JP6397533B2 - Range food - Google Patents

Description

  The present invention relates to a range hood that discharges oily smoke generated during cooking to the outdoors.

A range hood is generally equipped with a blower that rotates a fan with a hood and an electric motor. By rotating the fan with the electric motor, oil smoke generated during cooking is collected in the hood and discharged outdoors. Is.
In such a range hood, if the fan is rotated at a high speed with an electric motor, the amount of oily smoke discharged outside is large, and if the fan is rotated at a low speed with an electric motor, the aforementioned amount of discharge is reduced and the electric motor is electrically driven. The power consumption of the motor is large when the fan rotates at a high speed and decreases when the fan rotates at a low speed.

For this reason, when the fan is rotated at high speed by the electric motor when there is little oily smoke generated during cooking, power is wasted.
Then, the range hood disclosed by patent document 1 is proposed.
This range hood has a switch attached to the front of the hood. This switch has a plurality of operation switches, for example, strong switch, medium switch, weak switch, and off switch. When the strong switch is pressed, the electric motor is driven at high speed, the fan rotates at high speed, and the range hood is operated strongly. It becomes.
Similarly, when the middle switch and the weak switch are pressed, the electric motor is driven at a medium speed and is driven at a low speed, and the fan is rotated at a medium speed and a low speed, so that the range hood becomes a medium operation and a weak operation.
When the switch is turned off, the electric motor is stopped, the fan is stopped, and the range hood is stopped.
With such a range hood, it is possible to adjust the discharge amount by changing the rotation speed of the fan according to the amount of oily smoke generated during cooking, so that the power consumption of the electric motor can be reduced.

JP-A-10-132351

  In the above-described range hood, the use of a DC electric motor as an electric motor can reduce power consumption compared to the case of using an AC electric motor. Range hood is required.

Based on the above requirements, the present inventors have studied and experimented on the power consumption of the DC electric motor of the range hood, and found the following.
In the conventional range hood described above, the operation command voltage of the standard value based on the magnitude corresponding to the speed corresponding to the selected operation switch is continuously supplied to the DC electric motor. The power consumption per time is the same when the DC electric motor is rotating, and the power consumption when the DC electric motor is rotating is the power consumption per unit time × the motor rotation time.

Therefore, the inventors of the present invention use a range hood that intermittently reduces the operation command voltage to the DC electric motor that rotates the fan of the blower, thereby reducing the power consumption per unit time of the DC electric motor intermittently. As a result, power consumption could be further reduced.
However, when the operation command voltage to the DC electric motor is controlled as described above, a large wind noise is generated by the fan, which may cause discomfort to people around the range hood.

  In view of the above, the present inventors have further studied and experimented to obtain the range hood of the present invention.

The range hood of the present invention is a range hood provided with a hood 1 and a blower 10 that rotates a fan 12 with a DC electric motor 11, and the operation command voltage of the DC electric motor 11 is set during operation of the range hood. Provided is means for intermittently reducing the operation command voltage from the reference value to the set value in order to operate as the reference value, and the means immediately after the operation command voltage is reduced to the set value. Increase of the operation command voltage is started and increased to the reference value, or after driving for a time of a few seconds shorter than the driving time by the reference value at the set value, the increase to the reference value is intermittently performed. It is a range hood characterized by being performed multiple times.

  In the present invention, the means includes a changeover switch 41 that disconnects the input side 31a and the output side 31b of the voltage circuit 31 that sends an operation command voltage from the motor control device 30 to the DC electric motor 11, and the input side 31a and the output side. A delay circuit 42 provided between the switch 31b and the motor control device 30 enables the changeover switch 41 to be repeatedly turned on and off at predetermined intervals.

  In this way, since the voltage circuit 31 in the normal range hood can be configured to reduce by providing the changeover switch 41 and the delay circuit 42, it can be manufactured using the existing range hood.

  In the present invention, the means may be the microcomputer 32 provided in the motor control device 30 that outputs the operation command voltage to the DC electric motor 11.

  In this way, it is possible to freely set a setting value for decreasing the operation command voltage, a decrease time, and the like.

