KR101746213B1 - Ventilating fan - Google Patents

Abstract

The present invention relates to a constant air flow fan capable of improving accuracy and minimizing errors by controlling a constant air flow rate by detecting a change in current during a constant air flow rate control so that a constant air flow having a set target value can be provided,
A power module for supplying power to the motor; and a controller for controlling the motor so that the rotational speed of the motor is kept constant, Wherein the power module includes a feedback unit that amplifies a current of a power source supplied to the motor and feeds back the current to the control module, wherein the control module calculates a current value corresponding to a feedback current value and a positive air flow rate And a power controller for controlling the power module so that the current value corresponding to the current value and the feedback current value are equal to each other.

Description

VENTILATING FAN}

The present invention relates to a fan for ventilation,

And more particularly, to a constant air volume ventilation fan capable of improving accuracy and minimizing errors by controlling a constant air flow rate by detecting a change in current during a constant air flow rate control in which a constant air flow rate having a set target value can be provided.

Most buildings have a ventilation system that includes a ventilation fan for ventilation of the inside air.

Such a ventilation fan collects the indoor air and discharges it to the outside. In the case of the high-rise building, the pollutant is not smoothly discharged due to the static pressure loss.

As a conventional technique for solving such a problem, Japanese Patent Registration No. 10-0696854 (Mar. 13, 2007) (a conventional air flow fan using a BLDC motor) (hereinafter referred to as the prior art) is known.

In the related art, a constant air flow rate is controlled by using an RPM sensor (hall sensor, photo sensor) for measuring the rotation speed (RPM) of a BLDC motor (motor).

However, the direct measurement of the rotational speed of the motor has a problem in that the accuracy of the constant air flow rate is low because the error occurrence probability is high due to external factors such as vibration and impact.

Such an error causes an abnormal operation, which results in a loss due to a change in the static pressure of the wind, which results in a deterioration of the ventilation quality and an efficient discharge of pollutants.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

It is an object of the present invention to improve the precision and minimize the error by controlling the constant air flow rate by detecting the change of the current supplied to the motor according to the static pressure change.

The present invention also provides a table in which a current value (reference value) is compared with a voltage value according to a constant air volume to provide a more accurate constant air volume control through accurate reference value matching.

Another object of the present invention is to reduce the error of the constant airflow control by amplifying the feedback current so that the change of the current supplied to the motor can be precisely detected.

The present invention having the above object

A power module for supplying power to the motor; and a controller for controlling the motor so that the rotational speed of the motor is kept constant, Wherein the power module includes a feedback unit for amplifying a current of a power source supplied to the motor and feeding back the current to the control module, wherein the control module calculates a current value according to a feedback current value and a positive air flow rate And a power controller for controlling the power module so that the current value corresponding to the current value and the feedback current value are equal to each other.

Also, the comparison unit may include a table storing a current value (reference value) for a voltage according to a constant air flow rate, comparing a current value fed back and a current value corresponding to a constant air amount stored in the table, A power decrease command is transmitted to the power control unit, and when the feedback current value is lower than the reference value, the power increase command is transmitted to the power control unit.

In addition, the control module may further include an amplification controller for regulating an amplification factor of a current amplified by the feedback unit.

