shows typically the detection area of the temperature sensor when the separation distance between a hood part and a cooker is a median value between the minimum permissible distance and the maximum permissible distance. It is a figure which shows typically the detection area of the temperature sensor when the separation distance between a hood part and a cooker is a maximum permissible distance. It is a block diagram of the control system of the range hood of this embodiment. It is an operation flowchart about the control of the air volume of a fan and / and the rotation speed of a filter in the range hood of this embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to the following embodiments. In addition, each drawing is exaggerated for convenience of explanation. Therefore, the dimensional ratio of each component in each drawing is different from the actual one. Further, the same elements are designated by the same reference numerals in the drawings, and duplicate description will be omitted in the specification.

(Mechanical system configuration of range hood 100)
1 and 2 are front views and side views when the range hood 100 according to the present embodiment is installed in the kitchen, and FIG. 3 is a front view of the operation panel 120 included in the range hood 100. 4 to 10 are views used for explaining the temperature sensor 300 and the sensor cover 400, FIG. 4 is a perspective view showing the temperature sensor 300 and the sensor cover 400, and FIG. 5 shows the sensor cover 400 as the temperature sensor 300. It is a perspective view which shows by disassembling each component of the temperature sensor 300 further separated from. 6, 7, and 8 are a front view, a side view, and a bottom view showing the temperature sensor 300 and the sensor cover 400. FIG. 9 is a sectional view of a main part showing the temperature sensor 300 and the sensor cover 400 attached to the hood portion 140, and FIG. 10 is a perspective sectional view showing a part of the sensor cover 400 cut out.

With reference to FIGS. 1 and 2, the range hood 100 includes a hood unit 140 located above the cooker 200, an operation panel 120 including switches, and a detection unit 310 for detecting the upper temperature of the cooker 200. It has a temperature sensor 300 and the like. The range hood 100 sucks in odors, smoke, oily odors and oily smoke generated during cooking performed by the cooker 200, and exhausts them to the outside. The illustrated cooker 200 has three heat sources 210 (collective term for the three heat sources 210A, 210B, 210C described later) and a grill outlet 220. In the present specification, the heat source 210 means a burner or a trivet near the burner for the gas cooker 200, and a heater for the IH cooker 200.

The range hood 100 includes a hood portion 140 and a main body portion 110 above the hood portion 140. The hood unit 140 collects the odor and oil smoke generated by cooking, and the main body 110 exhausts the collected odor and oil smoke. The hood unit 140 is provided with an intake port 112 that sucks in odors and oily smoke generated by cooking, and the main body 110 is sucked from the exhaust port 114 that communicates with the outside and into the passage connecting the intake port 112 and the exhaust port 114 from the intake port 112. It is equipped with a fan 116 that sucks and exhausts the oil smoke. The fan 116 is driven by the fan motor 117. A filter (disc) 118 that rotates to remove oil from oil smoke sucked from the intake port 112 is provided between the intake port 112 and the fan 116, or at the intake port 112. The filter 118 is driven by the filter motor 119. The range hood 100 can be operated by rotating only the fan 116, rotating both the fan 116 and the filter 118, or rotating only the filter 118. Further, the range hood 100 may be provided with a fixed (ordinary) filter that does not rotate, or may be a filterless range hood 100. The range hood 100 includes an operation panel 120 for instructing the operation of the range hood 100. The operation panel 120 is arranged in the center of the front side of the hood portion 140.

With reference to FIG. 3, the operation panel 120 has, as switches, an operation switch 121, an air volume switch 122, an air volume automatic switch 123, a timer switch 124, a lighting switch 125, a constant ventilation switch 126, and the like.

The operation switch 121 is a switch for operating the range hood 100. When the operation switch 121 is pressed, a range hood ON signal is transmitted (to a control unit described later), and when the operation switch 121 is pressed again, a range hood OFF signal is transmitted. The air volume switch 122 is a switch for manually switching the air volume of the fan 116 between weak, medium, and strong. The air volume automatic switch 123 automatically switches the air volume of the fan 116 and the rotation speed of the filter 118 stepwise or continuously according to the upper temperature of the cooker 200 detected by the temperature sensor 300. It is a switch for. This automatic operation is canceled when the air volume switch 122 is pressed. The timer switch 124 is a switch for rotating the fan 116 and the filter 118 after cooking is completed. The lighting switch 125 is a switch for turning on / off the LED bulb that illuminates the upper surface of the cooker 200. The constant ventilation switch 126 is a switch for operating / stopping the constant ventilation by manually rotating / stopping the fan 116.

