JP6949591B2 - Range food - Google Patents

Description

The present invention relates to a range hood, and more particularly to a range hood including a blower and a control unit for controlling the blower.

For example, when cooking using a cooking device such as a gas stove or a gas grill, the ventilation device used to exhaust the cooking exhaust to the outside includes a blower and a control unit for controlling the blower. There is a range hood.

As such a range hood, Patent Document 1 includes a gas sensor that detects the concentration of a specific type of gas, and the control unit obtains the gas concentration obtained by the gas sensor and the gas concentration thereof. A range hood that updates the set air volume based on the set air volume at the time is disclosed.

That is, the range hood disclosed in Patent Document 1 newly sets an appropriate set air volume corresponding to various cases (that is, updates the set air volume) based on the gas concentration and the set air volume obtained from the gas sensor. ) Is configured to be able to.

Then, in the range hood of Patent Document 1, for example, when cooking is performed by a gas stove and the gas concentration to be detected reaches a predetermined value (for example, the first threshold value), the blower of the range hood is stopped. However, the blower of the range hood is driven according to the detection value (value of change rate K) of the gas sensor.

As a result, when cooking with a cooking device such as a gas stove, if the gas concentration exceeds the first threshold value, the blower of the range hood can be automatically driven. Therefore, the cooking device such as a gas stove It is meaningful to be able to maintain a good environment in the area where the stove is installed, usually in the kitchen.

Further, the range hood disclosed in Patent Document 1 is configured so that the blower of the range hood can be automatically stopped when the gas concentration becomes equal to or less than the second threshold value. Therefore, it is possible to save energy by not operating the blower wastefully.

That is, the range hood described in Patent Document 1 does not require the gas stove and the range hood to communicate with each other by a method such as wired communication or wireless communication, and the gas stove and the range hood are the same manufacturer. It has an excellent feature that the gas stove and the range hood can be interlocked with each other and the range hood can be automatically ventilated without the need for a specific model.

Japanese Unexamined Patent Publication No. 2016-173193

However, the range hood of Patent Document 1 includes the following problems.

The range hood is often installed and used directly above a gas cooking device such as a gas stove. Therefore, in the range hood of Patent Document 1, the gas sensor is strongly affected by the flow of the combustion exhaust gas by installing the range hood directly above the gas cooking device such as a gas stove. As a result, oil smoke and water vapor generated during cooking directly lick the surface of the gas sensor, and oil smoke containing dust adheres to the detection part of the gas sensor, making it impossible to accurately detect the concentration of a predetermined gas. In some cases.

On the other hand, when the gas sensor is arranged in a place where it is difficult to receive the flow of the combustion exhaust gas, the gas sensor is kept away from the flow of the combustion exhaust gas, and the combustion exhaust gas reaching the gas sensor is sucked together with the combustion exhaust gas. Since it may be diluted by air, the concentration of a predetermined gas in the combustion exhaust gas cannot be detected accurately, and it becomes difficult to accurately link a gas cooking device such as a gas stove with a range hood.

The present invention solves the above-mentioned problems of the range hood, suppresses the adhesion of oil smoke or the like to the detection unit of the gas sensor, and accurately links the gas cooking device such as a gas stove with the range hood for automatic ventilation. The purpose is to provide a range hood that can be operated.

In order to achieve the above object, the range hood of the present invention is
A casing that has a ventilation passage inside and is installed on the rear wall surface, which is the wall surface on the back side when viewed from the front.
A hood portion having a suction port at the upstream end of the ventilation passage and configured to collect gas rising from below and suck it from the suction port.
The blower provided in the ventilation path and
A control unit that controls the blower is provided.
The set air volume is configured so that it can be set continuously or stepwise from the air volume 0 to the appropriately set upper limit air volume, and
A range hood configured such that the control unit controls the blower so that the air volume of the gas blown by the blower becomes the set air volume.
It is equipped with a plurality of gas sensors that detect the concentration of a specific type of gas contained in the gas passing through the ventilation passage.
Wherein each of the plurality of gas sensors, with respect to flue gas state, and are not having a predetermined sensitivity
The hood portion is provided with a wiring passage located outside the ventilation passage and for passing the wiring connected to the control unit.
The ventilation passage and the wiring passage are separated by a partition wall, and the inner peripheral surface of the partition wall constitutes the inner peripheral surface of the ventilation passage.
The partition wall includes a through hole arranged on the front side and a through hole arranged on the rear side.
At least one of the plurality of gas sensors serves as a front gas sensor at a position where the combustion exhaust gas diluted with fresh air supplied from the front side of the hood portion by ventilation reaches the front side of the hood portion. It is arranged at a position retired from the inner peripheral surface of the ventilation passage to the wiring passage side by a predetermined dimension so as to face the ventilation passage from the through hole formed on the front side of the partition wall.
At least one of the plurality of gas sensors serves as a rear gas sensor to provide a dense combustion exhaust gas that is less diluted by fresh air supplied from the front side of the hood portion by ventilation on the rear side of the hood portion. It is arranged so as to face the ventilation passage from a through hole formed on the rear side of the partition wall at a position where it can be reached and retired from the inner peripheral surface of the ventilation passage by a predetermined dimension to the wiring passage side. ,
The control unit is characterized in that the set air volume is updated based on the gas concentration obtained from the front gas sensor and the rear gas sensor and the set air volume.

