JP2005254043A - Removal method and apparatus for gaseous substance contained in gas - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a novel gas removal method removing a gas containing a gaseous substance to be treated contained in the gas by contacting the gas containing the gaseous substance to be treated with a mist-like treating liquid, and an apparatus therefor. <P>SOLUTION: The method absorbs/removes the gaseous substance by contacting the gas containing the gaseous substance to be absorbed/removed with the liquid for absorbing the gaseous substance. The method and the apparatus for absorbing/removing the gaseous substance by contacting the gas containing the gaseous substance to be absorbed/removed with the liquid for absorbing the gaseous substance is characterized in that, while ultrasonic vibration by a vibration plate is imparted to the gas and the liquid in the state that the liquid exists in the mist shape, the gaseous substance is absorbed/removed by the liquid by contacting both gas containing the gaseous substance and liquid for absorbing the gas. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a method and apparatus for removing a gaseous substance contained in a gas.

The method for removing undesired gas contained in the gas is the gas refining process required in the energy industry such as various refining industries including iron making, thermal power generation, nuclear power generation, and gas supply business, and purification in the chemical manufacturing industry. It is used in many fields such as processes, combustion gas purification technology, cooling equipment cooling facilities, and air purification technology in buildings. In these methods, various measures are taken in each field, but the basic operation is to bring a processing gas containing a gas to be removed into contact with the liquid for absorbing the gas, and into the liquid. It is gas-liquid contact that tries to take in gas.
This operation is an ideal method because when the gas and the liquid are brought into contact with each other, the conditions can be freely selected by setting the type and amount of the liquid and the temperature conditions.
However, this operation requires a large amount of liquid to be used, requires a liquid regeneration process by treating the liquid after absorbing the gas, and increases the size of the equipment and the energy cost required for it. Therefore, there is a problem in that much labor is required for maintenance.
In this method, it is important to reduce the amount of liquid and bring the gas and liquid into good contact with each other to absorb the gaseous substance to be removed. If the amount of liquid can be reduced, a means for contacting the gas and the liquid and a small scale of the liquid regeneration process can be achieved.
In view of this point, the present inventors have considered that the liquid to be brought into contact is not simply supplied as a liquid, but in the form of water droplets, and the water droplets and gas are brought into contact with each other. As a specific means for this purpose, water is scattered on the bottom surface of the gas removal device by irradiating it with airborne ultrasonic waves, and the gas contained in the gas is absorbed and removed by the water droplets. Invented a method to do this (Non-Patent Document 1). Conventionally, in a dehumidifier or the like, it has been performed that an ultrasonic wave generating means is installed in water and a mist-like liquid is generated by its action. However, in this case, the mist liquid is not used for gas adsorption. Further, in order to vaporize when supplying the liquid material, ultrasonic vibration is applied to the liquid material (Patent Document 1), which is also intended to perform heating and vaporization, and gas adsorption. Not intended. A mist-like liquid is generated as seen in supplying perfume to the vibrating surface (Patent Document 2), chemical spraying (Patent Document 3), using mist-like materials for analysis of raw water (Patent Document 4), etc. Many ideas are made to make it happen, but this does not cause gas adsorption. Compared with these, the method of the inventors is unique in that water, which is liquid, is put on the bottom surface and water droplets are scattered by irradiating the water with airborne ultrasonic waves through the space. It attracted attention as it was. Certainly, although this method can be said to be unique as a means for generating water droplets, the generated mist-like water droplets act on the gas to be treated, as in the conventional method. That is not intended. Therefore, there is no idea of creating a good gas-liquid contact state with the generated liquid substance and the gas to be treated, and there is no consideration to sufficiently absorb the gas to be removed. It was a problem.
When the present inventors make gas-liquid contact with the gas to be treated with the mist-like liquid, it is important to maintain a good contact state and absorb and remove the gas from the gas to be treated. I have been thinking about these specific measures.

Japanese Patent Laid-Open No. 10-317144 Japanese Patent Laid-Open No. 10-85314 Japanese Patent Laid-Open No. 2001-149833 JP-A-2003-57153 Proceedings of the Acoustical Society of Japan p.1055-1056 (1997.3).

  An object of the present invention is to bring a gas containing a gaseous substance to be treated into contact with a mist-like liquid to be treated. It is an object of the present invention to provide a novel gas removal method and apparatus for removal.