The temperature sensor 300 is arranged on the bottom surface portion 141 of the hood portion 140 so as to be displaced to either the left or right side of the operation panel 120. In this embodiment, the temperature sensor 300 is displaced to the left side of the operation panel 120 (see FIG. 1). The temperature sensor 300 is arranged closer to the front side of the bottom surface portion 141 of the hood portion 140 (see FIG. 2).

With reference to FIGS. 4 to 9, the temperature sensor 300 includes a detection unit 310 that detects the upper temperature of the cooker 200, a case body 320 that houses the detection unit 310, and a lid that closes the upper opening 321 of the case body 320. It has a part 330 and. The detection unit 310 is composed of an infrared sensor. The case body 320 has a support portion 322 on which the detection unit 310 is placed. The lid portion 330 has a leg portion 331 that sandwiches the detection portion 310 with the support portion 322 of the case body 320. When the lid portion 330 is attached to the upper opening 321 of the case body 320, the detection portion 310 is sandwiched between the support portion 322 and the leg portion 331. The bottom surface portion 141 of the hood portion 140 is parallel to the horizontal plane. The case body 320 is arranged in the hood portion 140 so that the lower surface thereof is parallel to the bottom surface portion 141 of the hood portion 140. In a state where the temperature sensor 300 is arranged on the bottom surface portion 141 of the hood portion 140, the detection unit 310 is arranged so as to be three-dimensionally twisted and inclined with respect to the horizontal plane. More specifically, if the side in which the temperature sensor 300 is provided is one side and the other side is the other side in the left-right direction, the detection surface of the detection unit 310 is inclined so as to face the other side with respect to the horizontal plane, and is rearward. It is arranged at an angle so that it faces the side.

The range hood 100 further includes a sensor cover 400 arranged on the side of the detection surface of the temperature sensor 300. A general infrared sensor is a unit in which a lens unit is mounted on a substrate on which electronic components are mounted. The sensor cover 400 is indispensable for devices such as the range hood 100 that are installed in an environment where oily smoke and dust are generated.

With reference to FIG. 9, the hood portion 140 has a panel 150. The panel 150 includes a surface 150a constituting a bottom surface portion 141 visible to the cook, and a through hole 151. The sensor cover 400 is sandwiched between the back surface 150b of the panel 150 and the pressing portion 160 in a state of facing the extraction hole 151. In the present embodiment, the pressing portion 160 is the case body 320 of the temperature sensor 300. When the sensor cover 400 is sandwiched between the back surface 150b of the panel 150 and the pressing portion 160, the sensor cover 400 is arranged parallel to the horizontal plane.

The sensor cover 400 has a substantially rectangular plate shape. The sensor cover 400 has a protruding portion 410 having an outer peripheral shape corresponding to the inner peripheral shape of the punch hole 151 in the central portion thereof. The height of the protrusion 410 is the same as the plate thickness of the panel 150. The height of the protruding portion 410 does not have to be physically the same as the plate thickness of the panel 150, and the surface 410a of the protruding portion 410 of the sensor cover 400 and the surface of the panel 150 with the sensor cover 400 attached. A height that is substantially flush with 150a is sufficient. The surface 410a of the projecting portion 410 may project slightly from the surface 150a of the panel 150, or may be slightly recessed from the surface 150a of the panel 150. Since the surface 410a of the protruding portion 410 and the surface 150a of the panel 150 are substantially flush with each other, and the boundary between the inner circumference of the punched hole 151 and the outer circumference of the protruding portion 410 can be narrowed, the design is good and the design is good. Cleanability is good.

The sensor cover 400 has two pins 420 that project toward the case body 320. The lower surface of the case body 320 has a hole 323 into which the two pins 420 are fitted. The position of the sensor cover 400 with respect to the temperature sensor 300 is determined by fitting the two pins 420 into the hole 323.

The material for forming the sensor cover 400 is a resin material. The material for forming the sensor cover 400 is not limited as long as it is a material that transmits infrared rays at a constant level, and examples thereof include a single crystal silicon sheet and a resin material. Considering the ease of molding and cost reduction, the material for forming the sensor cover 400 is preferably a resin material. Examples of the resin material include high-density polyethylene and PTFE. The wall thickness is not particularly limited, but is preferably 1 mm or more because it may cause tearing if it is too thin.

