JP6546415B2 - Range food - Google Patents

Description

  BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a range hood, and more particularly, to a range hood including a blowing unit and a control unit that controls the blowing unit.

  Conventionally, a range hood provided with a blower and a controller for controlling the blower is used. The air blowing means is provided in the air passage formed in the casing, and the air blowing means is driven, and the gas rising from below is sucked from the suction port of the air passage and discharged to the outside.

  By the way, the range hood provided with the gas sensor which detects the density | concentration of the specific gas in the gas which ventilates a ventilation path is known (for example, refer patent document 1).

  This range hood can detect the cooking time by the heating cooker and detect the gas concentration generated, and the gas generation amount and the total amount of gas required to discharge all of the gas generation based on the cooking time and the gas concentration. From this total amount, the operation delay time required to discharge the total amount of gas is calculated by the air volume of the air blowing means set manually, and the air blowing means is delay-operated over this operation delay time.

Patent No. 3276028

  In the conventional example shown in Patent Document 1, since the gas is completely discharged with respect to the total amount of the gas to be discharged by the delay operation, the remaining gas is surely discharged to the outside, And, it is possible to minimize the loss of thermal energy due to the discharge of the conditioned air.

  However, since the air volume of the air blowing means set manually is not changed, for example, when the air volume of the air blowing means is set small, the operation delay time required to discharge all the total amount of gas to be discharged is long It was not desirable.

  The present invention has been made in view of these circumstances, and an object thereof is to provide a range hood which eliminates the inconvenience caused by the fact that the set air volume of the air blowing means is not changed.

In order to solve the above-mentioned subject, the invention concerning claim 1 is provided with the casing which has a ventilation way, the ventilation means provided in the ventilation path, and the control part which controls the ventilation means, and the casing is A hood portion having a suction port which is an upstream end of the ventilation path and collecting a gas rising from below and sucking it from the suction port, continuously between 0 as a lower limit and an appropriately set upper limit Alternatively, the set air volume can be set in stages, and the control unit is a range hood that controls the air blowing device such that the air volume of the gas blown by the air blowing device becomes the set air volume, the air passage A gas sensor for detecting the concentration of a specific type of gas in the gas to be blown, the control unit updating the set air volume based on the gas concentration obtained from the gas sensor and the set air volume Are those that, for a given said set air volume before updating, as the said gas concentration is high, so that the set air volume of the updated increases, updates the set air volume, the set air volume before updating Is larger than 0 and smaller than a predetermined value, the set air volume is updated such that the set air volume after update becomes 0 when the gas concentration is equal to or less than a second threshold .

  According to the first aspect of the present invention, it is possible to update the set air volume suitable for various cases based on the gas concentration and the set air volume obtained from the gas sensor.

Furthermore, as the gas concentration increases, since the air volume required for discharge quickly the air containing the detected gas becomes larger, as the gas concentration increases, it is possible to increase the set air volume of the updated .

Furthermore , the gas concentration becomes equal to or less than the second threshold, and the air blowing means of the range hood can be automatically stopped, and the gas stove and the range hood are substantially interlocked without communication by wire or wirelessly. It is possible to

It is a sectional side view of the range hood of one embodiment of the present invention. It is a front view of the range hood of one embodiment of the present invention. It is a schematic block diagram of the gas sensor in the range hood of one embodiment of the present invention.

  Hereinafter, an embodiment of the present invention will be described based on FIGS. 1 to 3.

  As shown to FIG. 1, FIG. 2, the range hood 1 of this invention is equipped with the casing 10, the ventilation means 40, a control part (not shown), and the gas sensor 5. As shown in FIG.

  The casing 10 has an air passage 4 therein and a hood portion 3. The hood portion 3 has a suction port 41 which is an upstream end of the air passage 4, collects gas rising from below and sucks in the gas from the suction port 41. In the present embodiment, the casing 10 includes the casing main body 2, and the hood portion 3 is provided on the lower side of the casing main body 2.