In the range hood of the present invention, it is preferable that the front gas sensor and the rear gas sensor have a predetermined sensitivity to hydrogen.

Further, during the operation of the blower, the control unit is configured to stop the blower when the gas concentration detected by the rear gas sensor is equal to or less than a predetermined stop gas concentration. Is preferable.

Further, it is preferable that the set air volume is updated based on the weighted values of the gas concentrations obtained by the front gas sensor and the rear gas sensor and the set air volume. ..

The range hood of the present invention is configured as described above, and it is possible to prevent oil smoke and the like from adhering to the detection portion of the gas sensor to reduce the detection sensitivity, and when the range hood is stopped, the range hood can be suppressed. By detecting the combustion exhaust gas generated from a gas cooking device such as a gas stove during cooking with a rear gas sensor, it becomes possible to accurately start the range hood.

That is, according to the present invention, since the front gas sensor and the rear gas sensor are arranged at positions retracted by a predetermined dimension from the inner peripheral surface of the ventilation path, it is possible to prevent the gas sensor from being strongly affected by the flow of combustion exhaust gas. As a result, it becomes possible to suppress a decrease in sensitivity due to oil smoke or the like adhering to the detection part of the gas sensor, and the rear gas sensor is arranged in a recessed position, and fresh air supplied from the front by ventilation. Since it comes into contact with the dense combustion exhaust gas having a small dilution ratio due to the above, the generation of the combustion exhaust gas can be reliably detected and the range hood can be started accurately.

Further, on the front side gas sensor, a flue gas from such stove, ventilation by will be reaching the combustion exhaust gas is diluted with fresh air supplied from the front side, resulting in ventilation and the amount of combustion exhaust gas An output corresponding to the gas concentration that depends on both of the above is obtained.

Therefore, by controlling the set air volume by the output of the front gas sensor, it is possible to suppress the occurrence of excess or deficiency of ventilation, and it is possible to perform appropriate ventilation.

That is, according to the present invention, it is possible to suppress the gas sensor from being strongly affected by the flow of combustion exhaust gas, to suppress a decrease in sensitivity due to oil smoke or the like adhering to the detection portion of the gas sensor, and to suppress a decrease in sensitivity of the gas sensor on the rear side. As a result, it is possible to realize a range hood capable of reliably detecting combustion exhaust gas having a small dilution ratio by fresh air, accurately linking the gas stove and the range hood, and accurately performing automatic ventilation operation.

Further, when the front gas sensor and the rear gas sensor having a predetermined sensitivity to hydrogen are used, it becomes possible to more accurately perform the automatic ventilation operation according to the concentration of the combustion exhaust gas.

Further, when the control unit is configured to stop the blower when the gas concentration detected by the rear gas sensor is equal to or lower than the predetermined stop gas concentration during the operation of the blower, a gas such as a gas stove is used. When the gas cooking equipment is extinguished when the cooking equipment is used, the combustion exhaust gas (gas not diluted with fresh air) of the gas cooking equipment does not reach the rear gas sensor in a short time, and the rear side gas sensor is not reached. Since the gas concentration (or the output corresponding to the gas concentration) detected by the side gas sensor tends to decrease significantly, it is possible to quickly and accurately detect the extinguishing of the gas stove and stop the blower. It is possible to obtain a range hood capable of performing automatic ventilation operation more accurately.

Further, by configuring the set air volume to be updated based on the weighted values of the gas concentrations obtained by the front gas sensor and the rear gas sensor and the set air volume, the automatic ventilation operation can be performed more appropriately. It is possible to realize a range hood that can be made to perform.

It is a main part side sectional view of the range hood which concerns on embodiment of this invention. It is a right sectional view of the main part of the range hood which concerns on embodiment of this invention. It is a schematic block diagram of the gas sensor used in the range hood which concerns on embodiment of this invention. It is a block diagram of the control part provided in the range hood which concerns on embodiment of this invention. It is a figure which shows the reaction of the gas sensor when the gas stove (gas cooking equipment) installed below the range hood which concerns on embodiment of this invention is burned.

Hereinafter, embodiments of the present invention will be shown, and the features thereof will be described in more detail.

The range hood 1 according to the present embodiment is used together with gas cooking equipment such as a gas stove and a gas grill, and as shown in FIGS. 1 and 2, it is formed on a rear wall surface W which is a wall surface on the back side when viewed from the front. It includes a casing 10 to be installed, a blower 40, a control unit (not shown), a front gas sensor 5 (5a), and a rear gas sensor 5 (5b). Specifically, the rear wall surface W described above is, for example, a wall surface of a kitchen.
In the following embodiment, the range hood 1 used together with the gas stove, which is a dregs cooking device, will be described.