With reference to FIGS. 4, 5 and 9, the lower surface of the case body 320 of the temperature sensor 300 is formed with a first surface 324 for pressing the sensor cover 400 against the panel 150 and a screw hole 326 for fixing the sensor cover 400 to the panel 150. It has a second surface 325 and the like. Two pins 327 are formed on the second surface 325. The heights of the first surface 324 and the second surface 325 are different, and a step is formed. The panel 150 is formed with a step corresponding to the shape of the step on the lower surface of the case body 320. The panel 150 has a first mounting portion 152 facing the first surface 324 of the case body 320 and a second mounting portion 153 facing the second surface 325 of the case body 320. The lower surface of the first mounting portion 152 of the panel 150 is a surface 150a constituting the bottom surface portion 141 visible to the cook. A through hole 151 is formed in the first mounting portion 152 of the panel 150. The second mounting portion 153 of the panel 150 is separated upward from the first mounting portion 152. The second mounting portion 153 of the panel 150 is penetrated by the first through hole 154 communicating with the screw hole 326 of the second surface 325 of the case body 320 and the two pins 327 of the second surface 325 of the case body 320. It has a second through hole (not shown).

The temperature sensor 300 is pressed against the back surface 150b from the inside of the panel 150. At this time, the soft sensor cover 400 is sandwiched between the panel 150, which is a product outer member, and the case body 320, which has strength. This makes it possible to prevent the sensor cover 400 from being deformed by touching it. The case body 320 can secure a certain strength depending on the wall thickness and shape even if it is an inexpensive resin such as ABS.

As shown in FIG. 9, the case body 320 of the sensor is fixed to the second mounting portion 153 of the panel 150 by the fastening screw 181 as the fixing portion 180. After fixing the temperature sensor 300 to the panel 150, the inner surface panel 170 constituting the bottom surface portion 141 of the hood portion 140 is attached. The inner panel 170 covers the second mounting portion 153 and the fastening screw 181 of the panel 150.

11 (A) and 11 (B) show an example of the monocular infrared sensor 341, and FIG. 12 shows an example of the compound eye infrared sensor 342.

As shown in the figure, the detection field of view of the general infrared sensors 341 and 342 is in the range of a quadrangular pyramid. When the temperature sensor 300 is arranged on the hood unit 140 by shifting it from the center to the left or right, it is necessary to direct the detection area of the detection unit 310 to the center of the cooker 200. Therefore, the detection unit 310 of the temperature sensor 300 is arranged so as to be three-dimensionally twisted and inclined with respect to the horizontal plane.

The temperature sensor 300 detects the temperature in the region shown by the dotted line in FIGS. 1 and 2. The temperature sensor 300 used in the present embodiment is composed of a compound eye temperature sensor that detects the upper temperature of the cooker 200 by a plurality of pixels. The compound eye temperature sensor has, for example, 64 pixels of 8 × 8 and can separately detect the temperature of the region corresponding to each pixel. The temperature sensor 300 can detect the upper temperature of the cooker 200 by dividing it into 64 regions, and can individually detect the temperature of each of the three heat sources 210. As the compound eye temperature sensor, for example, a compound eye infrared sensor 342 can be exemplified. The compound eye temperature sensor is not limited to the case where it has 64 pixels of 8 × 8 illustrated, and a compound eye temperature sensor having more pixels may be used.

In the present embodiment, the compound eye temperature sensor is used as the temperature sensor 300, but a monocular temperature sensor may be used. When a monocular temperature sensor is used, one monocular temperature sensor may be provided so as to detect the average temperature of the three heat sources 210, or each heat source can detect the temperature of each of the three heat sources 210 individually. Three monocular temperature sensors may be provided corresponding to 210. When actually equipped, a compound eye temperature sensor is preferable to a monocular temperature sensor. This is because the compound eye temperature sensor and the monocular temperature sensor can detect the temperature more accurately because of the difference in the number of pixels, and therefore the detection accuracy of the compound eye temperature sensor is better than the detection accuracy of the monocular temperature sensor.

FIG. 13 is a diagram schematically showing a state in which the temperature sensor 300 detects the upper temperature of the cooker 200. Since the temperature sensor 300 is attached to the bottom surface 141 of the range hood 100, the upper temperature of the cooker 200 is the heat source 210 (burner or the trivet or heater near the burner) 210A, 210B, 210C and the cooker 200. It is detected in the area covering the outlet 220 of the grill. Since the compound eye temperature sensor is used in this embodiment, the temperatures of the heat sources 210A, 210B, and 210C of the cooker 200 are the pixels (Tij (i = 1)) divided into 64, for example, 8 × 8 as shown in FIG. ~ 8, j = 1-8))) is detected as the temperature of the region corresponding to each of the heat sources 210A, 210B, 210C. On the other hand, when the temperature sensor 300 is a monocular temperature sensor, one monocular temperature sensor detects the average temperature of the three heat sources. Further, when three monocular temperature sensors are provided corresponding to the heat sources 210A, 210B, 210C of the cooker 200, the upper temperature of the cooker 200 is set for each of the heat sources 210A, 210B, 210C of the cooker 200. Detected. Therefore, the range hood 100 can easily determine which heat source 210A, 210B, 210C of the cooker 200 is used from the detection result of the temperature sensor 300.