Further, the control module may include a level adjusting unit for adjusting the voltage level of the control signal to a predetermined level so that the power adjusting unit controls the power module through a control signal, a noise detecting unit for detecting noise introduced into the control signal, And a filter driving unit for driving the filtering unit when noise is detected. The base level adjusting unit includes a switching circuit for supplying operating power, an input terminal for receiving a control signal, A ground short circuit for stabilizing the level adjustment operation of the control signal, and an output stage circuit having a transistor (Q101) for adjusting and outputting a control signal to a predetermined level, wherein the input stage circuit is connected to an input terminal One end of the capacitor C101 is connected to the capacitor C101 and the other end thereof is connected to the transistor Q10 And a resistor R102 connected between the emitter of the transistor Q101 and the ground. The ground stage circuit includes a capacitor C102 and a resistor R102 disposed between the emitter of the transistor Q101 and the ground and connected in series, Wherein the output stage circuit further comprises two parallel resistors R103 and R104 and a capacitor C103 connected to the collector of the transistor Q101 and a resistor R106 connected in parallel with the resistor R105 and the resistor R106, The two parallel resistors R103 and R104 are connected to the resistor R101 of the input stage circuit. The noise detector includes a first amplifying circuit connected to an output terminal of the level adjusting unit to primarily amplify the control signal, A detection circuit connected to the second amplifier circuit for detecting a noise included in the control signal, and a second circuit connected to the output terminal of the detection circuit, The first amplifier circuit includes an amplifier A101, a resistor R107 having one end connected to the (+) terminal of the amplifier A101 and the other end connected to the output terminal of the level adjuster, A resistor R108 and a capacitor C104 connected to the (+) terminal of the amplifier A101 and the other end of the resistor R108 and the capacitor C104 connected in parallel to each other, And a resistor R109 and a capacitor C105 interposed between the (-) terminal and the output terminal of the amplifier A101 and arranged in parallel with each other, and the second amplifier circuit includes the amplifier A102, A resistor R111 connected to the capacitor C106 and having one end connected to the output terminal of the level adjuster, a capacitor C106 connected to the capacitor C106 and having one end connected to the ground, (-) terminal of the amplifier A102 and a resistor R112 and a capacitor C107 arranged in parallel with each other, (+) Terminal of the second amplifying circuit is connected to the output terminal of the first amplifying circuit, and the detecting circuit is connected to the (+) terminal of the first amplifying circuit, and the resistor R113 and the capacitor C108 interposed between the output terminals, A resistor R115 having one end connected to the output terminal of the level adjusting unit and a resistor R117 and a capacitor C110 connected in parallel and having one end connected to the ground are connected, (-) terminal of the first comparator A103, one end of which is connected to the negative terminal of the first comparator A103 connected to the output terminal of the level adjuster A103, And a second comparator A104 having a resistor R114 and a resistor R116 and a capacitor C109 connected in parallel and having one end connected to the ground and the backflow prevention circuit is connected to the first comparator A103 of the detection circuit, And reverse diodes D101 and D102 respectively connected to output terminals of the second comparator A104 The filter driving unit includes a delay circuit connected to an output terminal of the noise detecting unit, a driving circuit connected to an output terminal of the delay circuit and generating a driving signal, a bias circuit for providing a stable operating point, The delay circuit includes a resistor R118 and a reverse diode D103 connected in parallel to each other and connected to an output terminal of the detection circuit. The driver circuit includes a first amplifier A105, The collector of the transistor Q102 is connected to the relay circuit, the emitter of the transistor Q102 is connected to the ground, the base of the transistor Q102 is connected to the ground, The first amplifier A105 is connected to the output terminal of the second amplifier A106. The positive terminal of the first amplifier A105 has one end connected to a resistor R119 connected to the output terminal of the noise detector, and the other end connected to the ground The output terminal of the delay circuit is connected to the (-) terminal of the first amplifier A105 and the (+) terminal of the second amplifier A106 is connected in parallel, and the resistor R120 and the capacitor C111 arranged in parallel are connected in parallel. A reverse diode D104 is interposed between the output terminal of the first amplifier A105 and the positive terminal of the second amplifier A106, and a reverse diode D104 is interposed between the output terminal of the first amplifier A105 and the positive terminal of the second amplifier A106 A resistor R122 having one end connected to the output terminal of the delay circuit and a resistor R124 and a capacitor C112 having one end connected to the ground respectively, And the other end of the bias circuit is connected to the output terminal of the first amplifier A105 of the driving circuit and the (+) terminal of the second amplifier A106, And two resistors R125 and R126 and a capacitor C113.

The present invention having the above-

It is also possible to provide a constant airflow control with improved accuracy and minimized error, and also to amplify the feedback current so as to precisely detect changes in the current supplied to the motor, So that the error of the regular airflow control can be reduced.

1 is a configuration diagram of the present invention;
2 is an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

While the present invention has been described in connection with certain embodiments, it is obvious that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the drawings, the same reference numerals are used for the same reference numerals, and in particular, the digits of the tens and the digits of the digits, the digits of the digits, the digits of the digits and the alphabets are the same, Members referred to by reference numerals can be identified as members corresponding to these standards.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the term " comprising " or " consisting of ", or the like, refers to the presence of a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

It is to be understood that the first to second aspects described in the present specification are merely referred to in order to distinguish between different components and are not limited to the order in which they are manufactured, It may not match.

The present invention relates to a constant air volume ventilation fan capable of improving accuracy and minimizing errors by controlling a constant air flow rate by detecting a change in current during a constant air flow rate control so that a constant air flow rate having a set target value can be provided.

