KR102376694B1 - Heat recovery ventilator including acoustic wave module device - Google Patents

Abstract

The present invention is a case; a total heat exchange element located at the center of the inside of the case and heat exchanged while the outside air and the inside air cross pass; an outdoor air intake and an indoor exhaust located on one side of the case; an indoor ventilation hole and an outdoor air supply mechanism located on the other side of the case; a sound wave module device for emitting sound waves to the outdoor air intake space on the side of the outdoor air intake port to agglomerate fine particles included in the outdoor air flowing in from the outdoor air intake port to coarsen the size; It provides a heat recovery type ventilation device including a sound wave module device comprising a.

Description

Heat recovery ventilator including acoustic wave module device

The present invention relates to a heat recovery type ventilation device including a total heat exchange element and a sound wave module device, and more particularly, by emitting sound waves to a total heat exchange element and outdoor air intake space where heat exchange occurs while outside air crosses through the air intake space, It relates to a heat recovery type ventilation device including a sound wave module device for coarsening the size by agglomeration of fine particles contained in outdoor air flowing in from an outdoor air intake port.

In general, particulate matter is caused by combustion of fossil fuels rather than natural factors. It is mainly caused by anthropogenic factors such as dust from roads and railways. Recently, particulate matter of 0.1 μm or less is classified as ultra-fine dust and managed separately. Such fine dust causes bronchial inflammation, asthma, chronic bronchitis, airway obstruction, or inactivates or removes bacteria from lung tissue. It is because of the risk that it interferes with respiratory tract infections and acts as an important risk factor for cardiovascular diseases such as myocardial infarction, stroke, heart rate abnormality, and sudden death.

Recently, the importance of ventilation facilities in buildings is increasing due to air environment problems such as fine dust. Ventilation is an important issue that is directly related to the health of the people. In accordance with the ventilation facility standards of apartment houses and multi-use facilities, ventilation is performed at least 0.5 times per hour. has been made compulsory. Furthermore, the ventilation system installed in the new apartment house is obligatory to install a filter to prevent the collection of external pollutants and the inflow into the room.

In a typical ventilation unit, a duct connecting the indoor and outdoor areas of the building is installed, and a blower fan that forcibly exhausts and introduces indoor and outdoor air through this duct is installed. It is designed to ventilate. However, the ventilation unit has a problem in that, when the temperature difference between the indoor and the outdoor is large, the outdoor air is directly introduced into the indoor and the cooling/heating efficiency of the building is deteriorated.

In order to solve the problem of the conventional ventilation unit, in a ventilation method configured such that the exhausted waste heat is exchanged with the outside air and the supply and exhaust can be mechanically operated by the blower, recently heat recovery type ventilation including a total heat exchange element use the device

In general, the heat recovery type ventilation device including the total heat exchange element discharges polluted indoor air to the outdoors and supplies fresh outdoor air to the room while indirectly contacting the indoor air with the total heat exchange element to control the temperature of outdoor air. It is possible to prevent heat loss by minimizing the change in the indoor temperature by supplying external air.

The power consumption of the conventional commercialized heat recovery ventilation device is proportional to the air volume, and the larger the air volume, the proportionally the processable area increases. This has the disadvantage of being small, and there are problems in power consumption and noise generation when developing a product with a large air volume. There is not much difference in technology and performance of each product as it is air filtration filtering. In addition, the heat recovery type ventilation device using the air filtration and filtering as a main mechanism has problems such as generation of differential pressure due to fine dust, replacement cycle, and reduction in efficiency.

There is a need to develop a new heat recovery type ventilation device that can solve problems of energy efficiency and noise without changing the design of the conventional ventilation device by increasing the filter collection efficiency.

Korean Patent Publication No. 10-1117523-0000

In order to solve the problems of the prior art described above, an embodiment of the present invention is a sound wave module device that emits sound waves to an outdoor air intake receiving space to agglomerate fine particles included in the outdoor air flowing from the outdoor air intake port to coarsen the size. It provides a heat recovery type ventilation device including a sound wave module device with increased filter collection efficiency, including.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. There will be.

One aspect of the present invention for achieving the above-described object of the present invention is a case; a total heat exchange element located at the center of the inside of the case and heat exchanged while the outside air and the inside air cross pass; an outdoor air intake and an indoor exhaust located on one side of the case; an indoor ventilation hole and an outdoor air supply mechanism located on the other side of the case; a sound wave module device for emitting sound waves to the outdoor air intake space on the side of the outdoor air intake port to agglomerate fine particles included in the outdoor air flowing in from the outdoor air intake port to coarsen the size; It provides a heat recovery type ventilation device including a sound wave module device comprising a.

