KR0124559B1 - Apparatus and method for reducing sound of fan-fluid system - Google Patents

Abstract

To increase the amount of the vented air flow and reduce the noise, the Helmholtz resonator of which the length is varied and the adjustment means which adjusts the length of the Helmholtz resonator and the control means which feeds the adjustment signal to the length adjustment means by recognizing the rotation number of the fan are provided.

Description

Noise Reduction Device and Method of Fan Flow System

1 is a block diagram of a conventional room air conditioner indoor unit.

2 is a conventional room air conditioning noise analysis.

3 is a block diagram of a room air conditioner indoor unit according to an embodiment of the present invention.

4 is a structural diagram of a Hermholtz resonator used in the present invention.

5 is a detailed configuration diagram of a room air conditioner indoor unit according to one embodiment of the present invention.

6 is a flowchart of a noise reduction method according to the present invention.

* Explanation of symbols for main parts of the drawings

1: evaporator, 2: rear guide van,

3: fan, 4: stabilizer,

5: resonance tube, 6: plunger,

7: support, 8: transport support,

9: linear motor, 10: digital analog converter,

11: analog digital converter, 12: microcomputer,

13 rpm sensor.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a noise reduction device and a method of a fan flow system in which an air flow system such as a room air conditioner and a hot air blower is increased, but the noise is reduced. By narrowing the flow rate, the blowout air volume is increased, but the Helmholtz resonator is installed in the stabilizer, and the resonator length is adjusted according to the rotation speed of the fan to reduce the noise.

The existing room air conditioner indoor unit includes an evaporator 1 performing a heat exchange function between a refrigerant and air as shown in FIG. 1, a fan 3 supplying kinetic and pressure energy to the heat exchanged air and discharging it to the outside. And a rear guide van 2 for guiding the air flow by the fan 3 and a stabilizer 4 for stabilizing the air flow due to the rotation of the fan 3. The heat exchanged in the evaporator 1 is guided to the rear guide van 2 and stabilized by the stabilizer 4 as it is rotated.

Here, the room air conditioner using the evaporator 1 is taken as an example, but the hot air heater using the heat generator has the same structure, except that cold air or hot air is discharged.

The discharge air volume of the room air conditioner indoor unit described above is greatly influenced by the following three factors: first, the distance between the fan (3) and the stabilizer (δ), and second, the fan (3) and the rear guide van (2). Interval h and third, rpm of the fan 3, and the like.

In particular, in the state where the fan 3 is rotating at a constant rpm, the change of the discharge air volume is quite sensitive according to the size of the gap ∂ between the fan 3 and the stabilizer 4, and in general, the smaller the δ, the smaller the discharge. The air volume increases, but when δ decreases, the fan rotation noise (nz noise) increases.

The fan rotation noise (nz sound) is determined by the rotation speed n and the blade number Z of the fan 3. If the frequency of the fan rotation noise (nz sound) is fn, fn can be expressed as follows.

However, as shown in the air condition noise analysis diagram of FIG. 2, a specific noise peak value exists at the fan rotation noise (nz noise) frequency fn, thereby narrowing the gap (∂) between the fan 3 and the stabilizer 4 to some extent. Things are a big problem.

That is, it is possible to increase the discharge air volume by narrowing the gap δ between the fan 3 and the stabilizer 4, but accordingly, a specific noise peak value is generated at fn.

The present invention is to solve the above problems by narrowing the gap between the fan and stabilizer to increase the discharge air volume by increasing the discharge air volume by adjusting the resonator length of the Hermholtz resonator installed in the stabilizer to remove the noise It is an object of the present invention to provide an apparatus and method for reducing noise in a fan flow system.

The noise reduction device of the fan flow system in the present invention aims to increase the discharge air volume while reducing the noise, and a Hermholtz resonator installed in a stabilizer and having a variable resonator length, and a resonator length of the Hermholtz resonator. And a control means for applying a length adjustment signal to the length adjustment means by recognizing the rotational speed of the fan. The noise reduction method of the fan flow system checks whether the fan speed is changed over a predetermined range. The fan rotation speed check process is performed, and if the rotation speed is changed, an adjustment process of outputting a resonator length adjustment signal is calculated by calculating a resonator length using the fan rotation noise frequency as the sound absorption frequency.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings showing preferred embodiments.

3 is a block diagram of a room air conditioner indoor unit according to an embodiment of the present invention. In the room air conditioner indoor unit including an evaporator 1, a rear guide van 2, a fan 3, and a stabilizer 4, the stabilizer ( 4) and a narrow interval between the fan 3 is installed, but the Stabilizer 4 is configured to install a Hermholtz resonator.