FIG. 14 schematically shows a detection area on the cooker 200 when the temperature sensor 300 is arranged on the hood unit 140 so as to be offset from the center, and the detection unit 310 of the temperature sensor 300 is arranged three-dimensionally twisted and inclined. It is a figure shown in. The temperature sensor 300 is arranged on the hood unit 140 so as to be offset from the center to the left or right, and the detection unit 310 of the temperature sensor 300 is arranged so as to be three-dimensionally twisted and inclined with respect to the horizontal plane. The detection area on the cooker 200 at this time is as schematically shown in FIG. The shape of the pixels cut on the 200 side of the cooker is just a quadrangle. Here, "mere quadrangle" means not a square, a rectangle, a trapezoid, or a rhombus, but a quadrangle whose opposite sides are not parallel to each other. Further, the size of the pixel changes depending on the separation distance between the hood portion 140 and the cooker 200 (see reference numeral H in FIG. 1). The area of the pixel increases as the separation distance H increases, and decreases as the separation distance H decreases.

15 to 16 are diagrams schematically showing a detection area of the temperature sensor 300 when the separation distance H between the hood portion 140 and the cooker 200 is different. The hood unit 140 can be installed in the kitchen within a range of the separation distance H from the cooker 200 from the minimum allowable distance to the maximum allowable distance. The minimum permissible distance is, for example, 600 mm, and the maximum permissible distance is, for example, 1000 mm. In this case, the median value between the minimum permissible distance and the maximum permissible distance is 800 mm.

As shown in FIG. 15, the temperature sensor 300 has an area of more than half of the total area of the heat source 210 of the cooker 200 toward the center of the heat source 210 based on the case where the separation distance H is the minimum allowable distance (for example, 600 mm). It is arranged in a state where the upper temperature in the above can be detected. As described above, the area of the pixel increases as the separation distance H increases. As shown in FIG. 16, when the separation distance H is the median value (for example, 800 mm), the detection area of the temperature sensor 300 is wider than the detection area at the minimum allowable distance (for example, 600 mm), and the cooker 200 The upper temperature can be detected in a wider range. As shown in FIG. 17, when the separation distance H is the maximum permissible distance (for example, 1000 mm), the detection area of the temperature sensor 300 is even wider than the detection area at the median value (for example, 800 mm), and the cooker 200 It becomes possible to detect the upper temperature of the above in a wider range. In this way, by determining the detection range of the temperature sensor 300 based on the case where the separation distance H is the minimum allowable distance, the temperature sensor 300 can set the temperature sensor 300 within the range from the minimum allowable distance to the maximum allowable distance. The upper temperature of the cooker 200 can be detected. That is, if the hood unit 140 is installed in the kitchen within the allowable separation distance H, the temperature sensor 300 does not input the actual separation distance H to the range hood 100 after installing the range hood 100. The upper temperature can be detected.

As shown in FIG. 16, the temperature sensor 300 moves back and forth in the center of the cooker 200 in the left-right direction with reference to the case where the separation distance H is the median value (for example, 800 mm) between the minimum allowable distance and the maximum allowable distance. The cooker center line 230 extending in the direction and the detection range center line 350 extending in the front-rear direction at the center of the detection range of the temperature sensor 300 in the left-right direction are arranged in a state in which they can be matched. In this way, by aligning the detection range center line 350 of the temperature sensor 300 with the cooker center line 230 based on the case where the separation distance H is the median value, the temperature sensor 300 has the separation distance H from the minimum allowable distance. The upper temperature of the cooker 200 can be stably detected within the range up to the maximum permissible distance.

The temperature sensor 300 of the present embodiment is composed of a compound eye temperature sensor. As shown in FIGS. 15 to 17, the temperature sensor 300 is arranged in a state in which the pixels on the front side of the cooker side form a straight line parallel to the front side side of the cooker 200 in the rectangular detection area. The pixels on the front side of the temperature sensor 300 on the cook side pass through the center of the heat source 210 on the front side and are located on the front side (cooker side) of the line extending in the left-right direction parallel to the outer peripheral edge of the cooker 200. The edges to be aligned are indicated by reference numerals 231 in FIGS. 15 to 17. By arranging the temperature sensor 300 in the above-mentioned state, the distortion and the size of each pixel are minimized at any separation distance H. Therefore, the difference in detection accuracy for each pixel becomes small. This eliminates the need to make corrections based on the difference in distance between each pixel of the temperature sensor 300 and the cooker 200. Even if correction is necessary, the correction can be minimized. Further, by arranging the temperature sensor 300 in the above state, an inexpensive infrared sensor that looks like a regular quadrangular pyramid is used, and even if the size of the detection area changes depending on the separation distance H, general cooking is performed. The heat source of the vessel 200 can be detected.