In one embodiment of the present invention, it may include a filter unit positioned between the outdoor air intake space and the total heat exchange element.

In one embodiment of the present invention, the filter unit may include any one or more of a pre-filter, a neutral filter, a semi-HEPA filter, a HEPA filter, and a wolpa filter.

In an embodiment of the present invention, the sound wave module device includes: a measurement sensor unit including an inflow fine particle measuring unit that measures fine particles in the air flowing into the outdoor air intake receiving space and outputs fine particle measurement data; a control unit for generating two or more low-frequency sound sources having different frequencies for aggregation of fine particles of different size distributions based on the measurement data of the fine particles and outputting them to a low-frequency sound wave generator; and a low-frequency sound wave generator that emits low-frequency sound waves corresponding to two or more different low-frequency sound sources for aggregation of the fine particles into the outside air intake receiving space.

In one embodiment of the present invention, the measurement sensor unit, the receiving space fine particle measurement unit for generating and outputting fine particle measurement data by measuring the fine particles contained in the air inside the outdoor air intake receiving space; to be configured to include can

In an embodiment of the present invention, the measurement sensor unit measures the fine particles contained in the air discharged through the outdoor air intake receiving space and the total heat exchange element, and then generates fine particle measurement data having a residual fine particle concentration. It may be configured to include; a residual fine particle measurement unit to output.

In one embodiment of the present invention, the measurement sensor unit, after detecting the frequency and sound pressure of the low-frequency sound waves inside the outdoor air intake receiving space, and then transmits the low-frequency sound wave measurement unit to the control unit; may be configured to include.

In one embodiment of the present invention, the control unit, a storage unit for storing the frequency and sound pressure data for each degree of contamination of fine particles for aggregation of fine particles; may be configured to include.

In one embodiment of the present invention, the frequency of the low-frequency sound waves may be 20 Hz to 20 kHz.

In an embodiment of the present invention, the sound pressure of the low-frequency sound waves may be 0 dB to 150 dB.

In an embodiment of the present invention, the control unit receives the frequency and sound pressure and residual fine particle measurement information of the low-frequency sound waves inside the outdoor air intake accommodating space to vary the frequency and sound pressure of the low-frequency sound sources and outputs the low-frequency sound source feedback control adjustment may be configured to perform

In one embodiment of the present invention, the low-frequency sound wave generator, the actuator installed in one or more pairs facing each other so as to emit the low-frequency sound waves that travel to face each other in the outdoor air intake receiving space It can be configured to include. .

In an embodiment of the present invention, a sound source amplifier for amplifying and outputting the low-frequency sound sources output from the control unit; may be configured to further include.

The heat recovery type ventilation device including the sound wave module device of an embodiment of the present invention described above is a simple method of outputting sound waves, and coarsens fine dust contained in the external air flowing into the outdoor air intake receiving space of the heat recovery type ventilation device by agglomeration. It can block PM 2.5 and PM 10 class fine dust from entering the room.

In addition, the efficiency of filtering is increased through coarsening of the fine dust described above, and the filter lifespan reliability is improved, so that the replacement cycle is increased, and the user's filter replacement and management is reduced, thereby increasing the economic effect.

In addition, since the capacity control of the motor of the heat recovery type ventilation device can be controlled by using the coarsening of the fine dust described above, there are effects of energy cost reduction and noise reduction.

It should be understood that the effects of the present invention are not limited to the above-described effects, and include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a schematic diagram of a heat recovery type ventilation device including a sound wave module device according to an embodiment of the present invention.
Figure 2 is a picture of the inside of the heat recovery type ventilation device equipped with a sound wave module device of an embodiment of the present invention.
3 is a functional block diagram of a sound wave module device according to an embodiment of the present invention.
4 is a diagram illustrating a mechanism in which fine particles are aggregated by low-frequency sound waves output in response to low-frequency sound sources having different frequencies for aggregation of fine particles according to an embodiment of the present invention.
5 is a diagram showing the superposition of low-frequency sound waves generated through a low-frequency generator composed of multiple actuators pairing a low-frequency sound source for aggregation of fine particles according to an embodiment of the present invention.
6 is a graph showing the difference between the intensity of the low-frequency sound wave output from a single actuator and the intensity of the low-frequency sound wave output from a pair of actuators facing each other for aggregation of fine particles according to an embodiment of the present invention.
7 is a schematic diagram of an experimental device for a reduction test of fine dust by a heat recovery type ventilation device including the sound wave module device of the present invention.
8 is a graph showing the results of the fine dust reduction test of FIG. 7 .
9 is a flowchart showing the processing process of the method of collecting and removing fine particles according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be embodied in several different forms, and thus is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part is said to be “connected (connected, contacted, coupled)” with another part, it is not only “directly connected” but also “indirectly connected” with another member interposed therebetween. "Including cases where In addition, when a part "includes" a certain component, this means that other components may be further provided without excluding other components unless otherwise stated.