  The hood portion 3 is in the form of a short rectangular box at the top and bottom. The hood portion 3 has a suction port 41 on the lower surface thereof, the air passage 4 is formed inside, and the top plate 31 is connected to the casing main body 2. The air passage 4 is formed from the hood portion 3 to the casing main body 2 and is formed throughout the inside of the casing 10. In addition, although the casing 10 is comprised from the casing main body 2 and the food | hood part 3 in this embodiment, it is not limited in particular to such a structure.

  In the hood portion 3, a partition wall 32 is provided, and the ventilation passage 4 and the wiring passage 33 are partitioned by the partition wall 32.

  The front end surface of the hood 3 is provided with an operation unit 11 for manually setting ON / OFF of the air blowing means 40, a set air volume, and the like. Further, the hood portion 3 is provided with a light 12. Wiring connected to the operation unit 11 and the light 12 is disposed in the wiring passage 33.

  A blower 40 is provided at a portion of the air passage 4 located in the casing main body 2. A duct 42 is provided on the downstream side of the blowing means 40 of the air passage 4 located in the casing main body 2, and the downstream end of the duct 42 is an outlet 43 of the air passage 4.

  Furthermore, although not shown, a hose or the like is connected to the discharge port 43, and the gas is discharged to the outside (outdoor).

  The control unit includes a microcomputer and executes control according to a control program. The control unit and peripheral devices associated with the control unit can be variously known publicly and are not particularly limited.

  As the air blowing means 40, one provided with driving means such as a fan and a motor for driving the fan is suitably used, but various publicly known ones can be suitably used and are not particularly limited. The air flow rate of the air blowing means 40 is controlled by the control unit, and more specifically, the driving means is controlled. The blowing amount (per unit time) may be directly detected by a known detection means, may be estimated from the number of rotations of the fan, or is estimated from one or both of the current and voltage of the drive means. It may be.

  Data of the detected (or estimated) air flow rate is transmitted to the control unit. The air flow rate data may be analog data such as voltage or current applied from the detection means to the control unit, or may be digital data. The control unit obtains the air blowing amount from the transmitted data of the air blowing amount. For example, in the case where what is sent is so-called raw data of the air flow rate, the control unit obtains the air flow rate by an arithmetic function having one function based on the raw data, but various concrete processes in control are considered There is no particular limitation. The control unit performs feedback control based on the data of the air flow rate so as to match the air flow rate actually detected with the set air flow rate (hereinafter referred to as a set air flow rate). The control of the air flow rate by the control unit is not limited to feedback control but may be feed forward control, etc., and is not particularly limited, and control is performed such that the actual air flow rate falls within a predetermined error range with respect to the set air volume. What is necessary is

  The gas sensor 5 detects the concentration of a specific type of gas in the atmosphere (hereinafter referred to as a gas concentration). FIG. 3 shows a circuit equivalent to the gas sensor 5 of the present embodiment.

In the present embodiment, a semiconductor gas sensor, which is a detection unit 51 having a resistance R _S and a resistance unit 52 having a resistance R _L and connected in series to the detection unit 51, and a detection unit 51 connected in series And an application part (not shown) which applies a predetermined voltage V _C (V) to both ends of the resistance part 52, a heating part 53 for maintaining the detection part 51 at a predetermined temperature, and a voltage of both ends of the resistance part 52 And a measuring unit (not shown) for measuring V _O (V). 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 easy to maintain the temperature of the detection unit 51 at a predetermined temperature. For the sake of convenience, the resistance value of the resistor R _S is denoted by R _S (Ω), with the same sign, and the same applies to the resistor R _L.

The resistance R _S of the detection unit 51 is a variable resistance in which the resistance value R _S changes according to the gas concentration. Here, the resistance value R _S is represented by [Equation 1].

In the gas sensor 5 of the present embodiment, the resistance value R _S of the detection unit 51 changes according to the gas concentration (the ratio of the specific gas in the atmosphere to the entire atmosphere) for the specific flammable gas, and the measurement unit The measured voltage V _O changes. Thereby, the gas concentration of the specific flammable gas is detected. Specific gases in this embodiment include, but are not limited to, hydrogen, ethanol, isobutane and carbon monoxide.

  In addition, although the gas sensor 5 is the well-known semiconductor gas sensor 5 mentioned above in this embodiment, it is not specifically limited to this, Various gas sensors 5 can be utilized suitably.