  In the present invention, the microcomputer 32 can gradually increase the operation command voltage to the DC electric motor 11 gradually from the standard value to the set value and then gradually increase to the standard value.

  In this way, since the rotation of the fan 12 is slowly increased, the wind noise at that time is reduced, and the wind noise of the fan 12 can be further suppressed.

In the present invention, a switch for sending an operation signal to the motor control device 30 that outputs an operation command voltage to the DC electric motor 11 and an eco mode switch 25 for sending an eco mode operation signal are provided.
At least when the eco mode operation signal is output from the eco mode switch 25 to the motor control device 30, the operation command voltage can be controlled.

  In this way, it is possible to select a normal driving state and an eco-mode driving state.

In the present invention, by changing the standard value of the operation command voltage of the DC electric motor 11, two or more different air volumes can be set,
When the set air volume is large, the ratio of the voltage to be decreased from the standard value of the operation command voltage can be increased compared to when the air volume is large.

  In this way, power consumption during operation of the range hood can be further reduced, and the user can be prevented from feeling uncomfortable due to noise generated during operation of the range hood.

  According to the present invention, the power consumption during operation of the range hood can be reduced, and the wind noise when the rotation of the fan 12 is slowed down, so that the wind noise of the fan 12 can be suppressed.

It is a whole schematic explanatory drawing of a range hood. It is explanatory drawing of a motor control part. It is explanatory drawing of a delay circuit. It is a pattern explanatory view of an operation command voltage. It is explanatory drawing of 2nd Embodiment of the motor control part of this invention. It is a pattern explanatory view of an operation command voltage. It is explanatory drawing which shows 3rd Embodiment of the motor control part of this invention. It is a pattern explanatory view of the operation command voltage in a 4th embodiment. It is a pattern explanatory view of the operation command voltage in a 4th embodiment.

As shown in FIG. 1, the range hood of the present invention includes a hood 1, a blower 10, and a switch 20. By operating the switch 20 to drive the blower 10, oil smoke generated during cooking is hooded together with air. Collect in 1 and discharge outdoors.
The blower 10 rotates the fan 12 and drives the range hood by driving the DC electric motor 11.
As shown in FIG. 2, the switch 20 includes a plurality of operation switches for selecting the operation state of the range hood, for example, a weak switch 21, a middle switch 22, a strong switch 23, and an operation stop switch 24, and any one operation switch is selected. By operating the operation signal, the motor control device 30 is input.

The range hood shown in FIG. 1 will be described in detail.
The hood 1 has a box shape in which a lower surface is opened by an upper surface plate 2 and a peripheral surface plate 3, and a filter 4 and a current plate 5 are provided in the hood 1.
The blower 10 is provided with a fan 12 in a casing 13, and the fan 12 is attached to a motor shaft 11 a of a DC electric motor 11 provided in the casing 13.
The blower 10 is provided in the hood 1, and rotates the fan 12 to suck air from the suction port 14 and discharge it to the discharge duct 15.
The switch 20 is attached to the front surface 3 a of the peripheral plate 3.

The motor control device 30 outputs, to the DC electric motor 11 based on various operation signals input from the switch 20, operation command voltages having different sizes determined according to the operation signals, and the DC electric motor 11 is input. It rotates at a speed corresponding to the driving signal.
For example, when a weak operation signal is input to the motor control device 30 by operating the weak switch 21, the operation command voltage is a basic minimum value that is determined so as to match the weak operation, and the DC electric motor 11 rotates at a low speed. The range hood is weak.
When the intermediate switch 22 is operated, an intermediate operation signal is input to the motor control device 30, the operation command voltage is a basic intermediate value determined to match the intermediate operation, and the DC electric motor 11 rotates at an intermediate speed. The hood is medium driving.
When the strong switch 23 is operated, a strong operation signal is input to the motor control device 30, the operation command voltage is a standard maximum value determined to match the strong operation, the DC electric motor 11 rotates at high speed, and the range hood Becomes strong driving.

The voltage circuit 31 that sends the operation command voltage from the motor control device 30 to the DC electric motor 11 is provided with a control means 40 that gradually and gradually decreases the operation command voltage to a set value.
The control means 40 includes a changeover switch 41 for connecting the input side 31a and the output side 31b of the voltage circuit 31, and a delay circuit 42 provided between the input side 31a and the output side 31b.