The terminology used herein is used only to describe specific embodiments, and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present specification, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

1 is a schematic diagram of a heat recovery type ventilation device 1 including a sound wave module device according to an embodiment of the present invention.

Referring to FIG. 1 , the heat recovery type ventilation device 1 including the sound wave module device 200 of the present invention includes a case 100 ; a total heat exchange element 110 located at the center of the inside of the case 100 and performing heat exchange while the outside air and the inside air cross pass; an outdoor air intake 120 and an indoor exhaust port 130 positioned on one side of the case 100; an indoor ventilation port 140 and an outdoor air supply port 150 located on the other side of the case 100; A sound wave module device 200 for emitting sound waves to the outdoor air intake receiving space 121 on the side of the outdoor air intake port 120 to agglomerate fine particles included in the outdoor air flowing in from the outdoor air intake port 120 to coarsen the size; It includes a filter unit 160 positioned between the outdoor air intake accommodating space 121 and the total heat exchange element 110, and in the inner space of the case 100, outdoor air located on the side of the outdoor air intake port 120 intake receiving space 121; an indoor exhaust accommodating space 131 positioned on the indoor exhaust port 130 side; an indoor ventilation accommodating space 141 located on the indoor ventilation hole 140 side; and an outdoor air supply accommodating space 151 located on the side of the outdoor air supply mechanism 150 .

In the present specification, the heat recovery type ventilation device includes a total heat exchange element, so that when supplying fresh outdoor air to a room, the indoor air transfers energy to the incoming outside air, thereby minimizing heat loss due to the supply of the outside air. It means a ventilation system that allows

In general, the heat recovery type ventilation device includes a case forming an accommodating space, a total heat exchange element accommodated in the accommodating space of the case, an outdoor air intake and an outdoor air supply port respectively formed in the case, an indoor ventilation port and an indoor exhaust port, and the outdoor air supply A supply air blower fan configured in the accommodation space on the appliance side, an exhaust blower fan configured in the accommodation space on the indoor exhaust port side, a controller that controls the air supply blower fan and the exhaust ventilation fan according to the user's operation, and the user can input an operation signal It is based on being composed of a remote control.

In the general heat recovery type ventilation device described above, the controller controls the operation of the supply air blower fan and the exhaust blower fan according to the user's remote control operation, so that the polluted indoor air is discharged outdoors and fresh outdoor air is supplied to the room by the total heat exchange element. By controlling the temperature of the outdoor air by indirect contact with the indoor air, it is possible to prevent heat loss by minimizing the change in the indoor temperature by supplying external air.

The present invention relates to a heat recovery type ventilation device (1) including a sound wave module device (200), in which fine particles are introduced and the introduced fine particles can be coarsened by the sound wave module device (200) of the present invention If it is a heat recovery type ventilation device including an accommodation space, the structure and type may not be limited.

Accordingly, the case 100 included in the heat recovery type ventilation device 1 including the sound wave module device 200 of the present invention; a total heat exchange element 110 located at the center of the inside of the case 100 and performing heat exchange while the outside air and the inside air cross pass; an outdoor air intake 120 and an indoor exhaust port 130 positioned on one side of the case 100; And the shape and structure of the indoor ventilation port 140 and the outdoor air supply port 150 located on the other side of the case 100 may not be limited as long as they are obvious in the art.

In one embodiment of the present invention, the filter unit 160 positioned between the outdoor air intake accommodating space 121 and the total heat exchange element 110 is a pre-filter, a neutral-star filter, a semi-HEPA filter, a HEPA filter, and a ULPA filter. It may be configured to include any one or more of the filters.

