KR101909176B1 - Radon adsorption filter and radon reduction apparatus inculding the filter - Google Patents

Abstract

A radon adsorption filter and a radon abatement device including the same are disclosed. The radon adsorption filter includes an activated carbon filter in which first activated carbon particles having a particle size of 1 um or less and second activated carbon particles having a larger particle size are mixed and the pores of the second activated carbon particles are filled with the first activated carbon particles. The radon abatement apparatus includes a harmful substance removing unit including a radon adsorption filter for adsorbing radon from the air sucked by the rotary fan, and a control unit for driving and controlling the rotary fan.

Description

[0001] The present invention relates to a radon adsorption filter including a radon adsorption filter,

The present invention relates to a radon abatement technique.

Radon, one of the radioactive materials, accounts for about 50% of the natural radiation dose per year. Radon is one of the natural radionuclides present in the natural environment, a colorless odorless inert gas that is formed by the collapse of uranium several times and is contained in rock, soil, or building materials. Radiation from the human body by radon is mostly inhaled from the air. These radon occur mainly in soil, rock, ground water, building materials (gypsum board, etc.) and LNG gas (liquefied natural gas) and flow into the indoor environment through cracks in building floors, basement walls, water pipes, do. In particular, the LNG gas contains 54 Bq / m ³ of radon, which is increased to more than 20000 Bq / m ³ (700,000 pCi / L) while undergoing the compression, cooling, , The radon-containing LNG gas flows into the indoor environment through the gas pipe through the supply pipe.

In addition, as the functionality of interior insulation materials, finishing materials, and eco-friendly building materials are maximized, the indoor environment has become highly airtight and deteriorated, contributing greatly to prevention of loss of cooling and heating energy. However, since the enclosed building is not ventilated, indoor air is prevented from being discharged to the outside, so that the radon contained in the room air can not escape to the outside, so the concentration of the radon contained in the room air is rising.

If a person breathed air that accumulated above the environmental standard for a long period of time, the high-energy alpha particles released during the alpha decay process of Po-214, Po-218, the decay products of the radon inhaled into the lungs of the human body, It also causes lung cancer by destroying lung basal cells. For reference, in the United States, approximately 19,000 people die each year from lung cancer caused by radon. The World Health Organization (WHO) and the US Environmental Protection Agency (EPA) are the main causes of lung cancer next to smoking. WHO recommends an indoor radon concentration of 2.7 pCi / L, The indoor radon concentration is recommended to be 4.0 pCi / L.

On the other hand, in Korean Patent Laid-Open Publication No. 10-2014-0044251, when a charcoal filter is mounted on a computer body and external air is introduced into the computer body when the air circulation function is performed by a cooling fan installed in the main body, A radon removal device is disclosed for allowing radon to be removed through a charcoal filter.

[Patent Document 1] Korean Patent Publication No. 10-2014-0044251 (published on April 14, 2014) [Patent Document 2] Korean Published Patent Application No. 10-2001-0103440 (published on Nov. 23, 2001)

Disclosure of Invention Technical Problem [8] The present invention provides a technical solution for improving the reduction rate of radon concentration contained in air.

It is another object of the present invention to provide a technical solution for efficiently using hardware resources for radon reduction.

It is another object of the present invention to provide a technical solution for grasping the replacement point of the activated carbon filter used for radon reduction.

The radon adsorption filter according to one aspect may include an activated carbon filter in which first activated carbon particles having a particle size of 1 um or less and second activated carbon particles having a larger particle size are mixed and the pores of the second activated carbon particles are filled with the first activated carbon particles .

The first activated carbon particles may be at most 50% of the mixed activated carbon.

The particle size of the second activated carbon particles can be up to 2 mm.

The radon adsorption filter may further include a conductor which conducts a negative charge to maintain the zeta potential of the mixed activated carbon located within a predetermined distance.

The conductor may be lattice-shaped.

According to an aspect of the present invention, there is provided a radon abatement apparatus comprising a harmful substance removing unit including a radon adsorption filter for adsorbing radon from air sucked by a rotary fan, and a control unit for driving and controlling the rotary fan. The first activated carbon particles and the second activated carbon particles having a larger particle size than the first activated carbon particles may be mixed with the activated carbon filter in which the pores of the second activated carbon particles are filled with the first activated carbon particles.

