JP6774733B2 - Range food - Google Patents

Description

The present invention relates to a range hood, and more particularly to a range hood having a member that raises and lowers so that a part of the hood can be stored in a cabinet when not in use.

A range hood installed in a kitchen or the like sucks steam, oil smoke, etc. generated by cooking performed with a cooking utensil together with the air flow generated by a blower, and after cleaning, the oil smoke remaining with the sucked air. Etc. are discharged to the outdoors.

Conventionally, a range hood that can be raised from a cabinet during cooking and stored in a cabinet when not in use after cooking has been known, centering on a dining kitchen and an island kitchen that does not have a partition wall.

For example, Patent Document 1 describes a range hood having two columns that can be raised and lowered with respect to a cabinet, and a hood portion having a suction port and the like over the upper surfaces of the two columns. In this range hood, the hood part is located above the cooking utensil by raising the support during cooking, and the oil smoke generated by cooking is sucked from the suction port provided in the hood part and exhausted or purified to the outside and indoors. Discharge to. Then, after the cooking is completed, the upper surface of the cooker is covered with the hood portion by lowering the support column.

Japanese Patent No. 2619471

However, in such a range hood, when the hood is lowered after cooking, a part of the body or a pot left behind during cooking may be caught between the hood and the cabinet, resulting in injury or damage to the object. I was afraid.

Therefore, the present invention has been made in view of the above problems, and an object of the present invention is to provide a range hood in which the hood portion rises when in use and falls when not in use, and when lowered by a simple configuration. The purpose is to provide a range hood having a self-inspection function for ensuring safety and maintaining the safety.

In order to solve the above problems, a cabinet having a cooking device, a support portion provided vertically movably to the cabinet, is supported by the supporting part, raised to the top plate facing the cabinet in use, not comprising a hood portion disposed in the vicinity of the top plate is lowered at the time of use, and a sensor for detecting an object between the top plate and the hood portion, said support portion is coupled between the hood portion to the position where the hood portion a part near does not consists in the detection range, has an optical surface of the sensor, the sensor detects the presence or absence of an object to be sandwiched between the top plate and the hood portion,
A range hood having a mechanism for stopping the descent when the sensor detects an object is provided.
According to this, since the support portion has the sensor at a position near the joint portion with the hood portion and the hood portion does not exist in the detection range, the sensor is connected to the hood portion and the top plate in the process of lowering the support portion. Since the object between the two is detected, it is possible to provide a range hood that is safe when descending with a simple configuration. Further, since the detection is performed only in the vicinity of the joint portion with the hood portion, that is, only the minimum detection range, the minimum sensor is required and the cost can be reduced.
Then, when the hood is lowered after cooking, a part of the body or a pot or the like left behind during cooking is caught between the hood and the cabinet, and there is no risk of injury or damage to the object .

Further, a self-inspection unit that performs self-inspection based on the detection result of the sensor is further provided, and the self-inspection unit detects the sensor in the space through which the hood unit passes while the sensor is functioning in the process of raising the support unit. By continuing, it may be characterized by inspecting that the optical surface of the sensor is dirty.
According to this, when dirt such as oil is attached to the optical surface of the sensor, the dirt attached to the optical surface of the sensor is continuously detected when the sensor is operated in the process of raising the support portion. Therefore, it is possible to inspect that the optical surface of the sensor is dirty by continuing to detect the sensor in the space where the hood portion has passed. In addition, by using a configuration in which the support part always rises in order to put the range hood into use, it is possible to perform a self-inspection to ensure safety when descending and maintain that safety with a simple configuration. it can.

Further, when the support is lowered when not in use and is in the lowest point position, at least a part of the optical surface of the sensor is below the upper surface of the top plate, and the self-inspection part has the support as the lowest point. It may be characterized by inspecting that the sensor is functioning normally by detecting the top plate when the sensor starts to rise from the position of.
According to this, when the sensor is defective, even if the sensor is below the top surface of the top plate, the sensor cannot detect the top plate, so that at least a part of the sensor is below the top surface of the top plate. Moreover, it is possible to inspect that the sensor is functioning normally by detecting the top plate of the sensor. In addition, by using a configuration in which the support portion is always raised in order to put the range hood into use, self-inspection can be performed with a simple configuration.

As described above, according to the present invention, the hood portion at the time of use increases, the range hood to be lowered when not in use, can provide a range hood to reduce the safety at the time of descending a simple configuration.