The casing 10 has a ventilation passage 4 inside, and also has a hood portion 3. The hood portion 3 has a suction port 41 which is an upstream end of the ventilation passage 4, and functions to collect gas rising from below and suck the gas from the suction port 41. The hood portion 3 is arranged on the lower side of the casing main body 2 included in the casing 10.

Further, the hood portion 3 has a flat rectangular parallelepiped shape (rectangular box shape) that is short in the vertical direction, and the opening on the lower surface side functions as a suction port 41, and a ventilation passage 4 is formed inside. It is a body and is connected to the casing main body 2 at the top plate 31.

The ventilation passage 4 is formed from the hood portion 3 to the casing main body 2, and the main portion of the space in the casing 10 constitutes the ventilation passage 4.
In the range hood 1 according to the present embodiment, the casing 10 is configured to include the casing main body 2 and the hood portion 3, but the configuration is not particularly limited to such a configuration.

A partition wall 32 is provided in the hood portion 3, and the ventilation passage 4 and the wiring passage 33 are separated by the partition wall 32.
The inner peripheral surface 32a of the partition wall 32 constitutes the inner peripheral surface 4a of the ventilation passage 4.

An operation unit 11 (FIG. 1) for manually setting ON / OFF of the blower device 40, a set air volume, and the like is provided on the front end surface of the hood unit 3. Further, the hood portion 3 is provided with a lighting 12 (FIG. 2). The wiring (not shown) connected to the operation unit 11 and the lighting 12 is configured to be arranged in the wiring passage 33.

In the region located in the casing main body 2 of the ventilation passage 4, for example, a blower 40 equipped with a sirocco fan or the like is provided. A duct 42 is provided on the downstream side of the blower device 40 in the ventilation passage 4 located in the casing main body 2, and the downstream end (upper end in FIGS. 1 and 2) of the duct 42 is the ventilation passage 4. It is a discharge port 43.

Further, an extension exhaust duct (not shown) is connected to the discharge port 43 so that the gas is discharged to the outside (outdoor).

Further, the range hood 1 according to the present embodiment includes a control unit 100 (see FIG. 4).

As shown in FIG. 4, the control unit 100 is a rear side gas sensor detection circuit 105a which is a detection circuit for the microcomputer 100a and the front side gas sensor 5 (5a), and a rear side which is a detection circuit for the rear side gas sensor 5 (5b). It is provided with a side gas sensor detection circuit 105b, a temperature sensor detection circuit 106, an operation switch board 107, a motor control circuit 108, a fan motor 109 for driving a fan included in the blower 40, and the like, according to a predetermined control program. It is configured to perform various controls. As the control unit 100 and peripheral devices associated therewith, various known devices can be appropriately used, and the configuration thereof is not particularly limited.

As the blower 40, for example, one provided with a fan such as a sirocco fan and a driving means such as a motor for driving the fan is preferably used, but various known ones can be appropriately used and are particularly limited. It is not something that is done. The amount of air blown by the blower device 40 is controlled by the control unit 100, and specifically, a driving means such as a motor is controlled. The amount of air blown per unit time may be directly detected by a known detection means. Further, it may be estimated from the rotation speed of the fan, or may be estimated from one or both of the current and the voltage of the driving means.

The detected or estimated air flow amount data is transmitted to the control unit 100. The air flow amount data may be analog data such as voltage and current applied to the control unit 100 from the detecting means, or may be digital data.

The control unit 100 obtains the amount of air blown from the transmitted amount of air blown data. For example, when what is transmitted is so-called raw data of the amount of air blown, the control unit 100 obtains the amount of air blown by a calculation function having one function based on the raw data. However, various specific processes in control can be considered and are not particularly limited.

The control unit 100 performs feedback control based on the air volume data in order to match the actually detected air volume with the set air volume (hereinafter referred to as the set air volume). The control of the amount of air blown by the control unit 100 is not limited to the feedback control, and may be controlled by a method such as feedforward control. That is, the method for controlling the air volume may be such that the actual air volume is controlled so as to be within a predetermined error range with respect to the set air volume.

The front gas sensor 5 (5a) and the rear gas sensor 5 (5b) detect the concentration of a specific type of gas in the atmosphere (hereinafter referred to as gas concentration), and in the present embodiment, the gas sensor 5 is a gas sensor 5. It includes two (plurality) gas sensors, the front gas sensor 5 (5a) and the rear gas sensor 5 (5b) described above.
The range hood 1 of the present invention may be provided with at least two gas sensors, the front gas sensor 5 (5a) and the rear gas sensor 5 (5b), and is not limited to two. ..

As shown in FIG. 1, the front gas sensor 5 (5a) is located on the front side of the hood portion 3 and is retired from the inner peripheral surface 4a of the ventilation passage 4 by a predetermined dimension (5 mm in the present embodiment). It is arranged at the position so as to face the ventilation passage 4. Specifically, it is arranged so as to face the ventilation passage 4 from the through hole 132a for the front gas sensor 5 (5a) provided in the partition wall 32 constituting the inner peripheral surface 4a of the ventilation passage 4.