The delay circuit 42 sequentially decreases and outputs the input operation command voltage to a set value as time passes.
For example, as shown in FIG. 3, the input side resistor 43 and the output side resistor 44 are grounded by a capacitor 45.

When the weak operation signal is input, the motor control device 30 continuously turns on the aforementioned changeover switch 41, so that the operation command voltage having the lowest basic minimum value passes through the changeover switch 41 to the DC electric motor 11. The DC electric motor 11 continues to rotate at a low speed.
When the intermediate operation signal is input, the motor control device 30 continuously turns on the aforementioned changeover switch 41, so that the operation command voltage of the intermediate intermediate value is passed through the changeover switch 41 and the DC electric motor 11. The DC electric motor 11 continues to rotate at a medium speed.

When a strong operation signal is input, the motor control device 30 repeats ON / OFF of the changeover switch 41 described above every predetermined time. When the changeover switch 41 is OFF, the operation command voltage having the above-mentioned standard maximum value is supplied to the DC electric motor 11 through the delay circuit 42. Therefore, the operation command voltage of the DC electric motor 11 is set from the standard maximum value. Slowly decreases gradually to the value.
Then, when a predetermined time elapses after the changeover switch 41 is turned off, the changeover switch 41 is turned on, and the operation command voltage of the standard maximum value is supplied to the DC electric motor 11 through the changeover switch 41.

As described above, when the strong switch 23 is operated, the operation command voltage supplied to the DC electric motor 11 is gradually decreased from the standard maximum value to the set value intermittently, and becomes the standard maximum value again.
For example, as shown in FIG. 4, the changeover switch 41 is turned on and off every 3 seconds, and when the changeover switch 41 is on, the operation command voltage is 100% (that is, the above-mentioned standard maximum value) and the changeover switch 41 is turned on. When is turned OFF, the operation command voltage is slowly decreased from 100% to 90% (that is, the setting value described above), and when the changeover switch 41 is turned ON again, it returns to 100%.

Thus, the power consumption of the DC electric motor 11 when the range hood is strongly operated, that is, the integrated power actual measurement value can be reduced by 5% to 10%. For example, the integrated power actual measurement value of 36.54 (wh) is normally 34.03 (wh), which is reduced to about 7%.
In addition, since the operation command voltage is slowly decreased, the rotational speed of the fan 12 by the DC electric motor 11 is slowly decreased. Therefore, wind noise generated when the rotational speed of the fan 12 is decreased is reduced. Wind noise is suppressed.

The motor control device 30 may have the function of the control means 40 described above.
For example, as shown in FIG. 5, it is assumed that the motor control device 30 has a microcomputer 32 for controlling the operation command voltage, and when the microcomputer 32 receives a weak operation signal and a medium operation signal, the above-mentioned standard minimum value is obtained. The operation command voltage of the standard intermediate value is continuously output, and when the strong operation signal is input, the operation command voltage having the pattern shown in FIG. 4 is output.

In this case, when a strong operation signal is input to the motor control device 30, an operation command voltage having a pattern shown in FIG. 6 may be output every 3 seconds.
That is, the operation command voltage is gradually decreased from 100% to 88% in a predetermined time (for example, 2.4 seconds), and the operation command voltage having a value of 88% is output for the predetermined time (for example, 1 second). % Gradually and gradually increase in a predetermined time (for example, 2.4 seconds).

  By doing so, the rotational speed of the DC electric motor 11 slowly slows down and increases slowly, so that the rotation of the fan 12 slowly slows down, slowly increases, and the wind noise when the fan 12 slows down. The wind noise when the speed is increased is reduced, and the wind noise of the fan 12 is further suppressed.

In the above-described embodiment, the power consumption is reduced only during the strong driving. However, the power consumption may be reduced during the middle driving and the weak driving.
For example, when a medium operation signal and a weak operation signal are input to the motor control circuit 30, the changeover switch 41 is repeatedly turned on and off at predetermined time intervals.