The above "parallel" does not have to be physically parallel, and as long as the correction based on the difference in the distance between each pixel of the temperature sensor 300 and the cooker 200 can be eliminated or simplified. It suffices if the pixels on the front side of the cooker are laid out in a straight line and the straight line is substantially parallel to the front side of the cooker 200 (see Aligning Sides 231).

As shown in FIG. 9, the detection unit 310 of the temperature sensor 300 is arranged so as to be inclined with respect to the horizontal plane. The sensor cover 400 is arranged parallel to the horizontal plane. The temperature sensor 300 is composed of a compound eye temperature sensor. In such a case, when the thickness of the sensor cover 400 is uniform, the infrared transmission distance differs for each pixel, so that an error occurs between the detection temperature and the actual temperature for each pixel.

Therefore, it is preferable that the thickness of the sensor cover 400 is thicker in the portion where the distance from the cooker 200 is short than in the portion where the distance from the cooker 200 is long. More specifically, on the front side of the bottom surface portion 141 of the hood portion 140, if the side in which the temperature sensor 300 is provided is one side and the other side is the other side in the left-right direction, the other side of the sensor cover 400 is compared with one side. There is thickness. Or / and, the front side of the sensor cover 400 is thicker than the rear side. With this configuration, the infrared transmission distance of the sensor cover 400 is the same for each pixel. Therefore, it is possible to correct the error caused by the difference in the distance between each pixel of the temperature sensor 300 and the cooker 200.

Even when the temperature sensor 300 is composed of a monocular temperature sensor, as described above, the thickness of the sensor cover 400 is the distance between the sensor cover 400 and the cooker 200 as compared with the portion where the distance from the cooker 200 is long. It is preferable that the portion close to is thicker. This is because the error caused by the difference in the distance between each pixel of the temperature sensor 300 and the cooker 200 can be corrected.

(Structure of control system of range hood 100)
FIG. 18 is a block diagram of the control system of the range hood 100 of the present embodiment. The range hood 100 includes a fan 116, a fan motor 117, a filter 118, a filter motor 119, an operation panel 120, a control unit 130, and a temperature sensor 300. The control unit 130 includes a threshold temperature storage unit 135 and is built in the range hood 100.

The configurations and functions of the fan 116, the fan motor 117, the filter 118, the filter motor 119, the operation panel 120, and the temperature sensor 300 are as described above.

The threshold temperature storage unit 135 stores the threshold temperature for changing the air volume of the fan 116 and / and the rotation speed of the filter 118. The threshold temperature storage unit 135 stores the threshold temperature corresponding to each region of the upper temperature detected by the temperature sensor 300.

The control unit 130 is the upper temperature and threshold temperature storage unit of the cooker 200 detected by the temperature sensor 300 when the air volume automatic switch 123 (see FIG. 3) of the operation panel 120 is pressed and the range hood 100 is automatically operated. The air volume of the fan 116 is determined by comparing with the threshold temperature (for the fan) stored in the 135. Further, the control unit 130 compares the upper temperature of the cooker 200 detected by the temperature sensor 300 with the threshold temperature (for the filter) stored in the threshold temperature storage unit 135, and determines the rotation speed of the filter 118. .. In this embodiment, both the air volume of the fan 116 and the rotation speed of the filter 118 are determined by the control unit 130, but the present invention is not limited to this, and either one may be determined by the control unit 130. Further, the control unit 130 determines only the air volume of the fan 116 in the case of a filterless range hood not provided with the filter 118 or a range hood provided with a fixed filter.

The control unit 130 sets the threshold temperature to be lower in the pixels where the distance between the temperature sensor 300 and the cooker 200 is longer than in the pixels where the distance between the temperature sensor 300 and the cooker 200 is short. Set. More specifically, on the front side of the bottom surface portion 141 of the hood portion 140, assuming that the side in which the temperature sensor 300 is provided is one side and the other side is the other side, the temperature threshold value of each pixel of the temperature sensor 300 is set to one side. The temperature threshold on the other side is corrected to be lower than the temperature threshold of. Or / and, the temperature threshold value of each pixel of the temperature sensor 300 is corrected so that the temperature threshold value on the rear side is lower than the temperature threshold value on the front side.