  The detected gas concentration data is transmitted to the control unit. In the present embodiment, the concentration data transmitted to the control unit is a voltage (analog data) applied from the measurement unit of the gas sensor 5 to the control unit, and the control unit performs one function based on the voltage. The gas concentration is obtained by the computing function that it has. In addition, what is transmitted to a control part may not be analog data, but may be digital data converted based on a voltage, and is not particularly limited. In any case, the control unit can finally obtain the gas concentration from the transmitted concentration data.

In the range hood 1 of the present invention, the control unit newly sets the set air volume based on the gas concentration and the set air volume obtained from the gas sensor 5, that is, updates the set air volume. As the set air volume, a predetermined range is appropriately set by the range hood 1. The lower limit is always OFF (stop state), that is, 0 (m ³ / h), and the upper limit is appropriately set. The set air volume may be continuously settable between the upper limit and the lower limit or may be set stepwise, or some of them may be continuous and the rest may be set stepwise. It may be.

  Also, updating of the set air volume is performed at predetermined intervals, and it is preferable to perform updating as much as possible (ultimately continuously) especially, but it is not particularly limited. For example, conditions for updating are separately It may be determined and performed when the condition is satisfied.

  Hereinafter, updating of the set air volume will be described according to the present embodiment.

Density data, in the present embodiment as described above, the voltage V _O to be measured by the measurement portion of the gas sensor 5. The voltage V _O, if the gas concentration of 0 becomes a predetermined value, the resistance value R _S at this time becomes a predetermined value, this is the reference resistance value R _S0. Although the reference resistance value R _S0 and other values (resistance value R _S , resistance value R _L, etc.) differ depending on the gas sensor 5, each gas sensor may be stored in a storage device such as a ROM (Read Only Memory) attached to the control unit. A value corresponding to 5 is stored.

  In the present embodiment, the change rate K (%) is defined as an index indicating the gas concentration. The rate of change K is expressed by [Equation 2].

Rate of change K, the resistance value corresponds with R _S and one-to-one, the resistance value R _S is a one-to-one correspondence with the gas concentration, the rate of change K is a one-to-one correspondence with the gas concentration, the higher the gas concentration becomes high The rate of change K is increased. Therefore, although the control described below is based on the change rate K and the gas concentration does not directly appear, it can be said that the control is performed based on the gas concentration.

[Table 1] shows the types of gas to be detected by three types of gas sensors 5 of types 1 to 3 with different detection targets, and the relationship between the concentration (ppm) of each gas in each type and R _S / R _S0 I will illustrate. In addition, the blank in the table indicates that the corresponding gas is not a detection target in the corresponding type. The gas sensor 5 of the present embodiment is of the type 1, but is not limited to the type 1, the type 2, the type 3, and the like.

  As described above, the range hood 1 of the present invention updates the set air volume, but more specifically, from the gas concentration (corresponding to the change rate K) and the set air volume at a certain point in time, the control unit The set air volume used in the above is updated. It goes without saying that a certain time point is a time point prior to the update time of the set air volume, but it is preferable that it be just before the update time.

  It is preferable that updating of the set air volume tends to increase the set air volume after updating as the gas concentration becomes higher than the predetermined setting air volume before updating. That is, although not shown, when the gas concentration is taken along the X axis and the set air volume after update is taken along the Y axis with respect to a predetermined set air volume before updating, the relation line of gas concentration-set air volume after updating is a so-called It is preferable to be on the right. As the relationship line goes up, the Y value may continuously increase (monotonically increase) as the X value increases, or there may be a horizontal portion in one part and the other part in a continuous increase. It may be increased or gradually increased. Although the Y value generally increases as the X value increases, it is assumed that the reduction in part does not occur for some reasons.

As the gas volume (m ³ / h) required to rapidly discharge the air containing the detected gas increases as the gas concentration increases, it is preferable to increase the set air volume after updating as described above. is there.