As shown in FIG. 7, an eco mode switch 25 is provided in the switch 20, and by operating the eco mode switch 25, the operation command voltage of the DC electric motor 11 is intermittently and slowly increased to a set value as described above. You may make it decrease.
For example, when each of the weak switch 21, the middle switch 22, and the strong switch 23 is operated, the operation command voltages of the basic minimum value, the intermediate value, and the maximum value are continuously output to make the range hood a normal weak operation, Medium and strong driving.
When the eco-mode switch 25 is operated, an eco-mode operation signal is input to the motor control device 30, and the motor control device 30 determines the operation command voltage from the standard maximum value when the strong operation signal is input intermittently. Slowly decreases gradually to the set value, or gradually decreases gradually from the standard maximum value to the set value, and then gradually increases to the standard maximum value.
That is, the above-described strong eco mode operation with reduced power consumption is set.

The operation is not limited to the above-described operation. When the weak switch 21, the middle switch 22, and the strong switch 23 are operated, the normal weak operation, intermediate operation, and strong operation are performed.
Only when both the eco mode switch 25 and the strong switch 23 are operated, the operation command voltage is controlled as described above to set the strong eco mode operation, and both the weak switch 21 and the eco mode switch 25 are operated. Is a normal weak operation, and when both the middle switch 22 and the eco mode switch 25 are operated, a normal medium operation is set.

Moreover, you may operate | move as follows.
When the weak switch 21, the middle switch 22, and the strong switch 23 are operated alone, the normal weak operation, medium operation, and strong operation are performed.
When both the weak switch 21 and the eco mode switch 25 are operated, the operation command voltage is intermittently gradually decreased from the basic minimum value to the set value, or gradually decreased from the basic minimum value to the set value. After that, it gradually increases gradually to the standard minimum value to make it a weak eco-mode operation.

  When both the middle switch 22 and the eco mode switch 25 are operated, the operation command voltage is intermittently and gradually decreased from the basic intermediate value to the set value, or gradually decreased from the basic intermediate value to the set value. After that, it gradually increases to the standard intermediate value, and the middle eco-mode operation is started.

  When both the strong switch 23 and the eco mode switch 25 are operated, the operation command voltage is intermittently and gradually decreased from the standard maximum value to the set value, or gradually from the standard maximum value to the set value. After decreasing, it gradually increases gradually to the standard maximum value, and strong eco-mode operation is made.

  That is, at least when the eco mode switch 25 is operated, the eco mode operation is performed.

  The eco mode switch 25 described above may be turned on and off independently, or may be turned on alone and turned off in conjunction with the operation of the operation stop switch 24.

  By selecting and operating a plurality of operation switches of the switch 20 and changing the magnitude of the standard value of the operation command voltage of the DC electric motor 11, the rotational speed of the DC electric motor 11 is increased or decreased, and the air volume set in the range hood If the air flow is different, the ratio of the voltage to be reduced from the standard value of the operation command voltage, that is, the rate of decrease with respect to the specified value, is set when the set air volume is large (when the standard value is large). Larger than when the air volume is small (when the standard value is small).

  In this way, power consumption during operation of the range hood can be further reduced, and the user can be prevented from feeling uncomfortable due to noise generated during operation of the range hood.

That is, when the standard value of the operation command voltage of the DC electric motor 11 is large and the set air volume is large, noise (wind noise and roaring sound of the fan 12) generated at the time of the range hood operation is large. Even if there is, it is hard to be worried about user.
On the other hand, when the standard value of the operation command voltage of the DC electric motor 11 is small and the set air volume is small, the noise generated during the range hood operation is small. Therefore, the user feels the noise increase and decrease sensitively and the noise increase and decrease. The user feels uncomfortable.
For example, since the noise level is high during strong driving, it is difficult for the user to be concerned about the increase or decrease in noise, but the noise is so small that it is not usually anxious during weak driving, and it is a comfortable state. It is.

  Therefore, when the set air volume is large, the ratio of the voltage to be reduced from the standard value of the operation command voltage is increased to increase the power consumption. The ratio of noise is reduced to reduce the increase or decrease in noise.