The present inventors diligently investigated the above problems and found the following matters.
A good contact state can be maintained if the mist consisting of the liquid to be treated and the gas containing the gas to be removed are brought into contact with each other while being subjected to ultrasonic vibration by the diaphragm. It was found that it can be absorbed. In addition, when a liquid is supplied from the upper part of the diaphragm to a diaphragm that is vibrated by vibration generating means such as a vibrator, the liquid can be atomized by the action of the diaphragm, and a liquid mist is formed on the upper part of the diaphragm. Can be generated. Although the gas to be treated exists on the surface of the diaphragm, the vibration of the diaphragm can be transmitted to the liquid and the gas. Sound waves can be applied directly. As a result, the gaseous substance contained in a state where various liquids are vaporized comes into contact with the mist, and the gaseous substance to be treated can be taken into the mist.
In light of this, a new gas removal method for removing the gaseous substance to be treated contained in the gas by bringing the gas containing the gaseous substance to be treated into contact with the mist-like liquid to be treated, and It came to invent the device.

According to the present invention, the following inventions are provided.
(1) In a method of absorbing and removing the gaseous substance by bringing a gas containing the gaseous substance to be absorbed and removed into contact with a liquid that absorbs the gaseous substance, the liquid is present in a mist state. The gas and the liquid are brought into contact with the liquid containing the gaseous substance, and the liquid that absorbs the gas is brought into contact with the liquid while the ultrasonic vibration is applied to the gas and the liquid. A method of absorbing and removing the gaseous substance by bringing the gas containing the gaseous substance to be absorbed and removed into contact with a liquid that absorbs the gaseous substance.
(2) The gas containing the gaseous substance to be absorbed and removed includes a fine powdery solid substance, and the gas containing the gaseous substance to be absorbed and removed as described in (1) A method of absorbing and removing the gaseous substance by contacting the liquid to be absorbed.
(3) The state in which the liquid is present in a mist state is that the liquid that absorbs the gaseous substance is a mist-like liquid generated by ultrasonic vibration using a vibration plate. A method of absorbing and removing the gaseous substance by bringing a gas containing the gaseous substance to be absorbed and removed into contact with a liquid that absorbs the gaseous substance.
(4) In a device that absorbs and removes the gaseous substance by bringing a gas containing the gaseous substance to be absorbed and removed into contact with a liquid that absorbs the gaseous substance, the space in which the liquid exists in a mist form; A diaphragm for applying ultrasonic vibration to the gas and liquid below the space, a means for supplying a gas containing a gaseous substance to be absorbed and removed, a gas discharging means for absorbing and removing the gaseous substance, and a gaseous substance An apparatus for absorbing and removing the gaseous substance by bringing the gas containing the gaseous substance to be absorbed and removed into contact with the liquid that absorbs the gaseous substance, characterized in that the apparatus has a means for discharging the liquid that has absorbed the gaseous substance.
(5) The gas containing the gaseous substance to be absorbed and removed includes a fine powdery solid substance in the gas containing the gaseous substance to be absorbed and removed. An apparatus that absorbs and removes the gaseous substance by contacting the liquid to be absorbed.
(6) The liquid supply means that absorbs the gaseous substance in the upper part of the space where the liquid exists in a mist form can supply the liquid supplied from the liquid supply means that absorbs the gaseous substance to the diaphragm. The gas containing the gaseous substance to be absorbed and removed is brought into contact with the liquid that absorbs the gaseous substance according to claim 4, wherein the liquid is generated in the form of a mist by the vibration of the diaphragm. An apparatus for absorbing and removing the gaseous substance.

According to the present invention, a trace amount of a gaseous substance contained in a gas can be taken into the liquid by applying ultrasonic vibration to the gas to be processed while the liquid to be processed is atomized. Can do.
Further, according to the present invention, the liquid to be processed is made to exist in a state where the liquid is atomized by using the vibration plate, and the ultrasonic vibration is applied to the gas to be processed and the liquid to be processed. By acting, a trace amount of gaseous substances contained in the gas can be taken into the liquid.
As a result, gaseous substances and odorous substances can be removed. Further, when a finely divided solid substance is included, it can be similarly treated and removed.