The pre-filter (primary filter) is a filter having the most average function and means a filter capable of filtering out dust with a size of about 5 μm, and the secondary filter is a filter having the most average function. It means a filter capable of filtering out dust with a size of about 1 μm, and the semi HEPA, HEPA, and ULPA filters are about 0.5 μm, 0.3 μm, 0.3 μm or less, respectively. It means a filter that can filter out dust of the size of

In an embodiment of the present invention, the filter included in the filter unit 160 may be used in combination with the above-mentioned filters, and in a specific embodiment, the pre-filter and the semi-HEPA filter may be sequentially positioned and used. It is not limited.

Specifically, when the heat recovery type ventilation device 1 is driven by locating the pre-filter and the semi-HEPA filter sequentially, the air introduced into the outdoor air intake accommodating space 121 is directed toward the total heat exchange element 110 . The pre-filter primarily filters large-sized dust among the dust contained in the air, and the semi-HEPA filter secondarily filters the dust that has passed through the pre-filter.

At this time, when the fine dust contained in the air introduced into the outdoor air intake accommodating space 121 is coarsened using the sound wave module device 200, As the amount increases, the amount of fine dust that passes through the total heat exchanger and flows into the room can be reduced.

In addition, at this time, as the amount of fine dust filtered by the pre-filter increases, the amount of fine dust reaching the semi-HEPA filter is reduced, thereby making it possible to use the semi-HEPA filter for a long time. Filter replacement cycle may increase.

In addition, since the size of the fine dust filtered by the filter increases, the filter collection efficiency is increased, which has an advantage in that it is not necessary to use an expensive filter.

Figure 2 is a photo of the inside of the heat recovery type ventilation device (1) mounted with a sound wave module device 200 of an embodiment of the present invention.

Referring to FIG. 2 , the sound wave module device 200 is configured to output sound waves to the outdoor air intake receiving space 121 on the outside air intake port 120 side of the case 100 of the heat recovery type ventilation device 1 . It may be possible, and it is possible to coarsen the fine dust contained in the external air flowing into the outdoor air intake receiving space 121 .

3 is a functional block diagram of the sound wave module device 200 according to an embodiment of the present invention.

Referring to FIG. 3 , the sound wave module device 200 of the present invention generates fine particle measurement data such as concentration, size, temperature, humidity, etc. of the fine particles flowing into the outdoor air intake receiving space 121 using a measurement sensor, etc. The frequency of the low-frequency sound waves output into the inflow fine particle measuring unit 211 that outputs the air intake, the receiving space fine particle measuring unit 212 measuring the fine particles in the outdoor air intake accommodating space 121, and the outdoor air intake accommodating space 121 and a low-frequency sound wave measuring unit 213 for measuring sound pressure and a residual fine particle measuring unit 214 for measuring residual fine particles in the air discharged through the outdoor air intake accommodating space 121 and the total heat exchange element. sensor unit 210; Based on the fine particle measurement data measured by the measurement sensor unit 210, a size distribution of fine particles is generated, and two or more low-frequency sound sources having different frequencies for aggregating fine particles for each size distribution are generated. a control unit 220 for outputting; a sound source amplifying unit 230 amplifying and outputting two or more low-frequency sound sources output from the control unit 220; It may be configured to include a low-frequency sound wave generator 240 for outputting low-frequency sound sources for the aggregation of the fine particles as low-frequency sound waves.

In one embodiment of the present invention, the inflow fine particle measuring unit 211 includes the number, size, concentration, volume, After measuring the temperature, etc., it may be configured to output to the control unit 220 as fine particle measurement data.

In one embodiment of the present invention, the control unit 220 each other based on the fine particle measurement data including the number, size, concentration, volume, temperature, etc. of the fine particles output from the inflow fine particle measurement unit 211 . It may be configured to generate and output two or more low-frequency sound sources having different frequencies and sound pressures for aggregation of fine particles of different size distributions.

The control unit 220 includes functions for converting the frequency and sound pressure information of the low-frequency sound source and the low-frequency sound source for each fine particle measurement data such as the number, size, concentration, volume, temperature, etc. of the fine particles to generate the low-frequency sound sources It may be configured to include a storage unit 221 for storing program information and the like.

In this case, the frequencies of the low-frequency sound sources have different frequencies within the range of 20 Hz to 20 kHz so as to be harmless to the human body within the audible frequency, and the sound pressure of the low-frequency sound waves may be 0 dB to 150 dB.