Further, the rear gas sensor 5 (5b) is a position on the rear side of the hood portion 3 (a position close to the rear wall surface W), and has a predetermined dimension from the inner peripheral surface 4a of the ventilation passage 4 (5 mm in the present embodiment). It is arranged so as to face the ventilation passage 4 at the position where it is retired. Specifically, the through holes 132b for the rear gas sensor 5 (5b) provided in the partition wall 32 constituting the inner peripheral surface 4a of the ventilation passage 4 are arranged as desired in the ventilation passage 4.

Although the rear gas sensor 5 (5b) is shown in FIG. 2, the front gas sensor 5a (FIG. 1) is not shown.

FIG. 3 shows an equivalent circuit of the gas sensor 5 (5a, 5b) used in the range hood 1 according to the present embodiment.

The gas sensor 5 (5a, 5b) used in the range hood 1 of the present embodiment is a semiconductor gas sensor, and has a detection unit 51 having _{a resistor RS and a resistor RL} as shown in FIG. a resistor 52 connected to the detection portion 51 in series, applying unit for applying a predetermined voltage V _C (V) across the sensor 51 and the resistor 52 are connected in series (not shown), the detection It includes a heating unit 53 for maintaining the unit 51 at a predetermined temperature, and a measuring unit 55 for measuring _{the voltage V O (V) at both ends of the resistance unit 52.}

Furthermore, the heating unit 53 has a resistance R _H, the predetermined heat is generated in the resistance R _H by a predetermined voltage V _H (V) is applied to both ends of the resistor R _H. This makes it easier to maintain the temperature of the detection unit 51 at a predetermined temperature. For convenience, the resistance value of the _{resistor R S is represented by the same code as R S} (Ω), and the resistor R _L is also _{represented by the same code as R L} (Ω).
The resistance R _S of the detection unit 51 is a variable resistance whose resistance value R _{S changes depending on the gas concentration.}

Here, in examining the range hood 1 of the present embodiment including the two gas sensors of the front side gas sensor 5 (5a) and the rear side gas sensor 5 (5b) described above, first, a range hood having only one gas sensor is examined. Consider the case of.
When the range hood has only one gas sensor 5, the resistance value _RS is represented by the following equation (1).
_{R S = {(V C -V} O) / V 0} × R L ...... (1)

On the other hand, since the range hood 1 of the present embodiment includes two gas sensors, a front gas sensor 5 (5a) and a rear gas sensor 5 (5b), each of the gas sensors 5 (5a, 5b) is provided. _{From the voltage V O} ( _VOa , V _Ob ) measured by the measuring unit 55 of _{the above, the apparent resistance value R S} obtained by combining the two gas sensors 5 (5a, 5b) is obtained from the above equation (1). I have to. This point will be described later.
_{The smaller the value of RS} obtained by the equation (1), the higher the gas concentration.

The front gas sensor 5 (5a) and the rear gas sensor 5 (5b) used in the range hood 1 of the present embodiment have a gas concentration (specification in the atmosphere with respect to the entire atmosphere) for a gas having a specific flammability. _{The resistance value R S} of the detection unit 51 changes according to the gas ratio), _{and the voltage V O} ( _{VO a} , V _Ob ) measured by the measurement unit 55 changes. The front gas sensor 5 (5a) and the rear gas sensor 5 (5b) used in the range hood 1 of the present embodiment have a predetermined sensitivity to the combustion exhaust gas.

However, the specific gas for detecting the combustion exhaust gas includes, for example, hydrogen, ethanol, isobutane, carbon monoxide, and the like, but is not limited thereto.

The front gas sensor 5 (5a) used in the range hood 1 of the present embodiment is a type 1 gas sensor shown in Table 1, and is flammable contained in city gas or LP gas such as hydrogen and isobutane. It has a predetermined sensitivity to gas.

The rear gas sensor 5 (5b) used in the range hood 1 of the present embodiment is also a type 1 gas sensor shown in Table 1, and is flammable contained in city gas and LP gas such as hydrogen and isobutane. It has a predetermined sensitivity to gas.

As described above, the two gas sensors used in the range hood 1 according to the present embodiment, that is, the front gas sensor 5 (5a) and the rear gas sensor 5 (5b) are gas sensors having the same characteristics. ..

In the range hood 1 according to the present embodiment, a semiconductor gas sensor is used as the gas sensor 5, but the gas sensor that can be used in the present invention is not limited to the semiconductor gas sensor, and various gas sensors can be appropriately used. It is possible to use it.

The detected gas concentration data is transmitted to the control unit 100. In the present embodiment, the concentration data transmitted to the control unit 100 is a voltage (analog data) applied from the measurement unit 55 of the gas sensor 5 to the control unit 100, and the control unit 100 is one from this voltage. The gas concentration is obtained by the calculation function that has as a function. The data transmitted to the control unit 100 may be digital data converted based on voltage instead of analog data, and there are no particular restrictions on the type. In any case, the control unit 100 can finally obtain the gas concentration from the transmitted concentration data.