  Further, it is preferable that updating of the set air volume tends to increase the set air volume after updating as the setting air volume before updating becomes larger than the predetermined gas concentration. That is, although not shown, when the set air volume before update is taken on the X axis and the set air volume after update is taken on the Y axis for a predetermined gas concentration, the relationship between the set air volume before update and the set air volume after update It is preferred that the line be so-called upswing. Just as with the case of the above-mentioned relationship between the gas concentration and the set air volume after the update, the relationship line is on the right, even if the Y value increases (monotonously increases) as the X value increases. It is good, and there is a horizontal part in one part, the other part may increase continuously, and shall increase in steps. Also, similarly, although the Y value generally increases as the X value increases, it is assumed that the reduction is partially prevented for some convenience.

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

  In the present embodiment, the setting air volume is updated as shown in [Table 2].

That is, from the change rate K shown in the upper part of [Table 2] (that is, corresponding to the gas concentration) and the set air volume before update (m ³ / h) shown in the left column, the corresponding set air volume after update (m ³⁾ Update to / h). In the present embodiment, the set air volume (m ³ / h) has seven steps of 0 (OFF), 150, 200, 250, 300, 400, 500.

  In this embodiment, it is understood from [Table 2] that the set air volume after update tends to increase as the change rate K is larger than the set air volume before update.

  In particular, even when the set air volume before updating is 0, this tendency is present, and in this case, when the gas concentration exceeds the first threshold, the set air volume after updating is a set air volume exceeding 0.

  For example, when cooking with a gas stove is performed, the gas concentration to be detected reaches a predetermined value (which is a first threshold). Therefore, even when the blowing means 40 of the range hood 1 is stopped, if the rate of change K exceeds the value of the rate of change K corresponding to the gas concentration of the first threshold (10 in the present embodiment), the range hood The first air blowing means 40 starts driving. As a result, when the cooking by the gas stove is performed, the gas concentration exceeds the first threshold, and the blower 40 of the range hood 1 can be automatically driven. On this occasion, the gas stove and the range hood 1 are substantially interlocked with each other without communication between the gas stove and the range hood 1 by wire or wireless, and the gas stove does not have to be the same maker or predetermined model as the range hood 1 It becomes possible.

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

  For example, when cooking with a gas stove, although a particularly large air volume is not required, if 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 gas, When the cooking is finished, no gas is generated, and the driving of the range hood 1 becomes unnecessary.

Therefore, when the set air volume before updating is larger than 0 and not more than a predetermined value (150 (m ³ / h) in the present embodiment), the change rate K is the change rate K corresponding to the gas concentration of the second threshold. When the value (5 in the present embodiment) or less, the blower unit 40 of the range hood 1 stops driving. As a result, when the cooking by the gas stove is finished, the gas concentration becomes equal to or less than the second threshold, and the air blowing means 40 of the range hood 1 can be automatically stopped. On this occasion, the gas stove and the range hood 1 are substantially interlocked with each other without communication between the gas stove and the range hood 1 by wire or wireless, and the gas stove does not have to be the same maker or predetermined model as the range hood 1 It becomes possible.

Reference Signs List 1 range hood 10 casing 11 operation unit 12 illumination 2 casing main body 3 hood unit 31 top plate 32 partition wall 33 wiring passage 4 air passage 40 air blowing means 41 suction port 42 duct 43 exhaust port 5 gas sensor 51 detection unit 52 resistance unit 53 heating unit

Claims (1)

A casing having an air passage,
An air blower provided in the air passage;
A control unit that controls the blowing unit;
The casing has a suction port that is an upstream end of the air passage, and includes a hood portion that collects gas rising from below and collects it from the suction port.
The set air volume can be set continuously or stepwise between 0 which is the lower limit and an upper limit which is appropriately set,
The control unit is a range hood that controls the blowing unit such that an air volume of gas blown by the blowing unit becomes the set air volume,
A gas sensor is provided for detecting the concentration of a specific type of gas in the gas blown through the air passage;
The control unit is configured to update the set air volume based on the gas concentration obtained from the gas sensor and the set air volume .
The set air volume is updated such that the set air volume after update increases as the gas concentration increases with respect to the predetermined air volume before update.
If the set air volume before updating is larger than 0 and smaller than a predetermined value, the set air volume is updated such that the set air volume after updating is 0 when the gas concentration is less than or equal to a second threshold. Feature range hood .

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