The control unit can variably control the rotational speed of the fan according to the measured concentration level of the radon.

The controller analyzes the performance of the radon adsorption filter and, if the analysis result is unsatisfactory, can notify the outside.

The controller can analyze the performance of the radon adsorption filter based on the change in the measured radon concentration after activating the radon abatement function for a certain period of time.

The disclosed radon adsorption filter improves the reduction of the concentration of radon contained in the room air. In addition, the zeta potential of the activated carbon can be maintained at '-', thereby continuing the radon adsorption performance of the activated carbon.

And the radon abatement device according to the disclosure enables efficient use of the fan driving motor by varying the speed of the rotating fan according to the radon concentration level. Also, by analyzing the performance of the radon adsorption filter and informing the user when replacement is necessary, the user can change the radon adsorption filter.

1 is a block diagram of a radon reduction apparatus in accordance with one embodiment.
2 is a reference diagram for explaining production of a radon adsorption filter.
3 is an exemplary view showing the zeta potential range of activated carbon.
4 is a table showing the parameters of the planetary mill for activated carbon.
5 is a table showing the conditions for product commercialization experiments.
FIG. 6 is a table showing the radon reduction rate by the manufacturer of activated carbon.
7 is a table showing average particle size of activated carbon produced using a planetary mill.
8 is a table showing the size distribution of the average activated carbon particle size.
9 is a table showing the radon reduction rate for each sample.
FIG. 10 is a table showing the reduction ratio of lardon gas according to the product commercialization experiment result.
11 is a graph showing the reduction of lagoongas according to the product commercialization experiment result.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a radon reduction apparatus in accordance with one embodiment. The radon abatement device serves to reduce the radon contained in the indoor air. Such a radon abatement device can be configured in an air purifier. As shown in FIG. 1, the radon abatement apparatus includes a harmful substance removing unit 100 and a control unit 200, and may further include a radon measuring unit 500. In addition, a fan driving unit 300 for sucking room air and a rotary fan 400 may basically be included.

The harmful material removing unit 100 includes a radon adsorption filter 110. The radon adsorption filter 110 includes an activated carbon filter 111 that adsorbs radon from the sucked air. The activated carbon filter 111 uses activated carbon as a filter for adsorbing radon and includes one or more activated carbon. The activated carbon is mixed with the first activated carbon particles and the second activated carbon particles having a larger particle size, so that at least some of the voids of the second activated carbon particles are filled with the first activated carbon particles. In this case, the effective surface area of the activated carbon particles is increased. Preferably, the particle size of the first activated carbon particles is less than or equal to 1 um, i. E., Up to 1 um. milling can be used to produce first activated carbon particles with a particle size of less than 1 um (including nanoparticles). The activated carbon filter 111 can be manufactured by mixing the prepared first activated carbon particles with second activated carbon particles having a larger particle size to fill the pores of the second activated carbon particles. The first activated carbon particles may be mixed at 30% to 40% of the weight of activated carbon, and at most 50% of the activated carbon may be mixed. And the particle size of the second activated carbon particles can be up to 2 mm. Considering that the particle size of the first activated carbon particles is at most 1 um, it may be 1 to 2 mm. Second Activated Carbon Particles Various sizes of particles can be mixed in the above range.

According to the activated carbon filter 111 formed by mixing the first activated carbon particles and the second activated carbon particles, the surface area of the activated carbon (1 kg) reaches about 400 m ² per 1 g, and the contact area of the air and the activated carbon is widened. And it can adsorb the radon prodrugs (Pb-218, Pb-214, Bi-214, etc.) contained in the air to greatly reduce the exposure by the radionuclides.