(A) front view, (B) plan view, (C) left side view, (D) rear view, in a state where the elevating member in the first embodiment of the range hood according to the present invention is raised. The perspective view seen from the upper right in the state where the elevating member is raised in the 1st Example of the range hood which concerns on this invention. (A) front view, (B) plan view, (C) left side view, (D) rear view in a state where the elevating member in the first embodiment of the range hood according to the present invention is lowered. The perspective view seen from the upper right in the state where the elevating member is lowered in the 1st Example of the range hood which concerns on this invention. A cross-sectional view of (A) FIG. 3 (C) I-I cross section and (B) FIG. 3 (A) II-II cross section of the range hood according to the first embodiment of the present invention in a lowered state. FIG. 3, (C) an enlarged cross-sectional view of the vicinity of the joint in the cross section of FIG. 3 (C) I-I, and (B) an enlarged cross-sectional view of the vicinity of the joint in the cross section of FIG.

Hereinafter, each embodiment of the present invention will be described with reference to the drawings.
<First Example>
1 and 2 show a range hood 1 in use in the first embodiment of the present invention, and FIGS. 3 and 4 show a range hood 1 in use. The range hood 1 includes a cabinet 10 placed on the floor of a kitchen or the like, an elevating member 2 that partially moves up and down from the top plate 12 of the cabinet 10, and a drive device 60 that drives the elevating member 2 up and down. The fan 50 is arranged in the cabinet 10 to generate an air flow, and the purification device 70 is arranged on the air flow path. The top plate 12 of the cabinet 10 is provided with a cooking device 11, a discharge port 13, and an infestation hole 14 in the vicinity of the cooking device 11 on the right back side where the elevating member 2 appears and disappears.

The fan 50 is preferably a sirocco fan having a high static pressure, but is not particularly limited. Further, the purification device 70 is preferably composed of a plurality of types of filters. For example, a grease filter (woven cloth such as glass wool, non-woven fabric filter, lath net, slot filter, metal filter such as punching metal) for removing mainly oils and fats contained in air and inorganic ions are adsorbed. It is composed of a filter made of a continuously porous foam coated with a deodorant element. Of course, the purification device is not limited to this as long as it can remove oils and fats and odorous components from air containing oily smoke and the like.

The elevating member 2 is located substantially directly above the cooking cooker 11 when in use, and at a position where there is a slight gap from the top plate 12 when not in use, and supports the hood portion 30 having the suction port 31 and the hood portion 30. It is provided with a support portion 20 having a substantially constant radius of curvature and appearing and disappearing from the indentation hole 14 of the top plate 12, and an action portion 40 that supports the support portion 20 inside the cabinet 10 and raises and lowers the support portion 20.

In the range hood 1, when not in use, as shown in FIGS. 3 and 4, most of the support portion 20 is submerged below the upper surface SF of the top plate 12 and is housed in the cabinet 10. It is located on the back side of the upper surface of the top plate 12 with a slight gap from the upper surface SF, and is arranged in the vicinity of the top plate 12. However, the hood portion 30 may be in contact with the upper surface SF of the top plate 12 when not in use.

In the range hood 1, when the switch to be used in the unused state is turned on, the drive device 60 having a telescopic mechanism is pivotally supported by the upper part on the front side in the cabinet 10 by extending. The acting portion 40 is pushed up, and the entire elevating member 2 is raised until the acting portion 40 becomes almost horizontal. Then, almost the entire support portion 20 appears on the upper surface SF of the top plate 12, and the hood portion 30 of the elevating member 2 is located directly above the cooking cooker 11 and faces the upper surface of the top plate 12. It will be. The range hood 1 is locked at a position where the hood portion 30 is located directly above the cooking cooker 11 to maintain this state, and the fan 50 is operated to be in a usable state.

The range hood 1 in the used state receives air containing steam, oil smoke, etc. generated by cooking in the cooking cooker 11 from a suction port 31 provided in the hood portion 30 according to the flow of air generated by the fan 50. Inhale. The air sucked from the suction port 31 is guided to the purification device 70 through an air passage (not shown) provided inside the hood portion 30, the support portion 20, and the cabinet 10. The air guided to the purification device 70 is removed from oil smoke and the like, and is discharged from the discharge port 13 provided on the top plate 12. Of course, as in this embodiment, the purified air may be returned to circulate in the room through the discharge port 13, or the cleaned air may be exhausted to the outside through a duct.

On the contrary, when the drive device 60 is changed from the used state of the range hood 1 shown in FIGS. 1 and 2 to the unused state shown in FIGS. 3 and 4, the drive device 60 is driven so as to shorten itself in order to lower the elevating member 2. .. Alternatively, the drive device 60 may only release the lock when lowering the elevating member 2, and may be shortened by the weight of the elevating member 2 without using the power of the driving device 60. When lowering 2, a load may or may not be generated. For example, the drive device 60 is a linear actuator that drives only in the ascending direction or in both the ascending and descending directions. When the drive device 60 drives the elevating member 2 so as to shorten itself so as to lower the elevating member 2, the drive device 60 stops its own drive when the sensor detects an object, as will be described later. Further, when the drive device 60 lowers the elevating member 2 by its own weight, the drive device 60 has a mechanism for stopping the lowering when the sensor detects an object.