Hereinafter, a constant-flow-rate ventilation fan (hereinafter referred to as a ventilation fan F) according to the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 is a structural view showing the construction of the present invention.

1, the present ventilation fan F includes a motor m, a setting module 1, a power module 2, and a control module 3.

Prior to the description of each constitution, the ventilation fan rotates the blades coupled to the motor m to ventilate while generating wind. Since the present invention is an internal structure for driving the motor (m), the description of the device configuration deviates from the scope of the right to be protected by the present invention, so that even if a detailed description is omitted, There will be no difficulties for technicians to carry out.

In the description of each configuration, the motor m is configured to rotate by receiving power. 1, the motor m is composed of a BLDC motor m. The BLDC motor m has three-phase BLDC windings U, V and W, A detailed description of the present invention will not be described below.

Next, the setting module 1 is configured to set a target value (hereinafter referred to as a constant air flow rate) of the airflow amount according to the rotation of the motor m, and various types of input means such as a button, a touch screen, .

Next, the power module 2 is configured to supply power to the motor m, and includes a power supply unit 20 connected to the BLDC winding of the motor m and a power supply unit 20 connected to the power supply unit 20, And a feedback unit 21 for feeding back the current of the power source supplied to the motor m to the control module 3. [

The main feature of the present invention is that the feedback unit 21 amplifies the current of the power source supplied to the motor m and increases the variation width of the current due to the static pressure of the wind to increase the precision of the constant air amount control.

Next, the control module 3 is configured to control the motor m so that the rotational speed of the motor m is maintained at a constant air flow rate. The control module 3 may be implemented by a microcomputer. In addition to controlling the motor m, .

In addition to the feedback unit 21, a key feature of the present invention is that the control unit 3 includes a comparator 31 for comparing the current value fed back and the current value according to the constant air flow rate, And a power regulator 33 for controlling the power module 2 so that the current values are equal to each other. Here, the power regulator 33 preferably controls the power supply 20 in a PWM manner.

According to the present invention having the above-described configuration and features, it is possible to improve the accuracy and to provide a reliable constant airflow quality by minimizing the error as compared with a method of controlling the constant air flow rate by sensing the rotation itself of the motor have.

Hereinafter, further additional features of the present invention will be described.

As shown in FIG. 1, the ventilation fan F is equipped with a table t in which a comparison unit 31 stores a current value (reference value) with respect to a voltage of each constant air volume.

In this table t, a preliminarily generated constant current value (hereinafter, referred to as a reference value) of a constant air flow rate is stored. Through this, the control module 3 compares the current value fed back and the current So that the power module 2 supplied to the motor m can be controlled.

In the control process, if the feedback current value is higher than the reference value (the current value of the positive airflow), the comparator 31 transmits a power reduction command to the power controller 33, The control unit 33 controls the power module 2 to reduce the power supplied to the motor m until it becomes equal to the reference value stored in the table t to reduce the rotation speed of the motor m.

Also, if the feedback current value is lower than the reference value, the comparator 31 transmits a power increase command to the power controller 33, and the power controller 33 controls the power module 2 to control the motor m until it becomes equal to the reference value stored in the table (t), thereby increasing the rotational speed of the motor (m).

Also, as shown in FIG. 1, the ventilation fan F further includes a sensing module 4 for sensing a voltage supplied to the motor m.

It is possible to check the variation of the input voltage when the power supplied to the motor m is reduced or increased and to reflect the changed amount of power to the power module 2 through the power regulator 33.

Therefore, it is possible to correct the error of the regular air flow amount according to the change of the electric power supplied to the motor m when the AC input voltage fluctuates.

1, the ventilation fan F further includes an amplification control unit 35 for controlling the gain of the current amplified by the feedback unit 21 by the control module 3 .

When amplifying the current to be fed back from the feedback unit 21 to adjust the constant air flow rate, the amplification control unit 35 adjusts the degree of amplification according to the degree of the constant air flow rate to improve the precision of the regular air flow rate.

For example, when the air flow rate is small and the air flow rate is low, the change of the current due to the change of the static pressure of the wind is small, so that it is difficult to compare with the reference value of the table (t). Therefore, it is preferable to increase the degree of amplification of the feedback current in the case of low airflow.

In order to solve the above-mentioned error problem, the amplification control unit 35 selects the amplification degree optimized for the low or high air flow rate of the feedback unit 21 to narrow the error range of the constant air flow rate control.