In addition, the control unit 220 is a low-frequency sound wave measurement data and residual inside the outdoor air intake receiving space 121 input from the low-frequency sound wave measurement unit 213 and the residual fine particle measurement unit 214 of the measurement sensor unit 210 . After receiving the fine particle measurement data, it may be configured to perform a low frequency sound source feedback control that varies the frequency and sound pressure of the low frequency sound source in order to increase the fine particle aggregation efficiency.

In one embodiment of the present invention, the sound source amplifying unit 230 is configured to include amplification elements for amplifying the low-frequency sound sources, and if necessary, amplifies the low-frequency sound sources output from the control unit 220 and outputs them. .

In an embodiment of the present invention, the low-frequency sound wave generator 240 reproduces the low-frequency sound sources output from the control unit 220 and enters the outside air intake accommodating space 121 into the low-frequency sound waves corresponding to the frequencies of the low-frequency sound sources. can be outputted to cause the fine particles to vibrate and collide to agglomerate. To this end, the low-frequency sound wave generator 240 may be configured to include one or more actuators 241 that output low-frequency sound waves of different frequencies into the outside air intake accommodating space 121 . In addition, the actuators 241 overlap the low-frequency sound waves output in response to the low-frequency sound sources, thereby increasing the collision force and collision frequency of the fine particles to increase cohesion efficiency, forming pairs to face each other and receiving the outdoor air intake It may be installed in the space 121 . In this case, the number of actuator pairs may be increased according to the area or volume of the outdoor air intake receiving space 121 .

In an embodiment of the present invention, the measurement sensor unit 210 includes the frequency, sound pressure, and vibration speed of the fine particles and low-frequency sound waves inside the outdoor air intake accommodating space 121 and the air inside the outdoor air intake accommodating space 121 . It may be configured to measure and output to the control unit 220 . Accordingly, the measurement sensor unit 210 may include a fine particle measurement sensor, a sound wave meter for frequency measurement, a dB meter for sound pressure measurement, and measurement sensors such as a speedometer for medium vibration velocity measurement.

In one embodiment of the present invention, the low-frequency sound wave generator 240 installed in the outdoor air intake receiving space 121 is configured to include actuators 241 that output low-frequency sound waves. The actuators 241 may be installed in a plurality of pairs opposite to each other on the outside of the outdoor air intake receiving space 121 to increase the intensity of the sound waves by superimposing the low-frequency sound waves to increase the aggregation efficiency of the fine particles.

In one embodiment of the present invention, the residual fine particle measuring unit 214 measures the residual fine particles in the air discharged from the outdoor air intake receiving space 121 to perform feedback control for fine particle aggregation, a measurement sensor is configured to include, installed in the outdoor air supply air receiving space 151, and after measuring the fine particles contained in the air discharged from the outdoor air intake receiving space 121 through the total heat exchange element 110, the residual It may be configured to generate residual fine particle measurement data including the size, concentration, number, etc. of the fine particles and output to the controller 220 .

The sound wave module device 200 having the above configuration is installed in the outdoor air intake accommodating space 121, measures the air flowing into the outdoor air intake accommodating space 121, and the size and concentration of fine particles contained in the incoming air. The size distribution of fine particles is created based on the measurement data of fine particles having information such as , humidity, and temperature. In addition, after extracting two or more low-frequency sound sources having different frequencies for performing aggregation of fine particles included in different size distributions of fine particles, the low-frequency sound wave for aggregation of fine particles into the outside air intake receiving space 121 is reproduced. print them out As a result, fine particles having different size distributions are aggregated at the same time by different frequencies to generate a fine particle agglomeration. The efficiency is significantly improved, and the fine particle removal efficiency is also significantly improved.

4 is a view showing a mechanism in which fine particles are agglomerated by low-frequency sound waves output in response to low-frequency sound waves having different frequencies for aggregation of fine particles according to an embodiment of the present invention. (Fluid) and microparticles (p1, p2) show the waveform of vibration caused by low-frequency sound waves, and in FIG. indicates aggregation.

The aggregation behavior of ultrafine particles in a medium due to wave interference for aggregation of fine particles applied to the present invention is a phenomenon of agglomeration due to collision due to a difference in movement speed between particles in a medium based on the ortho-kinetic collision mechanism.

By developing the aggregation behavior of ultra-fine particles under the conditions of acoustic wave (Hz) and arbitrary SPL (Sound Pressure Level, dB), ultra-fine particles of 1 μm or less can become more than 10 μm in a short time under conditions of several Hz and several dB. The cohesive behavior of coarsening was confirmed.