The radon adsorption filter 110 may include a conductor 112 in addition to the activated carbon filter 111. A negative charge is conducted to the conductor 112. Conducted negative charge plays a role in sustaining the zeta potential of activated carbon. For this purpose, the activated carbon of the conductor 112 and the activated carbon filter 111 are located within a predetermined distance. This is because the negative charge of the conductor 112 can influence the desired degree of zeta potential of the activated carbon. In one embodiment, the conductor 112 is lattice-shaped. When the conductor 112 is in the form of a lattice, as shown in FIG. 2, activated carbon is inserted into the grid holes formed between the grids of the conductor 112 to manufacture the radon adsorption filter 110.

The conductor 112 will be further described below. As shown in Fig. 3, the activated carbon particles of the activated carbon filter 111 have a negative electrode and a zeta potential around the activated carbon particle. In the case of activated carbon, '-' means that the zeta potential is capable of binding with the '+' ion radon prodrug, and the greater the zeta potential, the better the adsorption capacity of radon. However, when activated carbon is exposed to air, many positively charged particles are adsorbed on activated carbon pores. If this phenomenon continues, the zeta potential of the activated carbon becomes 0 and the adsorption performance is lost. In other words, the radon prodrugs captured on activated carbon are finally converted to Pb-210 and Pb-206 through half-life, and the efficiency of adsorbing the radon prodrug of activated carbon is time-consuming. In order to prevent this, when the negative charge is conducted to the conductor 112, the zeta potential of the activated carbon can be maintained to be '-' continuously.

Meanwhile, the harmful material removing unit 100 may further include a fine dust filter 120. The fine dust filter 120 may be a hepa filter. In one embodiment, the fine dust filter 120 is disposed on the rotating fan 400 side and the radon adsorption filter 110 is disposed behind the fine dust filter 120. In this case, the sucked air passes through the fine dust filter 120 and the fine dust is removed, and the radon is removed while passing through the radon absorbing filter 110.

Next, the controller 200 is a controller for controlling the entire apparatus, and may include at least one of a processor and an FPGA (Field Programmable Gate). The control unit 200 controls the fan driving unit 300 to rotate the rotating fan 400. [ Accordingly, the indoor air is sucked into the radon reduction device, and the radon contained in the sucked air is removed through the harmful material removing unit 100. The control unit 200 may also control the associated circuit so that a negative charge is conducted to the conductor 112 of the radon adsorption filter 110.

The controller 200 controls the rotation speed of the rotary fan 400 according to the level of the measured radon concentration. For example, when the radon concentration is less than the reference value, the control unit 200 does not drive the rotating fan 400 or drives the rotating fan 400 at the lowest speed. When the radon concentration is higher than the reference value, Increase speed. Also, even when the radon concentration is higher than the reference value, the controller 200 can increase or decrease the speed of the rotary fan 400 according to the concentration level. That is, when the radon concentration level is high, the speed of the rotating fan 400 is increased, and when the radon concentration level is low, the speed of the rotating fan 400 is also low. To this end, the rotational speed information for each radon concentration level may be stored in memory in advance. The control unit 200 checks the rotation speed information corresponding to the measured radon concentration level in the memory and controls the fan driving unit 300 so that the rotation fan 400 rotates according to the determined rotation speed information.

The radon abatement apparatus includes at least one of a radon measuring unit 500 and a radon concentration receiving unit 600. The radon measuring unit 500 measures the concentration of radon contained in the indoor air. The technique of measuring the radon concentration itself is well known, and a description thereof will be omitted. The radon concentration receiver 600 is a communication module for receiving data measured by the radon meter, which is a device separate from the radon reduction device. The radon concentration receiver 600 may be a wired receiver or a wireless receiver. The communication method is not particularly limited. The control unit 200 variably controls the rotation speed of the rotary fan 400 according to the measurement data of the radon measuring unit 500 and the measurement data received through the radon concentration receiving unit 600 as described above.