In another aspect, as shown in FIG. 1, the ventilation fan F further includes a rotation sensing unit 37 for the control module 3 to detect the rotation angle of the motor m.

The rotation sensing unit 37 may be a hall sensor for sensing a change in magnetic field.

The control module 3 monitors the current position of the rotor of the motor m, that is, the rotation angle, that is, the rotation angle, through the rotation sensing unit 37 to monitor the state of the motor m.

1, the control module 3 preferably further includes an A / D (analog-to-digital) converter 39 to convert the input analog signal into a digital signal.

Setting of the target regular air flow rate and the voltage and current supplied to the motor m are converted into digital values through the AD conversion unit 39 to provide digital processing with a relatively high accuracy as compared with analog processing.

In the meantime, in the present invention, the control module 3 allows the power controller 33 to control the power module 2 through a control signal. There is a possibility that noise may be introduced into such a control signal due to influence by high frequency, interference by strong electric field of the power module 2, influence by the external environment, and the like.

The noise introduced into the control signal causes the voltage level of the control signal to increase or decrease rapidly, causing unstable operation of the control module 3 and the power module 2, and may cause malfunction and failure.

In order to solve this problem, the present invention provides a signal generating apparatus comprising: signal generating means for adjusting a voltage level of a control signal to match the operation of the power supply module, detecting and eliminating noise introduced into the control signal, (5) was further introduced.

The signal generating means 5 according to an embodiment of the present invention will now be described in more detail with reference to FIG.

(For the sake of convenience, it is not necessary to distinguish the names of the device units in the following description.) Therefore, it is preferable to deduce through the corresponding circuit including each element,

2, the signal generating means 5 includes a level adjusting unit 51 for adjusting the voltage level of the control signal to a predetermined level, a noise detecting unit 52 for detecting noise introduced into the control signal, And a filter driving unit 53 for driving the filtering unit 54 at the time of noise detection.

2, the level adjusting unit 51 for adjusting the voltage level of the control signal to a predetermined level includes a switching circuit 51 for supplying operating power, an input terminal circuit 512 for receiving a control signal, A grounding single circuit 513 for stabilizing the level adjusting operation of the control signal, and an output terminal circuit 514 for adjusting and outputting the control signal to a predetermined level.

More specifically, the switching circuit 51 determines whether the npn transistor Q101 constituting the output stage circuit 514 operates according to the voltage level of the input control signal. Although the specific configuration and the description of the configuration of the switching circuit 51 are omitted, those skilled in the art will be able to understand and infer the configuration as much as possible.

The input stage circuit 512 includes a capacitor C101 connected to an input terminal to which a control signal is input and two resistors R11 and R11 connected to the base of the transistor Q101 and having one end connected to the capacitor C101, ) R12.

Next, the ground short circuit 513 is composed of a capacitor C102 and a resistor R105 and a resistor R06 connected in parallel between the emitter of the transistor Q101 and the ground and connected in series.

The output stage circuit 514 includes npn transistor Q101 and two parallel resistors R103 and R104 connected to the collector end of the transistor Q101 and a capacitor C103. In particular, the two parallel resistors R103 and R104 are connected to the resistor R101 of the input stage circuit 512.

When the voltage level of the control signal is lower than a preset voltage level, the level adjusting unit 51 configured as described above supplies power to the transistor Q101 through the switching circuit 511 to drive the transistor Q101, The voltage level of the signal is raised by a predetermined voltage level.

In addition, when the voltage level of the control signal is higher than the predetermined voltage level, the level adjusting unit 51 cuts off the power applied to the transistor Q101 through the switching circuit 511 to stop the operation of the transistor Q101, The voltage level of the control signal is lowered by a predetermined voltage level.

At this time, the resistors R101 to R106 and the capacitors C101 to C103 of the input stage circuit 512, the ground short circuit 513 and the output stage circuit 514 determine the gain of the transistor Q101 to set the set voltage level The capacitor C101 of the input stage circuit 512 removes the DC component of the input control signal and the capacitor C103 of the output stage circuit 514 can remove the DC component of the control signal having the adjusted level .