The reasons why the temperature threshold needs to be corrected are as follows. The shorter the distance between each pixel of the temperature sensor 300 and the cooker 200, the narrower the detection range detected by one pixel, and the farther the distance between each pixel and the cooker 200, the wider the detection range detected by one pixel. .. For example, looking at FIG. 17, the lower left pixel has a small mass area, while the upper right pixel has a large mass area. This is because the compound eye temperature sensor captures the average temperature of each pixel as the temperature of the pixel, and therefore, the larger the mass area, the lower the average temperature tends to be detected. Therefore, the threshold temperature is set to a pixel in which the distance between the temperature sensor 300 and the cooker 200 is longer than that in the pixel in which the distance between the temperature sensor 300 and the cooker 200 is short (that is, the area of the mass is small). That is, by correcting so that the area of the mass is larger), the error caused by the difference in the distance between each pixel of the temperature sensor 300 and the cooker 200 can be corrected.

The temperature sensor 300 generates an electric signal when the detection unit 310 receives infrared rays emitted from the object. The temperature of the object is determined by converting the electrical signal output from the temperature sensor 300 into temperature. The "threshold temperature" in the present specification includes not only the temperature converted from the electric signal but also the electric signal itself output from the temperature sensor 300 corresponding to the temperature. Therefore, the "threshold temperature correction" may be corrected for the temperature converted from the electric signal, or may be corrected for the electric signal itself, and any pattern is included.

As shown in FIGS. 15 to 17, since the temperature sensor 300 is not installed directly above the center of the cooking surface of the cooker 200, the range in which each region of the temperature sensor 300 detects the temperature is shown in these figures. Distorted as shown. Therefore, due to the difference in the separation distance H between the cooker 200 and the range hood 100, for example, even if the heat source 210A is the same, the region where the temperature sensor 300 detects the temperature of the heat source 210 shifts. Similarly, even if the outlet 220 of the same grill is used, the area where the temperature sensor 300 detects the temperature of the outlet 220 of the grill shifts.

Due to this deviation, it becomes impossible to accurately specify the position of the outlet of the grill. Therefore, when it is desired to accurately specify the position and number of the heat source 210, the position of the outlet of the grill, etc., the storage unit of the control unit 130 stores the position of each heat source 210 and the outlet 220 of the grill for each separation distance H. Information on which region of the temperature sensor 300 the position corresponds to may be stored. In this case, the separation distance H can be set when the range hood 100 is installed at the site.

The control unit 130 sets the threshold temperature so that it is lower when the separation distance H is large than when the separation distance H is small.

(Operation of control unit 130)
FIG. 19 is an operation flowchart for controlling the air volume of the fan 116 and / and the rotation speed of the filter 118 in the range hood 100 of the present embodiment. This operation flowchart is processed by the control unit 130. This operation flowchart is executed when the air volume automatic switch 123 of the operation panel 120 (see FIGS. 3 and 18) is pressed and the range hood 100 is automatically operated.

The control unit 130 detects the upper temperature of the cooker 200 by the temperature sensor 300 (S100). The upper temperature is detected for each region. Specifically, as shown in FIG. 13, the temperature of all regions Tij = T11 to T88 of the temperature sensor 300 is detected.

Next, the control unit 130 compares the detected upper temperature of the cooker 200 with the threshold temperature stored in the threshold temperature storage unit 135 (S110). Next, the control unit 130 controls the air volume of the fan 116 and / or the rotation speed of the filter 118 according to the comparison result between the upper temperature of the cooker 200 and the threshold temperature (S120). In this case, the higher the upper temperature of the cooker 200, the higher the air volume of the fan 116 and / or the rotation speed of the filter 118, and the lower the upper temperature of the cooker 200, the higher the air volume of the fan 116 and / or the rotation speed of the filter 118. It becomes smaller. In this way, the air volume of the fan 116 and the rotation speed of the filter 118 can be determined based on the upper temperature detected by the temperature sensor 300 and automatically operated.

The control unit 130 sets the threshold temperature to be lower in the pixels where the distance between the temperature sensor 300 and the cooker 200 is longer than in the pixels where the distance between the temperature sensor 300 and the cooker 200 is short. Set. By changing the threshold temperature according to the distance between each pixel of the temperature sensor 300 and the cooker 200 in this way, the error caused by the difference in the distance between each pixel of the temperature sensor 300 and the cooker 200 is corrected. can do.

The control unit 130 sets the threshold temperature so that it is lower when the separation distance H is large than when the separation distance H is small. By changing the threshold temperature according to the separation distance H in this way, it is possible to correct the error caused by the difference in the separation distance H. In addition, the position and number of each heat source 210, whether or not the grill is used, the position of the outlet 220 of the grill, and the like can be grasped more accurately.