The range hood 1 includes a sensor 24 (shown in FIG. 5) that detects an object between the hood portion 30 and the top plate 12. The sensor 24 functions while the elevating member 2 that goes from the used state to the unused state is lowered, and the lowering of the hood portion 30 may cause the sensor 24 to be sandwiched between the hood portion 30 and the top plate 12. Detects the presence or absence. The sensor 24 includes an optical surface 21 in the support portion 20 in the vicinity of the coupling portion 23 with the hood portion 30.

The sensor 24 is an infrared motion sensor, and the sensor itself emits infrared light from an optical surface such as an LED, and the reflected light is used to inspect whether or not an object such as a human body exists within a predetermined distance. Here, it is preferable that the predetermined range has an inspection distance substantially equal to the width W of the hood portion 30 in the width direction (direction perpendicular to the optical surface 21).

Further, the vertical width direction (direction parallel to the optical surface 21) in a predetermined range is the inspection width according to the specifications of the sensor. The optical surface 21 is provided near the coupling portion 23 with the hood portion 30 at a position where the hood portion 30 does not exist in the detection range of the sensor 24. That is, the distance from the coupling portion 23 in which the hood portion 30 and the support portion 20 are coupled, in other words, the corner portion formed by the hood portion 30 and the support portion 20, to the center of the optical surface 21 of the sensor 24 is the sensor. The distance is slightly longer than about half the length of the 24 inspection widths.

Within such a predetermined range, the sensor 24 detects an object between the hood portion 30 and the top plate 12 in the vicinity of the lower side of the hood portion 30 in the process of lowering the support portion 20, so that the sensor 24 descends with a simple configuration. In addition to providing the range hood 1 for time safety, the hood portion 30 that descends together with the optical surface 21 is located at a position that does not exist in the detection range, so that infrared light is reflected by the hood portion 30 and diffuse reflection occurs. It is possible to prevent malfunctions that occur as a result. Further, since the detection is performed only in the vicinity of the coupling portion with the hood portion 30, that is, only the minimum detection range, the minimum sensor is required and the cost can be reduced.

A self-inspection (self-check) in the range hood 1 will be described with reference to FIG. The range hood 1 includes an optical surface 21 of the sensor 24 in the support portion 20 in the vicinity of the coupling portion 23 with the hood portion 30. The sensor 24 emits and irradiates infrared light from the optical surface 21 in a direction substantially perpendicular to the optical surface 21 to detect an object within a predetermined range. When the support portion 20 is lowered when not in use and is at the lowest point position (the state shown in FIG. 5), the optical surface 21 is located below the upper surface SF of the top plate 12.

In this embodiment, the entire optical surface 21 is located below the upper surface SF of the top plate 12, but since the sensor 24 only needs to detect the side surface of the infestation hole 14 of the top plate 12, at least a part of the optical surface 21 May be located below the upper surface SF of the top plate 12. If at least a part of the optical surface 21 is located below the upper surface SF of the top plate 12 when the range hood 1 is to be changed from the unused state to the used state, and the sensor 24 is functioning normally. The side surface of the infestation hole 14 of the top plate 12 is detected. When a plurality of optical surfaces 21 are provided, it is preferable that a part of each of the optical surfaces 21 is located below the upper surface SF of the top plate 12. If the sensor element itself has a self-inspection function, it is not necessary to have such a configuration.

When having such a configuration, it is preferable that the range hood 1 includes a self-inspection unit 22. The self-inspection unit 22 inspects whether or not the sensor 24 is functioning normally based on the detection result of the sensor 24. When the switch to be used in the unused state is turned on, that is, when the support portion 20 starts to rise from the position of the lowest point, the self-inspection unit 22 activates the sensor 24 so that the sensor 24 is a top plate. Inspect whether or not 12 is detected. When the sensor 24 detects the side surface of the indentation hole 14 of the top plate 12, the self-inspection unit 22 determines that the sensor 24 is functioning normally. If the sensor 24 does not detect the side surface of the indentation hole 14, the self-inspection unit 22 determines that the sensor 24 is not functioning normally. When the switch for using the product in the unused state is turned on, the self-inspection unit 22 operates the sensor 24 and the sensor 24 is heavenly before the support unit 20 starts to rise from the position of the lowest point. You may inspect whether or not the plate 12 is detected.

According to this, when the sensor 24 is defective, even if the sensor 24 is below the upper surface SF of the top plate 12, the sensor 24 cannot detect the top plate 12, so that at least a part of the sensor 24 is on the top. It is possible to inspect that the sensor 24 is functioning normally by detecting the top plate 12 below the upper surface SF of the plate 12. Further, by using a configuration in which the support portion 20 is always raised in order to put the range hood 1 into use, a self-inspection can be performed with a simple configuration.