2, the noise detecting unit 52 for detecting noise introduced into the control signal includes a first amplifying circuit 521 connected to the output terminal of the level adjusting unit 51 for first amplifying the control signal, A second amplifying circuit 522 connected to the first amplifying circuit 521 and secondarily amplifying the amplified control signal, a detecting circuit 523 connected to the second amplifying circuit 522 and detecting noise included in the control signal, And a backflow prevention circuit 524 provided at an output terminal of the detection circuit 523 for preventing reverse flow of current and noise.

More specifically, the first amplifying circuit 521 includes an amplifier A101, a resistor R107 connected at one end to the (+) terminal of the amplifier A101 and at the other end to the output terminal of the level adjusting section 51, A resistor R108 and a capacitor C104 connected to the (+) terminal of the amplifier A101 and the other end connected to the ground and arranged in parallel with each other, a resistor R110 disposed between the (-) terminal of the amplifier A101 and the ground, And a resistor R109 and a capacitor C105 interposed between the (-) terminal and the output terminal of the amplifier A101 and arranged in parallel with each other.

The second amplifying circuit 522 includes an amplifier A102, a capacitor C106 connected to the (-) terminal of the amplifier A102, and a resistor C106 connected to the capacitor C106, one end of which is connected to the output terminal of the level adjusting section 51 (R111), a resistor (R112) and a capacitor (C107) connected to the capacitor (C106) and having one end connected to the ground and arranged in parallel to each other, And a resistor R113 and a capacitor C108.

And the (+) terminal of the second amplifying circuit 522 is connected to the output terminal of the first amplifying circuit 521.

The first amplifying circuit 521 and the second amplifying circuit 522 amplify the control signal so that the noise can be detected more reliably.

The detection circuit 523 includes a first comparator A103 and a second comparator A104. One end of the first comparator A103 is connected to the output terminal of the level adjusting section 51, The negative terminal of the first comparator A103 is connected to the resistor R115 of the second amplifier circuit 522 and the resistor R117 and the capacitor C110 of which one end is connected to the ground, (A102) and the (+) terminal of the second comparator A104 are connected.

The (-) terminal of the second comparator A104 is connected to the (-) terminal of the first comparator A103. The (-) terminal of the second comparator A104 is connected to the output terminal of the level adjusting unit 51 A resistor R114 and a resistor R116 and a capacitor C109 connected in parallel and having one end connected to the ground are connected.

 Therefore, the first comparator A103 operates as a high-pass filter and the second comparator A104 operates as a low-pass filter to detect and output a noise signal corresponding to the set level reference range.

In particular, the level reference range setting of such a noise signal is performed by setting the resistor R117 connected to the (+) terminal of the first comparator A103 and the capacitor C110 connected to the (-) terminal of the second comparator A104, (R114) R116 and the capacitor C109. For this purpose, it is also possible to configure the two resistors R116 and R117 as variable resistors.

The backflow prevention circuit 524 is composed of reverse diodes D101 and D102 connected to the output terminals of the first comparator A103 and the second comparator A104 of the detection circuit 523, respectively.

The backflow prevention circuit 524 serves to prevent the current passing through the detection circuit 523 from flowing backward so as not to reentry and to prevent the noise from being introduced from the filter driving part 53 described later.

2, the filter driving unit 53 for driving the filtering unit 54 at the time of noise detection is connected to the output terminal of the delay circuit 531 and the delay circuit 531 connected to the output terminal of the noise detecting unit 52 A driving circuit 532 for generating a driving signal, a bias circuit for providing a stable operating point, and a relay circuit 534 connected to the driving circuit 532 and the bias circuit 533 and driven by a driving signal .

More specifically, the delay circuit 531 is connected to the output terminal of the detection circuit 523 and comprises a resistor R118 and a reverse diode D103 which are arranged in parallel with each other.

The delay circuit 531 prevents the shortening of the lifetime of the component by repeatedly turning on and off the relay circuit 534. After the relay circuit 534 is operated once, (534) is not turned off, the time is reset every time the noise is detected, and stable driving through delay setting is provided.

Next, the drive circuit 532 is composed of a first amplifier A105, a second amplifier A106, a transistor Q102, a plurality of resistors R119 to R126, and capacitors C111 to C113, The collector of the transistor Q102 is connected to the relay circuit 534, the emitter to the ground, and the base to the output terminal of the second amplifier A106.

A resistor R119 having one end connected to the output terminal of the noise detector 52 and a resistor R120 and a capacitor C111 having one end connected to the ground and arranged in parallel are connected in parallel at the (+) terminal of the first amplifier A105, Lt; / RTI >

The output terminal of the delay circuit 531 is connected to the (-) terminal of the first amplifier A105.