Referring to FIG. 4 , the aggregation technique of the sound wave module device 200 according to an embodiment of the present invention is an application of Orthokinetic Collision behavior, in which fine particles collide by sound waves in a medium such as air, and van der Waals forces (van). It is the behavior of agglomeration due to surface attraction caused by der Waals force).

At this time, the fine particle aggregation efficiency (β) in the medium by the sound wave is the fine particle size (d), the vibration speed of the low-frequency sound wave (U ₀ ), the relaxation time of the fine particles (τ), which is the time until the collision of the two fine particles, It can be controlled as a variable of the relative entrainment time (η) of the fine particles, and the following [Equation 1] is an equation for calculating the aggregation efficiency (β), and [Equation 2] calculates the relative entrainment time (η) is the way

[Equation 1]

In addition, the speed difference between the fine particles can be calculated through Equation 2 below.

[Equation 2]

As shown in FIG. 4 , when a low frequency sound wave corresponding to a low frequency sound source is output through the low frequency sound wave generator 140 , the fine particles p1 and p2 in the unit cohesive channel 161 are generated as shown in FIG. 2 ( a ). , the medium vibrates in response to the frequency and sound pressure of low-frequency sound waves.

At this time, the vibration amplitude of the relatively small fine particles (p1) is greater than the vibration amplitude of the relatively large fine particles (p2), and the relatively small size fine particles (p1) and the relatively large fine particles (p2) When they collide with each other due to a difference in their moving distances, relatively small particles (p1) and relatively large particles (p2) are aggregated with each other by van der Waals force to form a fine particle aggregate. And by controlling the frequency and sound pressure of the low-frequency sound source, it is possible to adjust the cohesive efficiency (β) by applying Equation 1, thereby enabling feedback low-frequency sound source control for improving the cohesive efficiency.

4, Equations 1 and 2, U ₀ is the velocity amplitude of sound wave, y is the vibration velocity function of the fine particles, d is the size of the fine particles, y' is the medium is the vibration velocity function of, φ(=ωt±α) is the phase difference between the vibration velocity of the fine particle and the medium velocity, ω is the angular velocity of the low-frequency sound wave, α is the initial phase of the low-frequency sound wave, and τ(τ ₁ , τ ₂ ) is the two microscopic Particle relaxation time, η is the relative entrainment between the two particles, subscript 1 is small particles and related variables, subscript 2 is Large microparticles and related variables are shown.

5 is a diagram showing the superposition of low-frequency sound waves generated through the low-frequency generator 240 composed of multiple actuators 241 that pair with each other a low-frequency sound source for aggregation of fine particles according to an embodiment of the present invention, FIG. is a graph showing the difference in intensity between the intensity of the low-frequency sound wave output from the pair of actuators 241 opposing each other and the intensity of the low-frequency sound wave output from the single actuator 241 for aggregation of fine particles according to an embodiment of the present invention.

The actuators 241 constituting the low-frequency sound wave generator 240 are installed in pairs facing each other, thereby improving the aggregation efficiency of the fine particles.

Specifically, as shown in FIGS. 5 and 6 , the actuators 241 are installed in pairs opposite to each other, so that the low-frequency sound waves (w) are superimposed on each other, thereby increasing the intensity, and thereby, relatively small-sized fine particles. (p1) and the relatively large fine particles (p2), the vibration speed and the amount of impact at the time of the collision may increase, so that the aggregation efficiency may be increased.

7 is a schematic diagram of an experimental apparatus for a reduction test of fine dust by the heat recovery type ventilation device 1 including the sound wave module device 200 of the present invention.

Referring to FIG. 7 , a chamber capable of generating fine dust is connected to the heat recovery type ventilation device 1 including the sound wave module device 200 of the present invention, and heat recovery type ventilation including the sound wave module device 200 While operating the device (1), the change in the concentration of fine dust was analyzed depending on whether the sound wave was driven (Start: 2000 ± 10 % μg/m ³ (Particle Matter less than 2.5 μm); Speed: Low, Medium, High (MAX: 150 CMH);Sound: 30 Hz - 50 dB to 60 dB).

8 is a graph showing the result of the fine dust reduction test of FIG. 7, and specifically, a particle counter for measuring the concentration of PM 2.5 class fine dust is installed in S1 to S3, and PM at S2 position according to the driving time The concentration of 2.5 was analyzed, and a graph of the results was shown.