According to a further aspect, the controller 200 analyzes the performance of the radon adsorption filter 110, and alerts the user through the alarm unit 700 when the analysis result shows that the performance is unsatisfactory. In one embodiment, the controller 200 activates the radon abatement function and analyzes the performance of the radon adsorption filter 110 based on the change in the concentration of radon measured after a certain period of time. For example, when the measured radon concentration (first measured value) is equal to or higher than the reference value, the controller 200 activates the radon abatement function, that is, controls the fan driving unit 300 to operate the unrotated rotary fan 400 And increases the rotational speed of the rotating fan 400 in operation. If the concentration of the radon measured after a certain time from the activation point (second measured value) is not different from the first measured value or is still higher than the reference value (for example, 4.0 pCi / L) It is determined that the lifetime of the battery 110 has expired and the user is informed through the alarm unit 700 that replacement is required. In another embodiment, the control unit 200 checks the use time from the point of time when the radon absorption filter 110 is replaced, and if it exceeds the predetermined recommended use time, the user needs to replace the user through the alarm unit 700 It informs. For reference, the alarm unit 700 may include visual and / or audible alarm means, and the visual alarm means may be an LED.

Hereinafter, experiments and results of the radon reduction effect of the activated carbon filter will be described. The Applicant has examined the possibility of using ladon gass (including radon daunase, hereinafter referred to as radon gass) reduction of activated carbon on the basis of the physical performance and chemical performance of activated carbon, and confirmed the possibility of commercialized product.

⑴ Experimental method

① Radon chamber configuration

The radon chamber is a circulatory system. Air in the chamber was injected into the radon source through the motor pump, and 4 to 5 L of radon gas was supplied into the chamber. The radon source used was Pylon ²²⁶ Ra (0.1919 kBq, Model RNC), and the radon measurement was done with RAD7 at 1 hour intervals. The london gas was tested at 6 pCi / L to 12 pCi / L, and the chamber capacity was 216 L (about 200 L). The amount of activated carbon used in the experiment was 100g, and the amount of activated carbon to be used as the product was increased by a certain amount.

② Measurement of activated carbon radon reduction by activated carbon manufacturer

The main test activated carbon was purchased from Carbon Tech, and the Brunauer-Emmett-Teller equation (BET) was comparatively superior to the product sold in the market of 980 m ² / g and 1,500 m ² / g. Other products were purchased mainly through companies selling activated carbon products via the Internet. The degree of radon reduction of activated carbon products of six companies was measured.

③ Measurement of activated carbon radon reduction by oil mill

It is expected that the physical properties will vary depending on the undifferentiation of the activated carbon particles. Thus, a total of 11 kinds of activated carbon were pulverized by using HPM-502 planetary ball mill of HYPENGENE as shown in Table 4. The initial radon concentration was 6 pCi / L to 12 pCi / L, and the radon reduction experiment of each activated carbon was performed for 12 to 24 hours.

④ Product commercialization experiment

In order to test the radon abatement ability of activated carbon for product commercialization, a radon abatement experiment was carried out by placing it in a container of water-eating hippopotamus under the conditions shown in Table 5. A mixture of activated charcoal (ACG), activated charcoal (AC) and synthetic zeolite (SZ) was mixed at a constant rate and heat treated at 150 ℃ for 2 hours. The initial radon concentration was set at 11 pCi / L to 12 pCi / L, 24 hours at Group 1, and 48 hours at Group 2.

For reference, the lock & lock barrel is about 19L, and it is selected to fit only the water-eating hippopotamus container. In order to prevent the radon gas from passing through the water hippocampus when the radon is injected into the chamber, it was tested to the extent that it would not affect the overall chamber capacity by using the same product as the size of the hippocampus.

⑵ Experimental Results and Considerations

① Radon reduction rate by activated carbon manufacturer is shown in the table of Fig.

The reduction rate of the radon is the highest at 76.5% C, followed by 71.8%, while the remaining companies show a 30-60% reduction. For reference, Company A and Company F directly produce activated carbon, and the rest were purchased as commercial products by purchasing activated carbon from other companies. In other words, some of the companies that manufacture activated carbon in Korea are mostly purchased from activated carbon manufacturers and commercialize them.

② Size and radon reduction results of activated carbon particles pulverized by oil mill

Since the atomic size of ladon gas and its daughter nuclide is less than 2 nm (20 Å), it is considered that micro and meso pores will be exposed to more radon particles in the air when micro pore size pores are ground. Of nanoparticles of fine or nm size were prepared. The sizes of the average activated carbon particles produced using the planetary mill are shown in the table of Fig. From the results of # 7 and # 11, it can be seen that the average particle size decreases with increasing time at the same RPM. In the table of FIG. 7, '-' indicates that the test result is not completed and the result value is not entered.