(Type of range hood)
Range hoods are classified into "deep type", "flat type", "thin type", "falcon type", "square type", "undercut type" and the like according to the shape of the outer shell. The present invention is applicable to any type of range hood.

As described above, the range hood 100 includes a hood unit 140, an operation panel 120 including switches, and a temperature sensor 300 including a detection unit 310 for detecting the upper temperature of the cooker 200. The operation panel 120 is arranged in the center of the front side of the hood portion 140, and the temperature sensor 300 is arranged on the bottom surface portion 141 of the hood portion 140 so as to be displaced to either the left or right side of the operation panel 120. The detection unit 310 is arranged so as to be three-dimensionally twisted and inclined with respect to the horizontal plane.

With this configuration, the temperature sensor 300 can be provided while keeping the positions of the switches on the operation panel 120 as they are, so that the design change can be minimized. Moreover, since the mold is not changed, the cost can be suppressed. Further, the temperature above the cooker 200 can be detected even if the temperature sensor 300 is not located at the center. In this way, the temperature sensor 300 can be arranged while keeping the position of the operation panel 120 as it is, and the range capable of detecting the upper temperature of the cooker 200 even if the position of the temperature sensor 300 is not in the center. Food 100 can be provided. Further, the switches and lights provided on the operation panel 120 arranged at the center can be mounted on the hood portion 140 without being affected by the installation of the temperature sensor 300, and can be designed.

The hood unit 140 can be installed within a range in which the separation distance H from the cooker 200 is from the minimum allowable distance to the maximum allowable distance. The temperature sensor 300 is arranged in a state where it can detect an upper temperature in an area of more than half of the total area of the cooker 200 near the center of the heat source 210, based on the case where the separation distance H is the minimum allowable distance.

With this configuration, the temperature sensor 300 can detect the upper temperature of the cooker 200 within a range in which the separation distance H is from the minimum allowable distance to the maximum allowable distance.

The temperature sensor 300 extends in the front-rear direction at the center of the cooker 200 in the left-right direction with reference to the time when the separation distance H is the median value between the minimum allowable distance and the maximum allowable distance. And the detection range center line 350 extending in the front-rear direction at the center of the detection range of the temperature sensor 300 in the left-right direction are arranged in a state in which they can be matched.

With this configuration, the temperature sensor 300 can stably detect the upper temperature of the cooker 200 within a range in which the separation distance H is from the minimum allowable distance to the maximum allowable distance.

The temperature sensor 300 is composed of a compound eye temperature sensor that detects the upper temperature of the cooker 200 by a plurality of pixels. The temperature sensor 300 is arranged so that the pixels on the front side of the cooker form a straight line parallel to the front side of the cooker 200.

With this configuration, the difference in detection accuracy for each pixel becomes small. This eliminates the need to make corrections based on the difference in distance between each pixel of the temperature sensor 300 and the cooker 200. Even if correction is necessary, the correction can be minimized.

The range hood 100 further includes a sensor cover 400 arranged on the side of the detection surface of the temperature sensor 300. The temperature sensor 300 is composed of a binocular temperature sensor that detects the upper temperature of the cooker 200 by a plurality of pixels, and the sensor cover 400 is arranged parallel to the horizontal plane. The thickness of the sensor cover 400 is thicker in the portion where the distance from the cooker 200 is short than in the portion where the distance from the cooker 200 is long.

With this configuration, it is possible to correct the error caused by the difference in the distance between each pixel of the temperature sensor 300 and the cooker 200.

The range hood 100 includes a control unit 130 that controls the operating state of the range hood 100 by comparing the upper temperature detected by the temperature sensor 300 with a preset threshold temperature. The temperature sensor 300 is composed of a compound eye temperature sensor. The threshold temperature is lower in the pixels where the distance between the temperature sensor 300 and the cooker 200 is longer than in the pixels where the distance between the temperature sensor 300 and the cooker 200 is short. Note that controlling the operating state of the range hood 100 means controlling only the air volume of the fan 116, controlling both the air volume of the fan 116 and the rotation speed of the filter 118, and controlling only the rotation speed of the filter 118. Includes one of the things.

When controlling the operating state of the range hood 100 by changing the threshold temperature according to the distance between each pixel of the temperature sensor 300 and the cooker 200 in this way, each pixel of the temperature sensor 300 and the cooker 200 The error caused by the difference in distance between the and can be corrected.

The range hood 100 has a control unit 130, and the threshold temperature is lower when the separation distance H is large than when the separation distance H is small.

By changing the threshold temperature according to the separation distance H in this way, it is possible to correct the error caused by the difference in the separation distance H when controlling the operating state of the range hood 100.