Here, the reason why the Helmholtz resonator is installed in the stabilizer 4 is that the narrower the distance between the fan 3 and the stabilizer 4 is, the higher the specific noise peak is at the fan rotation noise frequency fn. This is because the sound absorption frequency of the Hermholtz resonator is adjusted to the fan rotation noise frequency fn to eliminate the specific noise peak value.

First, the casting and the principle of the Hermholtz resonator will be described with reference to FIG.

A Hermholtz resonator with a constant resonator diameter (D) and a resonator hole can be expressed as follows from an analytical model that simplifies the propagation of planar sound in an expansion chamber surrounded by a rigid wall within the resonator. .

here Where resonator length c is sound velocity f is sound absorption frequency.

As can be seen from the above equation (2), the resonator length ( Is determined, the sound absorption frequency (f) that is absorbed by the Hermholtz resonator is determined, so in the present invention, after installing the Hermholtz resonator in the stabilizer 4, the distance (δ) between the fan 3 and the stabilizer 4 By adjusting the resonator length G) to reduce the fan rotation noise frequency (fn) to the sound absorption frequency (f) by decreasing the volume of the exhaust fan, the discharge air volume is increased and the noise is reduced.

This embodiment of the present invention is illustrated in detail in FIG.

The Hermholtz resonator is installed with a resonance hole in the stabilizer (4) and the resonator length of the Hermholtz resonator ( ) Is variable by the plunger 6.

The resonator length ( The length adjusting means for adjusting () is a linear motor 9 whose rotation range is controlled by the length adjustment signal of the microcomputer 12, and a transfer support for changing the rotational motion of the linear motor 9 in a linear motion and transmitting it. 8) and a support 7 which is connected to the transfer support 8 and moves the plunger 6 installed in the resonance tube 5 of the Hermholtz resonator.

And the control means is composed of a microcomputer (12) where the microcomputer (12) receives the sensing input of the rpm sensor 13 to calculate the fan rotation noise frequency and then the resonator length adjustment signal of the fan rotation noise frequency as the sound absorption frequency Is configured to output.

Here, the microcomputer 12 receives the sensing input of the rpm sensor 13 through the analog digital converter 11 and outputs the resonator length adjustment signal through the digital analog converter 10.

The microcomputer 12 of the present invention checks the rotation speed of the fan 3 sensed by the rpm sensor 13 through the analog digital converter 11.

The microcomputer 12 calculates the fan rotation noise frequency fn at that time based on Equation (1) when the checked rpm rotation is changed by a predetermined range or more, and sets the fn as the sound absorption frequency f. ) Is calculated according to equation (2) and the resonator length ( Will output a length adjustment signal for adjusting).

The length adjustment signal of the microcomputer 12 is applied to the linear motor 9 through the digital analog converter 10 to control the rotation range of the linear motor 9 and the rotational motion of the linear motor 9 is transferred to the supporter ( 8) by linear motion.

The movement of the conveying support 8 causes the movement of the support 7 and the plunger 6 of the Hermholtz resonator is connected to the support 7 so that the plunger 6 is moved. ) Will be adjusted.

That is, the resonator length of the Hermholtz resonator installed in the stabilizer 4 according to the rotation speed change of the fan 3 ( By automatically adjusting), the fan noise peak value at the fan rotation noise frequency (fn) can be eliminated. Accordingly, the gap (δ) between the fan 3 and the stabilizer 4 can be narrowed to increase the discharge air volume while reducing the noise. It becomes possible.

The noise reduction method of the present invention is as follows.

The present invention consists of a fan rotation speed check process for checking whether the fan rotation speed fluctuates by more than a predetermined range, and an adjustment process for outputting a resonator length adjustment signal by calculating a resonator length using the fan rotation noise frequency as the sound absorption frequency when the rotation speed is changed. .

Here, the fan rotation speed check process is to adjust the resonator length set when the power is turned off when the power is checked and the fan is not rotated, and the rotation speed is set by detecting the rotation speed of the fan. This is done by checking if it is greater than the number variation.

And the adjustment process is the process of calculating the fan rotation noise frequency, the process of calculating the resonator length using the fan rotation noise frequency as the sound absorption frequency, if the change in the rotational speed of the fan is greater than the set rotation speed variation, the resonator according to the resonator length calculation Outputting a length adjustment signal.

This noise reduction method will be described based on the flowchart of FIG. 6, but will be described in detail with reference to FIG.

When the power is turned on the fan (3) that is the length of the initial length of the resonator when the resonator was set in a non-rotating state (n _o = 0), the system "off" ( _o = L- Rotate the linear motor (9) in the ') state and reset the system.