The output terminal of the first amplifier A105 is connected to the output terminal of the bias circuit 533 and the output terminal of the first amplifier A105 at the (+) terminal of the second amplifier A106. And a reverse diode D104 is interposed therebetween.

A resistor R122 connected at one end to the output terminal of the delay circuit 531 and a resistor R124 and a resistor R124 connected at one end to the ground respectively are connected to the negative terminal of the second amplifier A106, ) Are connected in parallel.

The bias circuit 533 has one end connected to the relay circuit 534 and the other end connected to the output terminal of the first amplifier A105 of the drive circuit 532 and the positive terminal of the second amplifier A106, And two resistors R125 and R126 and a capacitor C113.

The relay circuit 534 has a generally known configuration, and a simple description of the relay circuit 534 may be omitted.

More specifically, the bias circuit 533 controls the operating point of the voltage applied to the first amplifier A105 and the second amplifier A106 of the driving circuit 532 Setting. The voltage determined by the bias circuit 533 is applied to the first amplifier A105 and the second amplifier A106.

Also, when a voltage is applied to the resistors R122, R123, and R124 connected to the (-) terminal of the second amplifier A106, the second amplifier A106 is switched to the standby state for driving.

At this time, if an operation signal (a signal which is output after the noise detection unit 52 detects noise) is given from the noise detection unit 52 through the delay circuit 531, the first amplifier A105 and the reverse diode D104, The second amplifier A106 in the standby state is driven to operate the transistor Q102 and the transistor Q102 drives the relay circuit 534. [

Thereafter, the relay circuit 534 drives the filtering unit 54 to remove the noise of the control signal.

2, the filtering section 54 driven by the relay circuit 534 and removing noise includes a signal input circuit 541 for receiving a driving signal from the relay circuit 534 and receiving a control signal, A main filter circuit 542 connected to the signal input circuit 541 to remove noise included in the control signal and a main filter circuit 542 connected to the output terminal of the main filter circuit 542 for removing residual noise included in the control signal, And a filter circuit 543.

More specifically, the signal input circuit 541 is connected to the relay circuit 534 of the filter driving unit 53 and receives a driving signal for driving the filtering circuits 542 and 543. And receives a control signal. In addition, when no noise is detected in the control signal, an output terminal is provided so that the control signal can be directly outputted without passing through the filtering circuits 542 and 543.

The signal input circuit 541 includes a selector such as a multiplexer. The signal input circuit 541 selects an output terminal for outputting an input terminal or a control signal of the main filter circuit 542, that is, It is preferable to transmit the control signal. Although the illustration and the detailed description of the drawing relating to the signal input circuit 541 are omitted, it will be appreciated by those skilled in the art that the signal input circuit 541 can be understood and inferred.

Next, the main filter circuit 542 includes a forward diode D105 connected to the output terminal of the signal input circuit 541, a resistor R127 and a capacitor C114 connected in series to each other and a capacitor C114, C115 and a forward diode D106.

The forward diode D105 cuts off the current flow in one direction to block the reverse flow of the current from the main filter circuit 542 to the signal input circuit 541 and the resistor R127 connected in parallel with each other, And the capacitor C114 remove the noise included in the control signal. The capacitor C115 and the diode D106 connected thereto increase the noise removing efficiency.

The subfilter circuit 543 connected to the output terminal of the main filter circuit 542 for eliminating the residual noise includes an amplifier A107, first and second transistors Q103 and Q104, and a biased resistor R128 to R135) and capacitors C116 and C117.

In the sub filter circuit 543, three resistors R128, R129 and R130 are connected to the (+) terminal of the amplifier A107. One R128 is connected to the output end of the main filter circuit 542, And the other two of the resistors R129 and R130 are connected in parallel and the positive terminal of the amplifier A107 is connected between the two resistors R129 and R130.

The negative terminal of the amplifier A107 is connected to a capacitor C116 and two resistors R131 and R132 connected in parallel to each other and a reference voltage input terminal Sref. The two resistors R131 and R132 One of which is connected in series to the reference voltage input terminal and the other of which is connected to the ground and the capacitor C116 is connected in parallel between the two resistors R131 and R132.

The first and second transistors Q103 and Q104 are connected to the output terminal of the amplifier A107 and a resistor R133 is provided between the first transistor Q103 and the amplifier A107, And generates an operating point for driving the first and second transistors Q103 and Q104 with a constant voltage drop.