In the range hood 1 according to the present embodiment, the control unit 100 newly sets the set air volume based on the gas concentration and the set air volume obtained from the front gas sensor 5 (5a) and the rear gas sensor 5 (5b). That is, it is configured to update the set air volume.
As for the set air volume, a predetermined range is appropriately set by the range hood 1, and the lower ^{limit is always OFF (stopped state), that is, the air volume is 0 (m 3} / h), and the upper limit is appropriately set.

The set air volume may be configured so that it can be set continuously between the upper limit and the lower limit, or it may be configured so that it can be set stepwise. Further, it may be configured so that a part can be set continuously and the rest can be set stepwise.

Further, the set air volume is updated at predetermined intervals, but it is preferable that the set air volume is updated at the shortest possible intervals (ultimately continuously). However, there are no particular restrictions on the mode of updating, and for example, the conditions for updating may be separately defined so that the updating may be performed when the conditions are satisfied.

Next, the update of the set air volume in the range hood 1 of the present embodiment including the two gas sensors of the front side gas sensor 5 (5a) and the rear side gas sensor 5 (5b) will be described in more detail.

The concentration data for the specific gas detected by the front gas sensor 5 (5a) and the rear gas sensor 5 (5b) is the measurement unit of each gas sensor 5 (5a, 5b) as described above in the present embodiment. The voltage V _O (V _Oa , V _Ob ) measured at 55.

Specifically, the output voltage V _O of the apparent (equivalent to V _O in FIG. 3) the voltage V _Oa measured by the front-side gas sensor 5 measuring unit 55 of (5a), the rear side gas sensor 5 (5b) from each of the measurement unit 55 at the measured the voltage V _Ob (corresponding to V _O in FIG. 3), the following equation (2):
V _O = V _Oa + V _Ob …… (2)
Ask more.

Then, the apparent resistance value R _S is calculated by the above equation (1):
_{R S = {(V C -V} O) / V O} × R L ...... (1)
To be calculated by.
_{The smaller the value of RS} obtained by the equation (1), the higher the gas concentration.

The voltages V _Oa and V _Ob become predetermined values when the gas concentration is 0, and the resistance value R _{S at} this time becomes a predetermined value. Then, this value is set as the reference resistance value R _SO . The reference resistance value R _SO and other values (resistance value R _S , resistance value R _L, etc.) differ depending on the front gas sensor 5 (5a) and the rear gas sensor 5 (5b), but the range according to the present embodiment. In the hood 1, values corresponding to each gas sensor 5 (5a, 5b) are stored in a storage device such as a ROM (Read Only Memory) attached to the control unit 100.

Further, in the present embodiment, the rate of change K (%) is defined as an index indicating the apparent gas concentration detected by the front gas sensor 5 (5a) and the rear gas sensor 5 (5b). The rate of change K is expressed by the following equation (3).
K = {(R _{SO- RS} ) / R _SO } x 100 …… (3)
The rate of change K obtained by the formula (3) is a value from 0 to 100, and the larger the rate of change K, the higher the detected gas concentration.

Rate of change K is a one-to-one correspondence with the resistance value R _S apparent, one-to-one with the gas concentration of the apparent resistance R _S of the apparent rear side gas sensor 5 and the front side gas sensor 5 (5a) to (5b) is detected The rate of change K has a one-to-one correspondence with the apparent gas concentration detected by the gas sensor 5 (5a, 5b), and changes as the apparent gas concentration detected by the gas sensor 5 (5a, 5b) increases. The rate K increases.

Therefore, the control described below is based on the rate of change K, and although the apparent gas concentration detected by the front gas sensor 5 (5a) and the rear gas sensor 5 (5b) does not appear directly, it is practical. It can be said that the control is performed based on the gas concentration detected by the front gas sensor 5 (5a) and the rear gas sensor 5 (5b).

Table 1 shows the types 1 gas sensors used as the front side gas sensor 5 (5a) and the rear side gas sensor 5 (5b), and the gases to be detected by the type 2 and type 3 gas sensors which are reference gas sensors. The relationship between the type, the concentration (ppm) of each gas in each gas sensor, and the apparent resistance value R _S and the reference resistance value R _SO (that is, R _S / R _SO ) is illustrated.

_{The values shown in Table 1 are the output voltages V Oa} and V _Ob obtained for each of the front gas sensor 5 (5a) and the rear gas sensor 5 (5b), and for each of these output voltages V _Oa and V _Ob . The above equation (1):
_{R S = {(V C -V} O) / V 0} × R L ...... (1)
_{R S} / R _SO obtained individually by _{, in other words, R Sa} / R _SOa obtained from _{V Oa} for the front gas sensor 5 (5a), _{and V Ob} for the rear gas sensor 5 (5b). R _Sb / R _SOb is shown.

The blanks in Table 1 indicate that the gas sensor of the corresponding type is not a detection target because the sensitivity to the corresponding gas is low.