Next, an embodiment will be described.
As shown in FIG. 5, it is assumed that the motor control switch 30 includes a microcomputer 32 that controls the operation command voltage.
When a weak operation signal is input by operating the weak switch 21 of the switch 20, the microcomputer 32 continues to output the operation command voltage of the above-mentioned standard minimum value, and the normal weak operation is performed.

When the middle operation signal is input by operating the middle switch 22 of the switch 20, the microcomputer 32 changes the operation command voltage from the standard intermediate value 100% within a predetermined time (for example, 2 seconds) as shown in FIG. It gradually decreases gradually to 93.2%, and gradually increases or decreases gradually from 93.2% to 100% in a predetermined time (for example, 2 seconds).
That is, the ratio of the voltage to be reduced from the standard value of the operation command voltage is set to 6.8%.

When the strong operation signal is input by operating the strong switch 23 of the switch 20, the microcomputer 32 sets the operation command voltage to the standard maximum value 100 in a predetermined time (for example, 2.4 seconds) as shown in FIG. % Gradually decreases from 88% to 88%, and gradually increases gradually from 88% to 100% in a predetermined time (for example, 2.4 seconds).
That is, the ratio of the voltage to be decreased from the reference value of the operation command voltage is 12%, which is larger than that in the middle operation.

By doing in this way, even during the middle operation with a low noise value during the operation of the range hood, the rotation of the fan 12 slowly slows down and increases slowly, so the wind noise when the rotation of the fan 12 slows down, Wind noise when the speed is increased is reduced, and the wind noise of the fan 12 is further suppressed.
In addition, it is possible to reduce the power consumption during strong operation with high noise level during operation of the range hood.

In the above description, the ratio of the voltage for reducing the operation command voltage from the standard value to the set value is 10% of the standard value, preferably 7.93% to 12.03%, more preferably 8% to 12%. It is.
That is, the above-mentioned ratio is 12% or less of the standard value.
Further, the amount that gradually decreases gradually is 5% or less per second.

  DESCRIPTION OF SYMBOLS 1 ... Hood, 10 ... Blower, 11 ... Direct electric motor, 12 ... Fan, 20 ... Switch, 25 ... Eco mode switch, 30 ... Motor control device, 32 ... Microcomputer, 40 ... Means, 41 ... Changeover switch, 42 ... Delay circuit.

Claims (6)

A range hood comprising a hood (1) and a blower (10) that rotates a fan (12) with a DC electric motor (11),
Means for intermittently decreasing the operation command voltage from the standard value to the set value while operating the range hood with the operation command voltage of the DC electric motor (11) as a standard value. Provided,
The means starts increasing the operation command voltage as soon as the operation command voltage decreases to a set value and increases it to the standard value, or a time of several seconds shorter than the driving time by the standard value at the set value. The range hood is characterized in that, after being driven only, increasing to the standard value is intermittently performed a plurality of times.   The means includes a changeover switch (41) for cutting off the input side (31a) and the output side (31b) of the voltage circuit (31) for sending an operation command voltage from the motor control device (30) to the DC electric motor (11), A delay circuit (42) provided between the input side (31a) and the output side (31b) is provided, and the changeover switch (41) is repeatedly turned on and off at predetermined intervals by the motor control device (30). The range hood according to claim 1, which is configured as described above.   The range hood according to claim 1, wherein said means is a microcomputer (32) provided in a motor control device (30) for outputting an operation command voltage to a DC electric motor (11).   The range hood according to claim 3, wherein the microcomputer (32) gradually and gradually increases the operation command voltage to the DC electric motor (11) from the standard value to a set value and then to the standard value. A switch for sending an operation signal to a motor control device (30) for outputting an operation command voltage to the DC electric motor (11), and an eco mode switch (25) for sending an eco mode operation signal,
The range hood according to any one of claims 1 to 4, wherein the operation command voltage is controlled at least when an eco mode operation signal is output from the eco mode switch (25) to the motor control device (30). By changing the standard value of the operation command voltage of the DC electric motor (11), two or more different air volumes can be set,
The range hood according to any one of claims 1 to 5, wherein the ratio of the voltage to be reduced from the basic value of the operation command voltage is larger when the set air volume is larger than when it is small.

Images