The first transistor Q103 is an npn transistor, the base is connected to the output terminal of the amplifier A107, the emitter is connected to the ground, and the collector is connected to the base of the second transistor Q104.

The second transistor Q104 is a pnp transistor, the base is connected to the collector of the first transistor Q103 as described above, the collector is connected to the ground, and the emitter is connected to the control signal output terminal.

In particular, between the second transistor Q104 and the output terminal of the control signal, two resistors R134 and R135 arranged in series and a capacitor C117 connected in parallel between the two resistors R134 and R135 are provided.

The two resistors R131 and R132 and the capacitor C116 provided at the (-) terminal of the amplifier A107 are connected to the reference voltage input terminal Sref, To generate a reference voltage. This reference voltage serves as a reference for eliminating noise, and a voltage level higher or lower than the reference voltage is regarded as noise and eliminated.

Next, three resistors R128 (R129) (R130) provided at the (+) terminal of the amplifier drop the voltage level of the control signal passed through the main filter circuit 542 to be comparable to the reference voltage, May be omitted depending on the output voltage level of the circuit 542. [

The amplifier A107 operates as a comparator, compares the reference voltage level with the level of the control signal, and confirms whether there is residual noise.

The first transistor Q103 and the second transistor Q104 of the subfilter circuit 543 are turned on when the control signal includes the residual noise and is instantaneously higher or lower than the reference voltage (in general, the voltage is raised by noise). ), And charges the capacitor C117 with a voltage which is increased by the noise, and the voltage level of the control signal which is lowered by the capacitor C117 is equal to the reference voltage level.

Thereafter, if the voltage level of the control signal corresponds to the reference voltage level, the first transistor Q103 and the second transistor Q104 are turned off, and then the voltage stored in the capacitor C117 is connected through a resistor R135 connected in parallel Discharged and restored to the original state.

The configuration of the filtering section 54 is such that the noise is primarily removed through the main filter circuit 542 and the remaining noise and the instantaneous noise are secondarily removed through the sub filter circuit 543, And outputs a clean control signal that is not included, thereby providing an effect of preventing malfunction and failure of each configuration.

Of course, it is also possible to provide only the filtering unit 54. However, since the level adjusting unit 51 sets the voltage level of the stable signal, the control signal can be maintained at a constant level, The signal is amplified to detect the noise more sensitively and the driving of the filtering unit 54 can be selectively operated according to the noise detection through the filter driving unit 53 so that the life of the filtering unit 54, The life of the capacitors C114 to C117 provided in the capacitor 54 is extended.

In addition, the fact that the filtering unit 54 is not driven at all times and is selectively driven according to whether or not noise is detected can provide a remarkable effect in reducing power consumption.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

F; Ventilation fan m: Motor
1: Setting module 2: Power module
20: power supply unit 21:
3: Control module
31: comparator 33: power regulator
35:
4: detection module 5: signal generation means

Claims (4)

motor;
A setting module for setting a target value (a regular air flow rate) of the air flow rate according to the rotation of the motor;
A power module for supplying power to the motor; And
And a control module for controlling the motor so that the rotational speed of the motor is kept constant to be a constant air flow rate,
Wherein the power module includes a feedback unit for amplifying a current of a power source supplied to the motor and feeding back the amplified current to the control module,
Wherein the control module includes a comparator for comparing the feedback current value and the current value according to the regular air flow rate, and a power controller for controlling the power supply module so that the feedback current value and the current value according to the regular air flow are the same,

The control module
A level adjusting unit for adjusting the voltage level of the control signal to a predetermined level so that the power adjuster controls the power module through a control signal, a noise detector for detecting noise introduced into the control signal, Further comprising signal generating means including a filtering section and a filter driving section for driving the filtering section when noise is detected,

The level adjusting unit includes a switching circuit for supplying operation power, an input terminal for receiving a control signal, a ground short circuit for stabilizing a level adjustment operation of the control signal, and a transistor Q101 for adjusting and outputting a control signal to a predetermined level And an output stage circuit,
The input stage circuit includes a capacitor C101 connected to an input terminal to which a control signal is input and two resistors R101 and R102 connected in parallel to each other while one end is connected to the capacitor C101 and the other end is connected to the base of the transistor Q101, ),
The ground stage circuit includes a capacitor C102 and a resistor R105 and a resistor R106 connected in parallel between the emitter of the transistor Q101 and the ground,
The output stage circuit further includes two parallel resistors R103 and R104 and a capacitor C103 connected to a collector terminal of the transistor Q101. The two parallel resistors R103 and R104 are connected to a resistor (R101)