The control unit 130 of the range hood 100 of the embodiment also controls the rotation speed of the filter 118 by comparing the upper temperature detected by the temperature sensor 300 with a preset threshold temperature. Therefore, the control unit 130 controls only the air volume of the fan 116 based on the upper temperature detected by the temperature sensor 300, controls both the air volume of the fan 116 and the rotation speed of the filter 118, and controls the filter 118. Any automatic operation that controls only the number of revolutions can be executed.

In the range hood 100 of the above-described embodiment, the thickness of the sensor cover 400 is different from that of the cooker 200 in order to correct the error caused by the difference in the distance between each pixel of the temperature sensor 300 and the cooker 200. The part that is close to the cooker 200 is thicker than the part that is far away. When the wall thickness of the sensor cover 400 is made uniform, the thickness through which infrared rays pass is different in the infrared ray passing region of the sensor cover 400 assigned to each pixel. That is, the infrared transmittance of each pixel is different. In this case, the correct temperature of each pixel can be derived by confirming the transmittance of each pixel in advance with a blackbody furnace or the like and using that value as a correction value in the control program.

Since the temperature sensor 300 is composed of a compound eye temperature sensor, in addition to the above correction values, a correction may be added so as to lower the temperature of the pixel to be reacted more excessively. If the correction is performed to lower the temperature, the threshold temperature will be exceeded and the operation will be difficult. The reverse is also true.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and can be implemented as various embodiments based on the technical ideas described in the claims. Needless to say, they are also in the scope of the present invention.

100 range hood,
110 body,
112 intake,
114 Exhaust port,
116 fans,
117 fan motor,
118 filters,
119 filter motor,
120 operation panel,
130 control unit,
135 Threshold temperature storage,
140 Food section,
141 bottom part,
150 panels,
150a surface,
150b back side,
151 punch hole,
152 First mounting part,
153 Second mounting part,
180 fixed part,
181 Fastening screw,
200 cooker,
230 cooker centerline,
231 Aligned sides,
300 temperature sensor,
310 detector,
320 case body,
321 Top opening,
322 Support,
323 holes,
324 first page,
325 second side,
326 screw holes,
327 pins,
330 lid,
331 legs,
350 detection range centerline,
400 sensor cover,
410 protrusion,
410a surface,
420 pins,
H separation distance.

Claims (7)

With the hood part
An operation panel with switches and
It has a temperature sensor provided with a detection unit that detects the upper temperature of the cooker, and has.
The operation panel is arranged in the center of the front side of the hood portion.
The temperature sensor is arranged on the bottom surface of the hood portion by shifting to either the left or right side of the operation panel, and the detection portion is arranged so as to be three-dimensionally twisted and inclined with respect to the horizontal plane. Hood. The hood portion can be installed within a range of the separation distance from the cooker from the minimum allowable distance to the maximum allowable distance.
The temperature sensor is arranged in a state in which it can detect an upper temperature in an area of at least half of the total area of the cooker near the center of the heat source, based on the case where the separation distance is the minimum allowable distance. The range hood according to claim 1. The temperature sensor has a cooker center line extending in the front-rear direction at the center of the cooker in the left-right direction with reference to the case where the separation distance is the median value between the minimum allowable distance and the maximum allowable distance. The range hood according to claim 2, wherein the range hood is arranged so that the center line of the detection range extending in the front-rear direction can be matched with the center line of the detection range of the temperature sensor in the left-right direction. The temperature sensor is composed of a compound eye temperature sensor that detects the upper temperature of the cooker by a plurality of pixels.
The range hood according to any one of claims 1 to 3, wherein the temperature sensor is arranged in a state in which the pixels on the front side of the cooker form a straight line parallel to the front side of the cooker. Further having a sensor cover arranged on the side of the detection surface of the temperature sensor
The sensor cover is arranged parallel to the horizontal plane and
Any of claims 1 to 3, wherein the thickness of the sensor cover is thicker at a portion where the distance between the detection unit and the cooker is short than at a portion where the distance between the detection unit and the cooker is long. The range hood according to item 1. Further, it has a control unit for controlling the operating state of the range hood by comparing the upper temperature detected by the temperature sensor with a preset threshold temperature.
The temperature sensor is composed of a compound eye temperature sensor that detects the upper temperature of the cooker by a plurality of pixels.
The threshold temperature is lower in the pixels in which the distance between the temperature sensor and the cooker is long than in the pixels in which the distance between the detection unit and the cooker is short. The range hood according to any one item. Further, it has a control unit for controlling the operating state of the range hood by comparing the upper temperature detected by the temperature sensor with a preset threshold temperature.
The range hood according to claim 2 or 3, wherein the threshold temperature is lower when the separation distance is large than when the separation distance is small.