The size distribution of the average activated carbon particle size is shown in the table of FIG. The average particle size distribution was varied, and # 10 and # 11 were found to be less than 1 μm in size within 10%. And the table in FIG. 9 shows the radon reduction rate for each sample. It was found that the radon reduction rate was almost the same regardless of BET. There is also a slight difference in radon reduction rate depending on the operating time of the planetary mill and the RPM.

③ Product commercialization experiment result

FIGS. 10 and 11 show the results of reducing the lardon gas and the reduction graph. Group 1 (Group 1) used the permeable membrane as the permeable membrane. Fig. 10 shows the results of measurement for 24 hours except for No.06, showing a reduction rate of 60% to 65%. On the other hand, No.06 was measured for 48 hours, and the reduction rate of about 75% was increased by about 10% than that of No.01 ~ 05. Although not shown in Fig. 10, the reduction rate is 61.6% by the 24th hour of No. 06. In the case of Group 2, the nonwoven fabric was used as a nonwoven fabric. As a result of measurement except for No.04, the reduction rate was 80% ~ 82%. No.03 is being experimented, and it is judged that the prediction result is the same as the remaining samples.

11 is a graph showing the radon reduction results of the product samples of the group 1 and the group 2. When we used group 2 nonwoven fabric, the radon reduction progressed a little faster than the group 1 moisture permeation net. However, this is only the difference in radon abatement rate (numerical), and overall evaluation shows almost similar radon abatement rates in both the breathable mesh and the nonwoven fabric. No.04 of group 2 showed a radon reduction of more than 90% as a result of measurement up to 92 hours. And the half-life of radon is 91.2 hours (3.8 days), it can be understood that the result is a reduction result due to the adsorption performance of activated carbon.

In summary, the efficiency of radon reduction was found to be 86.3% using planetary wheat, and it was confirmed that the radon reduction efficiency was increased by 10% compared with the conventional one. In commercial commercialization experiments, the average radon reduction effect was 80%.

The present invention has been described with reference to the preferred embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

100: Removal of harmful substances 110: Radon adsorption filter
111: activated carbon filter 112: conductor
120: fine dust filter 200:
300: fan driving part 400: rotating fan
500: Radon measuring unit 600: Radon concentration receiving unit
700: Alarm section

Claims (11)

A harmful substance remover comprising a radon adsorption filter for adsorbing radon from the air sucked by the rotating fan; And
And a control unit for driving and controlling the rotary fan,
The radon adsorption filter includes an activated carbon filter in which first activated carbon particles having a particle size of 1 um or less and second activated carbon particles having a larger particle size are mixed and the pores of the second activated carbon particles are filled with the first activated carbon particles,
Wherein the controller analyzes the performance of the radon adsorption filter and informs the outside of the performance when the analysis results indicate that the radon adsorption filter is out of performance. A harmful substance remover comprising a radon adsorption filter for adsorbing radon from the air sucked by the rotating fan; And
And a control unit for driving and controlling the rotary fan,
The radon adsorption filter includes an activated carbon filter in which first activated carbon particles having a particle size of 1 um or less and second activated carbon particles having a larger particle size are mixed and the pores of the second activated carbon particles are filled with the first activated carbon particles,
Wherein the control unit comprises a radon adsorption filter for analyzing the performance of the radon adsorption filter based on a change in the concentration of the radon after the activation of the radon abatement function for a predetermined time or more. 3. The method according to claim 1 or 2,
Wherein the control unit comprises a radon adsorption filter for variably controlling the rotation speed of the fan according to the measured concentration level of radon. 3. The method according to claim 1 or 2,
Wherein the first activated carbon particles comprise a radon adsorption filter of at most 50% by weight of the mixed activated carbon. 3. The method according to claim 1 or 2,
The radon adsorption filter comprises:
A conductor that conducts a negative charge to maintain the zeta potential of the mixed activated carbon located within a predetermined distance;
Further comprising a radon adsorption filter. delete delete delete delete delete delete

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