Referring to FIG. 8 , the change in the concentration of PM 2.5 is clearly shown when the sound wave is not driven and when the sound wave is driven, and in particular, it can be confirmed that the reduction behavior varies according to a given sound wave frequency. This means that the energy, the cohesive position, the degree of constructive interference according to the sound wave frequency, and the like, vary depending on the shape and area of the outdoor air intake receiving space 121, and thus the concentration changes appear. there was.

9 is a flowchart showing the processing process of the method of collecting and removing fine particles according to an embodiment of the present invention.

As shown in FIG. 9 , in the method of collecting and removing fine particles, first, using the inflow fine particle measuring unit 211 , the outdoor air intake accommodating space 121 or the outdoor air intake accommodating space 121 is used to measure the contamination level of the fine particles inside. The initial fine particle measurement step (S10) of outputting the generated fine particle measurement data to the control unit 220 is performed. In this case, the fine particle measurement data may include the number, size, concentration, temperature, humidity of the medium, or area or volume data of the outdoor air intake receiving space 121 of the fine particles.

The control unit 220 extracts the frequencies and sound pressures of two or more low-frequency sound sources having different frequencies for the aggregation of the fine particles stored in the storage unit 221 according to the fine particle measurement data; a frequency and sound pressure data extraction step ( S20) is performed. At this time, the different frequencies and sound pressures extracted are classified according to the number, size, concentration, temperature, humidity of the medium, or the area or volume distribution of the outdoor air intake receiving space 121. 220) may be stored in the internal storage unit 221 . In this case, the frequency of the low-frequency sound source is in the range of 20 Hz to 20 kHz, and the sound pressure may be 0 dB to 150 dB, and the different frequencies and sound pressures are the size, concentration, indoor temperature, indoor humidity, and outdoor air of the fine dust. It may be extracted to correspond to the area or volume of the intake receiving space 121 .

Next, the control unit 220 performs a sound source generation step (S30) of generating and outputting two or more low-frequency sound sources having the extracted different frequencies and sound pressure data.

Next, when it is necessary to amplify the low-frequency sound sources, after the sound source generating step (S30) is performed, the low-frequency sound sources having different frequencies are received and amplified, and then the sound source is output to the low-frequency sound wave generator 240 . An amplification step (S40) may be performed.

Next, the low-frequency sound wave generating unit 240 receives the low-frequency sound sources and outputs low-frequency sound waves having different frequencies to the inside of the outdoor air intake receiving space 121, so that the outside air intake receiving space 121 is located inside the A fine particle aggregation step (S50) of aggregating the fine particles contained in the air according to different size distributions by vibrating them according to different size distributions is performed.

Thereafter, according to a preset period or a user's control command, the receiving space fine particle measuring unit 212 of the measuring sensor unit 210 outputs the low-frequency output corresponding to the two or more low-frequency sound sources having different frequencies. After detecting the frequency and sound pressure of the sound waves, they are transmitted to the control unit 220, and the number, concentration, size, etc. can be detected and transmitted to the control unit 220 . The control unit 220 compares the received frequencies and sound pressures with the extracted frequencies and sound pressures to determine whether they match, calculates the fine particle removal efficiency, and determines whether the fine particle removal efficiency reaches a target value. A determination step (S80) of achieving particle removal efficiency is performed.

As a result of the determination of the above-mentioned fine particle removal efficiency achievement determination step (S70), if the fine particle removal efficiency does not reach the target value, the control unit 220 applies [Equation 1] and [Equation 2] to aggregate the fine particles A low-frequency sound source feedback adjustment step (S80) of regenerating low-frequency sound sources having different frequencies to simultaneously agglomerate micro-particles of different micro-particle size distributions by deriving frequencies and sound pressures having frequencies that increase efficiency is performed.

And, as a result of the determination of the above-mentioned fine particle removal efficiency achievement determination step (S70), when the fine particle removal efficiency reaches a target value, the control unit 220 determines whether the fine particle removal operation is finished. By performing the end determination step (S90), if the operation is not finished, it returns to the fine particle aggregation step (S50) and performs the processing process again, and when the operation is finished, the fine particle aggregation purification operation is terminated.