At this time, the fan speed before the sensation time is set to n _i-1 = n _o = 0 and the length of the resonator is _i-1 = _o = L- Where i represents the current sensation point and i-1 the previous sensation point (L is the length of the resonator) 'Is the distance traveled).

When the power is turned on, the current fan speed (ni) and the previous fan speed (n _i-1 ) are set equally while the resonator length is set. _o = 1- ', Then the current fan speed (ni) is sensed to subtract the previous fan speed (n _i-1 ) from the current fan speed (ni) and change it to an absolute value (| n _i -n _{i- Check whether 1} |) is greater than the rotation speed fluctuation value α when setting the fixed speed.

If the value of | n _i -n _i-1 | is smaller than the rotational speed variation (α), the resonator length (L- The process of sensing fan speed is repeated without changing) and when the value of | n _i -n _i-1 is greater than the speed change value α, the process of varying the resonator length is performed.

That is, if | n _i -n _i-1 | is greater than the rotation speed fluctuation value α, the fan rotation speed is changed. Therefore, the fan rotation noise (NZ sound) is calculated and the fan rotation noise is converted to the fan rotation noise based on the formula (1). Calculated as noise frequency (fni).

When the fan rotation noise frequency fni is calculated, the sound absorption frequency in the Hermholtz resonator is used. _i )

Therefore, when the fan rotation noise frequency fni described above is the sound absorption frequency f, the resonator length ( _i ) is And c is the speed of sound _i is calculated.

Thus the resonator length ( _i ) is calculated, the resonator length of the previous sensing point ( _i-1 ) ) (△ = _{i- i-1} )

Length difference of resonator (△ ) Is calculated and the resonator length of the current sensing point (l _i-1 ) _i ) The control amount for adjustment is calculated and the linear motor position control amount is determined according to the diameter (D) of the resonator and the area ratio (S) of the resonator hole. The position control amount of the motor 9 is calculated.

After calculating the position control amount of the linear motor, a length adjustment signal for executing the output is output. The length adjustment signal output from the microcomputer 12 is converted from the analog converter 10 to the analog voltage in the digital analog converter 10 and then the linear motor. The rotation of the linear motor 9 is controlled by applying to (9).

This operation repeats the above sequence from the fan speed detection operation when the system is running and ends the above operation when the system is 'off'.

Therefore, the present invention narrows the distance between the fan and the stabilizer, but increases the amount of air discharged, but reduces the noise by adjusting the resonator length of the Hermholtz resonator installed in the stabilizer, eliminating a specific noise peak generated at the fan rotation noise frequency. Can be.

That is, the present invention increases the air discharge amount in the air flow system but reduces the noise.

Claims (7)

A fan flow system comprising a fan for supplying kinetic and pressure energy to air and a stabilizer for stabilizing air flow due to fan rotation, the fan flow system comprising: a Hermholtz resonator installed in the stabilizer and having a variable resonator length; And a control means for recognizing the length of the resonator of the Hermholtz resonator and a control means for recognizing the rotational speed of the fan and applying a length adjustment signal to the length adjustment means. The noise reduction device of claim 1, wherein the resonator length of the Hermholtz resonator is configured to be variable by moving the plunger. The method of claim 1, wherein the length adjusting means is connected to the linear motor, the linear motor whose rotation range is controlled by the length composition signal of the control means, a transfer support for changing the linear motion of the linear motor in a linear movement, and the transfer support; And a noise reduction device of a fan flow system configured as a support for moving a plunger for varying the resonator length of the Hermholtz resonator. The noise reduction device of claim 1, wherein the control unit comprises a microcomputer that calculates a rotation noise frequency of the fan and outputs a resonator length adjustment signal. The fan rotation speed check process checks whether the fan rotation speed fluctuates more than a predetermined range, and if the rotation speed is fluctuated, it calculates the resonator length using the fan rotation noise frequency as the sound absorption frequency and outputs a resonator length adjustment signal. To reduce the noise of the fan flow system. The fan rotation speed check process is a process of adjusting the length of the resonator set when the power is turned off when the power is checked when the power is turned off, and the fan rotation speed by detecting the rotation speed of the fan A method of reducing noise in a fan flow system by checking whether a change is greater than a set speed variation. The method of claim 5, wherein the adjusting process comprises: calculating a fan rotation noise frequency when the change in the rotation speed of the fan is greater than the set rotation variation value, calculating a resonator length using the fan rotation noise frequency as the sound absorption frequency, and a resonator. A method for reducing noise in a fan flow system, comprising outputting a resonator length adjustment signal based on a length calculation.