In the range hood 1 according to the present embodiment, the front gas sensor 5 (5a) has the characteristics shown in the type 1 column, and the rear gas sensor 5 (5b) also has the characteristics shown in the type 1 column. However, the present invention is not limited to this, and gas sensors exhibiting other characteristics may be used as the front side gas sensor 5 (5a) and the rear side gas sensor 5 (5b).

As described above, the range hood 1 according to the present embodiment is configured so that the set air volume can be updated. Specifically, the gas concentration (corresponding to the rate of change K) and the setting at a certain point in time. From the air volume, the control unit 100 is configured to update the set air volume used thereafter. It goes without saying that the above-mentioned time point is a time point before the time when the set air volume is updated, but it is preferable that it is immediately before the time when the set air volume is updated.

When updating the set air volume, it is preferable that the higher the gas concentration is, the larger the set air volume after the update tends to be with respect to the predetermined set air volume before the update. That is, although not particularly shown, if the gas concentration is taken on the X-axis and the set air volume after the update is taken on the Y-axis with respect to the predetermined set air volume before the update, the relationship line between the gas concentration and the set air volume after the update is taken. However, it is preferable that the so-called upward slope is obtained.

The mode in which the relation line rises to the right may be a mode in which the Y value continuously increases (monotonically increases) as the X value increases, and there is a horizontal portion in a part and the other portion. It may be a continuously increasing mode, or it may be a stepwise increasing mode. It should be noted that the present invention does not exclude a mode in which, for some reason, there is a step of reducing the Y value as a whole as the X value increases.

^{The higher the gas concentration, the larger the air volume (m 3} / h) required to promptly discharge the air containing the detected gas. Therefore, it is preferable to increase the set air volume after the update as described above.

Further, when updating the set air volume, it is preferable that the larger the set air volume before the update is, the larger the set air volume after the update tends to be with respect to the predetermined gas concentration. That is, although not particularly shown, if the set air volume before the update is taken on the X axis and the set air volume after the update is taken on the Y axis for a predetermined gas concentration, the set air volume before the update minus the set air volume after the update. It is preferable that the relational line rises to the right.

Further, in the mode in which the above-mentioned relationship line rises to the right, the Y value continuously increases (monotonically increases) as the X value increases, as in the case of the above-mentioned gas concentration-updated set air volume relationship line. ), It may be a mode in which a horizontal portion is partially provided and the other portion is continuously increased, or it may be a mode in which the portion is gradually increased. It should be noted that the present invention does not exclude a mode in which, for some reason, there is a step of reducing the Y value as a whole as the X value increases.

Normally, if the set air volume before the update is large regardless of the gas concentration, the desired set air volume after the update will be large. Therefore, as described above, the larger the set air volume before the update, the larger the set air volume after the update. It is preferable to increase.

In the range hood 1 according to the present embodiment, the set air volume is updated as shown in Table 2, for example.

That is, from the rate of change K (which increases as the gas concentration increases) shown in the upper part of Table 2 and the set air volume before the update (m ³ / h) shown in the left column, the corresponding set air volume after the update (m ^3). / H) is set and updated. In the present embodiment, there are seven stages of change in the set air volume (stage of the set air volume after the update) of 0 (OFF), 150, 200, 250, 300, 400, and 500 (m ³ / h).

In the range hood 1 according to the present embodiment, as shown in Table 2, the larger the rate of change K with respect to each set air volume before the update, the larger the set air volume after the update tends to be. I understand.

In particular, this tendency occurs even when the set air volume before the update is 0. In this case, when the gas concentration exceeds the first threshold value, the set air volume after the update exceeds 0.

<About interlocking with a gas stove>
FIG. 5 shows the reaction between the front gas sensor 5 (5a) and the rear gas sensor 5 (5b) when the gas stove is burned and hot water is boiled. In FIG. 5, the state values of R _S / R _O is small, represents a high gas concentration condition. Note that _RO is the resistance (reference resistance) of the detection unit 51 when the concentration of the target gas is 0. Further, the resistance R _S of the detection unit 51 becomes smaller as the gas concentration increases. Therefore, a _{state in which R S} / _RO is small indicates a state in which the gas concentration is high.

In FIG. 5, the rear side gas sensor 5 (5b) shows a quick reaction after the start of combustion of the gas stove (burner), while the front side gas sensor 5 (5a) shows a slow reaction. This is because the mixed gas of the combustion exhaust gas and the fresh air reaches the front gas sensor 5 (5a), whereas the rear gas sensor 5 (5b) is arranged at a recessed position due to the fresh air. It is probable that the rear gas sensor 5 (5b) responded more quickly than the front gas sensor 5 (5a) because the highly concentrated combustion exhaust gas with a small degree of dilution arrives.
Further, it can be seen that after the combustion of the gas stove (burner) is stopped, the output of the rear gas sensor 5 (5b), which has received the high-concentration combustion exhaust gas with a small degree of dilution by fresh air, tends to decrease significantly. ..