Although the technical idea of the present invention described above has been specifically described in the preferred embodiment, it should be noted that the above-described embodiment is for the description and not the limitation. In addition, those of ordinary skill in the technical field of the present invention will understand that various embodiments are possible within the scope of the technical spirit of the present invention. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: case
110: total heat exchange element
120: external air intake
121: outdoor air intake receiving space
130: indoor exhaust port
131: indoor exhaust accommodation space
140: indoor ventilation
141: indoor ventilation accommodation space
150: external air supply mechanism
151: outside air supply air receiving space
160: filter unit
200: sound wave module device
210: measurement sensor unit
211: inflow fine particle measurement unit
212: external air intake receiving space fine particle measurement unit
213: low-frequency sound wave measurement unit
214: residual fine particle measurement unit
220: control unit
221: storage
230: sound source amplification unit
140: low-frequency sound wave generator
141: actuator
x: fine particle vibration amplitude
U ₀ : the velocity amplitude of sound wave
τ: fine particle relaxation time (time until collision: particle relaxation time)
η: the relative entrainment between the two particles
F: air flow

Claims (13)

case;
a total heat exchange element located at the center of the inside of the case and performing heat exchange while the outside air and the inside air cross pass;
an outdoor air intake and an indoor exhaust located on one side of the case;
an indoor ventilation hole and an outdoor air supply mechanism located on the other side of the case;
a sound wave module device for emitting sound waves to the outdoor air intake space on the side of the outdoor air intake port to agglomerate fine particles included in the outdoor air flowing in from the outdoor air intake port to coarsen the size;
including,
It characterized in that it comprises a filter part positioned between the outdoor air intake receiving space and the total heat exchange element,
The sound wave module device may include: a measurement sensor unit including an inflow fine particle measuring unit that measures fine particles in the air flowing into the outdoor air intake receiving space and outputs fine particle measurement data; a control unit for generating two or more low-frequency sound sources having different frequencies for aggregation of fine particles of different size distributions based on the measurement data of the fine particles and outputting them to a low-frequency sound wave generator; and a low-frequency sound wave generator that emits low-frequency sound waves corresponding to two or more different low-frequency sound sources for aggregation of the fine particles into the outside air intake receiving space; characterized in that it comprises a,
The low-frequency sound wave generator includes a sound wave module device, characterized in that it comprises actuators installed in pairs opposite to each other so as to emit the low-frequency sound waves propagating opposite to each other in the outdoor air intake receiving space. Heat recovery ventilation system. delete The method of claim 1,
The filter unit is a heat recovery type ventilation device including a sound wave module device, characterized in that it includes any one or more of a pre-filter, a neutral filter, a semi-HEPA filter, a HEPA filter, and a wolpa filter. delete The method of claim 1,
The measurement sensor unit, the receiving space fine particle measurement unit for generating and outputting fine particle measurement data by measuring the fine particles contained in the air inside the outdoor air intake receiving space; a sound wave module device, characterized in that it is configured to include Heat recovery type ventilation system including. The method of claim 1,
The measurement sensor unit may include: a residual fine particle measurement unit for generating and outputting fine particle measurement data having a residual fine particle concentration after measuring the fine particles contained in the air discharged through the outdoor air intake space and the total heat exchange element; A heat recovery type ventilation device including a sound wave module device, characterized in that it comprises a. The method of claim 1,
The measurement sensor unit, after detecting the frequency and sound pressure of the low-frequency sound waves inside the outdoor air intake receiving space, a low-frequency sound wave measurement unit for transmitting to the control unit; Heat recovery comprising a sound wave module device, characterized in that it comprises a type ventilation. The method of claim 1,
The control unit, a storage unit for storing the frequency and sound pressure data for each fine particle contamination level for fine particle aggregation; Heat recovery type ventilation device including a sound wave module device, characterized in that it comprises a. The method of claim 1,
The frequency of the low-frequency sound waves is a heat recovery type ventilation device comprising a sound wave module device, characterized in that 20 Hz to 20 kHz. The method of claim 1,
The sound pressure of the low-frequency sound waves is a heat recovery type ventilation device including a sound wave module device, characterized in that 0 dB to 150 dB. The method of claim 1,
The control unit is
Sound wave module device, characterized in that it is configured to receive the frequency and sound pressure and residual fine particle measurement information of the low-frequency sound waves inside the outdoor air intake receiving space, and to adjust the frequency and sound pressure of the low-frequency sound sources by varying the frequency and sound pressure to output the low-frequency sound source feedback control adjustment A heat recovery ventilation system comprising a. delete The method of claim 1,
Heat recovery type ventilation device including a sound wave module device, characterized in that it further comprises;

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