The noise detector includes a first amplifier circuit connected to an output terminal of the level adjusting unit to primarily amplify a control signal, a second amplifier circuit connected to the first amplifier circuit to second amplify the amplified control signal, And a backflow prevention circuit provided at an output terminal of the detection circuit to prevent reverse flow of current and noise,
The first amplifying circuit includes an amplifier A101, a resistor R107 having one end connected to the (+) terminal of the amplifier A101 and the other end connected to the output terminal of the level adjusting unit, A resistor R110 disposed between the negative terminal of the amplifier A101 and the ground, and a resistor R110 connected between the negative terminal of the amplifier A101 and the ground, and a resistor R110 connected between the ground and the other end of the resistor R108 and the capacitor C104, And a resistor R109 and a capacitor C105 interposed between the (-) terminal and the output terminal of the capacitor C105,
The second amplifying circuit includes an amplifier A102, a capacitor C106 connected to the negative terminal of the amplifier A102, a resistor R111 connected to the capacitor C106 and having one end connected to the output terminal of the level adjuster, A resistor R112 and a capacitor C107 connected to the capacitor C106 and having one end connected to the ground and arranged in parallel with each other and a resistor C107 interposed between the negative terminal and the output terminal of the amplifier A102, R113) and a capacitor (C108), the (+) terminal of the second amplifying circuit being connected to the output terminal of the first amplifying circuit,
The detection circuit includes a resistor R115 having one end connected to the output terminal of the level adjusting unit and a resistor R117 and a capacitor C110 connected in parallel and having one end connected to the ground, A first comparator A103 connected to the amplifier A102 of the second amplifying circuit,
(-) terminal of the first comparator (A103), a resistor (R114) whose one end is connected to the output terminal of the level adjusting unit, and a resistor And a second comparator A104 to which a capacitor R116 and a capacitor C109 are connected,
The backflow prevention circuit comprises reverse diodes D101 and D102 respectively connected to the output terminals of the first comparator A103 and the second comparator A104 of the detection circuit,

The filter driving unit includes a delay circuit connected to an output terminal of the noise detecting unit, a driving circuit connected to an output terminal of the delay circuit and generating a driving signal, a bias circuit for providing a stable operating point, The relay circuit comprising:
The delay circuit includes a resistor R118 and a reverse diode D103 connected in parallel to an output terminal of the detection circuit,
The driving circuit includes a first amplifier A105, a second amplifier A106, a transistor Q102, a plurality of resistors R119 to R126, and capacitors C111 to C113,
The collector of the transistor Q102 is connected to the relay circuit, the emitter to ground, and the base to the output terminal of the second amplifier A106,
A resistor R119 whose one end is connected to the output terminal of the noise detecting unit and a resistor R120 and a capacitor C111 whose one end is connected to the ground and which are arranged in parallel are connected in parallel to the (+) terminal of the first amplifier A105 The output terminal of the delay circuit is connected to the (-) terminal of the first amplifier A105,
The positive terminal of the second amplifier A106 is connected to the output terminal of the first amplifier A105 and the output terminal of the first amplifier A105 is connected to the positive terminal of the second amplifier A106. A resistor R122 having one end connected to the output terminal of the delay circuit and a resistor R123 having one end connected to the ground and the other end connected to the output terminal of the delay circuit are connected to the negative terminal of the second amplifier A106, A connected resistor R124 and a capacitor C112 are connected in parallel,
The bias circuit has one end connected to the relay circuit and the other end connected to the output terminal of the first amplifier A105 of the driving circuit and the (+) terminal of the second amplifier A106. The two resistors R125, (R126) and a capacitor (C113). The method according to claim 1,
The comparing unit
A table storing a current value (a reference value) for a voltage of each constant air volume, and comparing the current value fed back and the current value of the constant air volume stored in the table,
And transmits a power reduction command to the power control unit when the feedback current value is higher than the reference value,
And transmits a power increase command to the power control unit when the feedback current value is lower than the reference value.
The method according to claim 1,
The control module
Further comprising an amplification control unit for regulating an amplification factor of a current amplified by the feedback unit.
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