In the range hood 1 according to the present embodiment, for example, when cooking with a gas stove, the first gas concentration (gas concentration) to be detected reaches a predetermined value (this is set as the first threshold value). Threshold is set.

Then, even when the blower 40 of the range hood 1 is stopped, when the rate of change K exceeds the value of the rate of change K corresponding to the gas concentration of the first threshold value (10 in this embodiment), the range hood 1 is used. The blower 40 of 1 is configured to start driving. As a result, when cooking is performed with a gas stove and the gas concentration exceeds the first threshold value, the blower 40 of the range hood 1 can be automatically driven.

In this way, when automatically driving the blower 40 of the range hood 1, the gas stove and the range hood 1 do not communicate with each other by wire or wirelessly, and the gas stove is the same manufacturer and a predetermined model as the range hood 1. It is possible to link the range hood 1 and the gas stove (that is, to automatically drive the blower 40 of the range hood 1) without the need to be, which is meaningful.

Further, even when the set air volume before the update is larger than 0 and smaller than the predetermined value, the set air volume after the update is set to 0 when the gas concentration is equal to or less than the second threshold value. In the present embodiment, when the set air volume is gradual, the set air volume before updating is larger than 0, and the minimum set air volume is 150 (m ³ / h), the rate of change K is the second threshold value. When it is 5 or less, the set air volume after the update is set to 0 (see Table 2).

For example, when cooking with a gas stove, a particularly large air volume is not required, but when the range hood 1 is driven with a set air volume larger than 0 and smaller than a predetermined value in order to discharge the generated combustion exhaust gas, the gas stove When the cooking is completed, the combustion exhaust gas is no longer generated, and the driving of the range hood 1 becomes unnecessary.

Therefore, even when the set air volume before the update is a predetermined value larger than 0 (150 (m ³ / h) in the present embodiment), the rate of change K corresponds to the gas concentration of the second threshold value. When the rate of change K is equal to or less than the value (5 in this embodiment), the driving of the blower 40 of the range hood 1 is stopped.

As a result, when cooking with the gas stove is completed, the gas concentration becomes equal to or less than the second threshold value, and the blower 40 of the range hood 1 can be automatically stopped.

In this way, when the blower 40 of the range hood 1 is automatically stopped, the gas stove and the range hood 1 are not communicated by wire or wirelessly, and the gas stove is the same manufacturer and a predetermined model as the range hood 1. It is also possible to link the range hood 1 and the gas stove (that is, automatically stop the blower 40 of the range hood 1) without the need for it, which is meaningful.

Further, in the case of the range hood 1 according to the present embodiment, since both the front gas sensor 5 (5a) and the rear gas sensor 5 (5b) have a predetermined sensitivity to hydrogen, the gas stove It is possible to realize a range hood capable of performing automatic ventilation operation according to the concentration of a specific gas in the combustion exhaust gas generated at the time of use.

Further, in the present embodiment, when the range hood 1 is stopped, the range hood 1 can be accurately started by detecting the combustion gas generated from the gas stove during cooking by the rear gas sensor 5 (5b).

Further, on the front side gas sensor 5 (5a), a flue gas from such stove, ventilation by will be reaching the combustion exhaust gas is diluted with fresh air supplied from the front side, resulting in ventilation and It is possible to obtain an output corresponding to the gas concentration that depends on both the amount of flue gas and the amount of flue gas. Therefore, by controlling the set air volume by the output of the front gas sensor 5 (5a), it is possible to suppress the occurrence of excess or deficiency of ventilation, and it is possible to perform appropriate ventilation.

That is, in the range hood 1 of the present embodiment, the front gas sensor 5 (5a) and the rear gas sensor 5 (5b) are provided by retreating from the ventilation passage 4 by a predetermined dimension, so that the gas sensor 5 (5a) is provided. 5b) can be suppressed from being strongly affected by the flow of combustion exhaust gas, and the decrease in sensitivity due to oil smoke or the like adhering to the detection portion of the gas sensor 5 (5a, 5b) can be suppressed, and the rear gas sensor can be suppressed. 5 (5b) makes it possible to reliably detect the combustion exhaust gas having a small dilution ratio by fresh air, accurately link the gas controller and the range hood, and reliably perform the automatic ventilation operation.

In the present embodiment, the apparent output voltage _VO as described above is calculated by the above equation (2):
V _O = V _Oa + V _Ob …… (2)
To be calculated by.
After that, the apparent resistance value _RS is calculated by the above equation (1):
_{R S = {(V C -V} O) / V O} × R L ...... (1)
To be calculated by.
Then, the rate of change K (%) is defined as an index indicating the apparent gas concentration, and the rate of change K is expressed by the above-mentioned equation (3) :.
K = {(R _{SO- RS} ) / R _SO } x 100 …… (3)
I try to ask for it.