In addition, the self-inspection unit 22 causes the sensor 24 to function even in the process of raising the support unit 20. Then, the self-inspection unit 22 inspects whether or not the sensor 24 detects any object in the space through which the hood unit 30 has passed while the support unit 20 is in the process of rising and the sensor 24 is operating. Since the hood portion 30 has just passed through, that is, the space below the hood portion 30, there is usually no object in the space through which the rising hood portion 30 has passed. Nevertheless, if the sensor 24 continues to detect some object, the self-inspection unit 22 determines that the optical surface 21 of the sensor 24 is dirty.

According to this, when dirt such as oil adheres to the optical surface 21 of the sensor 24, the optical surface 21 of the sensor 24 is in the process of raising the support portion 20 while the sensor 24 is operating. It will continue to detect dirt adhering to the. Therefore, it is possible to inspect that the optical surface 21 of the sensor 24 is dirty by the sensor continuing to detect in the space through which the hood portion 30 has passed. In addition, by using a configuration in which the support portion 20 always rises in order to put the range hood 1 into use, a self-inspection is performed to ensure safety when descending and to maintain the safety with a simple configuration. be able to.

<Other Examples>
In the above embodiment, the hood portion is cantilevered by one support portion, but two support portions may be provided on both sides and held by both sides. Further, in the above embodiment, the width of the hood portion in the depth direction is not so large and is beam-shaped, but even if the width in the depth direction is increased and the lid is used to cover the top plate of the cabinet when not in use. Good. Further, in the above embodiment, the suction port is provided only in the hood portion, but may be provided in another location such as a support portion.

Further, in the above embodiment, an air passage, a purification device, and a blower are provided inside the cabinet having the cooking cooker, and the elevating member is configured to appear and disappear from the indentation hole provided in the top plate of the cabinet. However, a cabinet having a cooking cooker and a range hood in which an air passage, a purification device, a blower, and an elevating member are unitized may be configured separately, and such a range hood may be installed adjacent to the cabinet. Even in this case, the hood portion of the elevating member is configured to face the top plate of the cabinet when in use and to be arranged in the vicinity of the top plate of the cabinet when not in use.

The present invention is not limited to the illustrated examples, and can be implemented with a configuration within a range that does not deviate from the contents described in each section of the claims. That is, the present invention is mainly illustrated and described with respect to a specific embodiment, but without departing from the scope of the technical idea and purpose of the present invention, the shape and material of the above-described embodiment are not deviated. , Quantity, and other detailed configurations can be modified by those skilled in the art. Therefore, the description that limits the shapes and the like disclosed above is merely an example for facilitating the understanding of the present invention, and does not limit the present invention. The description by the name of the member excluding some or all of the restrictions is included in the present invention.

1 Range hood 2 Elevating member 10 Cabinet 11 Heating cooker 12 Top plate 13 Discharge port 14 Indentation hole 20 Support part 21 Optical surface of sensor 22 Self-inspection part 23 Coupling part 24 Sensor 30 Hood part 31 Suction port 40 Acting part 50 Fan 60 Drive device SF Top surface of top plate

Claims (4)

With a cabinet with a cooker,
A support part that can be raised and lowered in the cabinet
A hood portion that is supported by the support portion and rises when in use to face the top plate of the cabinet, and descends when not in use and is arranged in the vicinity of the top plate.
A sensor that detects an object between the hood and the top plate,
With
The support portion has an optical surface of the sensor at a position near the coupling portion with the hood portion and the hood portion is not in the detection range.
The sensor detects the presence or absence of an object sandwiched between the hood portion and the top plate, and detects the presence or absence of an object .
A range hood having a mechanism for stopping descent when the sensor detects an object . Further equipped with a self-inspection unit that performs self-inspection based on the detection result of the sensor.
The self-inspection unit inspects that the optical surface of the sensor is dirty by continuously detecting the sensor in the space through which the hood unit passes while the sensor is operating in the process of raising the support unit. The range hood according to claim 1. When the support is lowered when not in use and is in the lowest point position, at least a portion of the sensor is below the top surface of the top plate.
The self-inspection unit is characterized in that when the support unit starts to rise from the position of the lowest point, the sensor detects the top plate to inspect that the sensor is functioning normally. The range hood according to claim 2. Further equipped with a self-inspection unit that performs self-inspection based on the detection result of the sensor.
When the support is lowered when not in use and is in the lowest point position, at least a portion of the optical surface of the sensor is below the top surface of the top plate.
The self-inspection unit is characterized in that when the support unit starts to rise from the position of the lowest point, the sensor detects the top plate to inspect that the sensor is functioning normally. The range hood according to claim 1.