On the other hand, _{the coefficients ka and kb for weighting the output voltage V Oa of} the front gas sensor 5 (5a) and the output voltage V _Ob of the rear gas sensor 5 (5b) are set respectively, and the apparent output voltage V _O , The following equation (4):
V _O = ka ・ V _Oa ＋ kb ・ V _Ob …… (4)
Further, the apparent resistance value _RS is calculated by the above equation (1):
_{R S = {(V C -V} O) / V O} × R L ...... (1)
After that, the rate of change K (%) is defined as an index showing the apparent gas concentration, and the rate of change K is calculated by the above formula (3) :.
K = {(R _{SO- RS} ) / R _SO } x 100 …… (3)
That is, the set air volume is updated based on the weighted values and the set air volume for each of the gas concentrations obtained from the front gas sensor 5 (5a) and the rear gas sensor 5 (5b). The coefficients ka and kb for weighting are set so that ka <kb, respectively, and the output of the rear gas sensor 5 (5b) is mainly used during the operation of the blower device 40. As a result, the blower 40 may be configured to stop.

With such a configuration, it is possible to provide a range hood 1 capable of more appropriately performing automatic ventilation operation.

Further, when the gas concentration detected by the rear gas sensor 5 (5b) is equal to or less than the predetermined stop gas concentration during the operation of the blower device 40 (that is, the output of the rear gas sensor 5 (5b) is predetermined. It is also possible to configure the control unit 100 to stop the blower 40 when the output is equal to or less than the stop output).

With this configuration, as shown in FIG. 5, when the gas stove is extinguished, the output ( _RS / R ₀ ) of the rear gas sensor 5 (5b) tends to decrease significantly, so that the gas stove is accurately extinguished. Since the blower device 40 can be stopped by detecting the above, it is possible to obtain the range hood 1 capable of more accurately performing the automatic ventilation operation.

In the above embodiment, the case of cooking using a gas stove has been described as an example, but the present invention is not limited to the gas stove, and is similarly applied to the case of using other gas cooking equipment such as a gas grill. Is possible.

The present invention is not limited to the above embodiment in other respects as well, and various modifications can be made within the scope of the present invention.

1 Range hood 2 Casing body 3 Hood part 4 Ventilation passage 4a Inner peripheral surface of the ventilation passage 5 Gas sensor 5a Front side gas sensor 5b Rear side gas sensor 10 Casing 11 Operation part 12 Lighting 31 Top plate 32 Partition 32a Partition inner circumference 33 For wiring Passage 40 Blower 41 Suction port 42 Duct 43 Discharge port 51 Detection unit 52 Resistance unit 53 Heating unit 55 Measuring unit 132a Through hole for front gas sensor 132b Through hole for rear gas sensor W Rear wall surface

Claims (4)

A casing that has a ventilation passage inside and is installed on the rear wall surface, which is the wall surface on the back side when viewed from the front.
A hood portion having a suction port at the upstream end of the ventilation passage and configured to collect gas rising from below and suck it from the suction port.
The blower provided in the ventilation path and
A control unit that controls the blower is provided.
The set air volume is configured so that it can be set continuously or stepwise from the air volume 0 to the appropriately set upper limit air volume, and
A range hood configured such that the control unit controls the blower so that the air volume of the gas blown by the blower becomes the set air volume.
It is equipped with a plurality of gas sensors that detect the concentration of a specific type of gas contained in the gas passing through the ventilation passage.
Wherein each of the plurality of gas sensors, with respect to flue gas state, and are not having a predetermined sensitivity
The hood portion is provided with a wiring passage that is located outside the ventilation passage and allows wiring connected to the control unit to pass through, and the ventilation passage and the wiring passage are separated by a partition wall. The inner peripheral surface of the partition wall constitutes the inner peripheral surface of the ventilation passage,
The partition wall includes a through hole arranged on the front side and a through hole arranged on the rear side.
At least one of the plurality of gas sensors serves as a front gas sensor at a position where the combustion exhaust gas diluted with fresh air supplied from the front side of the hood portion by ventilation reaches the front side of the hood portion. It is arranged at a position retired from the inner peripheral surface of the ventilation passage to the wiring passage side by a predetermined dimension so as to face the ventilation passage from the through hole formed on the front side of the partition wall.
At least one of the plurality of gas sensors serves as a rear gas sensor to provide a dense combustion exhaust gas that is less diluted by fresh air supplied from the front side of the hood portion by ventilation on the rear side of the hood portion. It is arranged so as to face the ventilation passage from a through hole formed on the rear side of the partition wall at a position where it can be reached and retired from the inner peripheral surface of the ventilation passage by a predetermined dimension to the wiring passage side. ,
The control unit is a range hood characterized in that the control unit is configured to update the set air volume based on the gas concentration obtained from the front gas sensor and the rear gas sensor and the set air volume. The range hood according to claim 1, wherein the front gas sensor and the rear gas sensor have a predetermined sensitivity to hydrogen. During the operation of the blower, the control unit is configured to stop the blower when the gas concentration detected by the rear gas sensor is equal to or less than a predetermined stop gas concentration. The range hood according to claim 1 or 2. It is characterized in that the set air volume is updated based on the weighted values of the gas concentrations obtained by the front gas sensor and the rear gas sensor and the set air volume. The range hood according to claim 1 or 2.

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