The contents of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing the contents of the present invention.
Reference numeral 1 denotes a processing facility (processing container) including a water droplet forming unit that applies vibration to a liquid to form water droplets, and a space for contacting the water droplets and gas.
The processing facility 1 includes a space 5 for supplying the liquid from the gas supply means 2 and the liquid supply means 4 to be processed downward and bringing the gas to be processed into contact with the generated mist liquid. Further, below the space portion 5, there is provided a vibration plate 3 that receives liquid from the liquid supply means 4 and generates a mist-like liquid. The vibration plate 3 and the liquid supply means 4 are sandwiched between A lower reflector 11 is provided. Further, the treated gas is discharged from the gas discharge means 6. The gas discharge means 6 is provided with analysis means 7 for analyzing how much the gaseous substance to be removed from the treated gas has been removed. The liquid that has absorbed the gas contained in the gas is taken out from the liquid discharging means 12.
The vibration generation amplification transmission means 13 includes a vibrator 8, a vibration expansion means 9 and a resonance transmission means 10, and vibrations generated by the means are transmitted to the vibration plate 3 to vibrate the vibration plate 3. The diaphragm 3 atomizes the liquid supplied from the supply unit 4 by vibration and sends it to the space 5. At the same time, since the diaphragm 3 is formed with a standing wave sound field using ultrasonic waves in the space portion 5 for contacting the gas to be processed and the generated mist liquid, the standing wave sound field using the ultrasonic waves is formed. Is preferable for the contact between the gas and the liquid.

The gas supply means 2 supplies a gas containing the gas to be removed to the processing facility, and includes pipes for supplying the gas to be removed, pumps and valves for supply, and meters such as a flow meter. In addition, the gas to be supplied can be adjusted.
In the description of the present invention, since ethanol vapor was selected as a model gas for treatment removal, 10 [ml] ethanol (manufactured by Wako Pure Chemical Industries, Ltd., purity 99.5) was fed into a container in the gas generation unit in order to send the gas. %) And air was blown with a fan so that ethanol was vaporized (air volume 92 [cm ³ / s]). At the start of vaporization, the rate of ethanol vaporization was not stable, so the time for which this rate was almost constant was left for 5 [min] for use. Note that the gas to be treated may be an organic or inorganic substance. If these gases have an odor, the odorous substance is absorbed and removed. The gas may contain dust or pollen. Such undesirable particulate solids can be removed as well.

  The liquid supply means 4 is a means for supplying a liquid to the processing apparatus 1 and supplies a liquid to be brought into contact with a gas, and measures a pipe, a pump and a valve for transportation, a flow velocity, and the like. It includes a device and the like, and has a branch pipe as a distribution means and a supply port at its distal end. In the present invention, means for distributing and supplying the liquid to a specific site is provided. This specific part is set so as to correspond to the most effective position by giving vibration to the liquid by the vibration of the diaphragm 3. this is. It is determined by the vibration frequency given by the diaphragm, and usually corresponds to the antinode portion of the vibration of the diaphragm. These are set in advance based on the measurement results. The liquid to be supplied may be any liquid that can absorb the gas contained in the gas, and water and various solvents can be used.

A space 5 exists between the liquid supply means 4 and the diaphragm 3 below the supply port for sending out the liquid. The liquid falls in a state of falling from the supply port in the space portion 5. In addition, this space also becomes an important place for the gas to be processed to come into contact with the generated mist liquid described later and the gas to be processed. A standing wave sound field is formed in the space 5 by the ultrasonic waves from the diaphragm 3.

The diaphragm 3 atomizes the liquid by vibration and forms the standing wave sound field. In short, any device that can vibrate by vibrations transmitted by the action of the vibrator may be used. In a specific example of the present invention, a lattice mode square flexible diaphragm (length of one side 217 [mm], thickness 3 [mm], made of duralumin) is screwed. The resonance frequency of the sound source was 19.74 [kHz].

In order to form a standing wave sound field in the processing apparatus 1, a flat reflector is installed on both sides of a diaphragm as a sound source, a lower diaphragm 11 is installed under the diaphragm, and an upper reflector 11 of the liquid supply means is installed. It is installed. The interval between them can be determined as appropriate. In the specific example of the present invention, the distance between the upper reflector and the lower reflector was 42 [mm] and 14 [mm], respectively.

The gas discharge means 11 is a means for taking out the processed gas from the processing apparatus and releasing the purified gas. Measuring means for measuring a pump, a valve, a flow rate, and the like are provided to discharge gas. In order to confirm whether or not the gas to be absorbed and removed is properly removed, a gas analyzing means 7 is provided. For this, a gas detection sensor is used.

A collecting means is provided so that the liquid that has absorbed the gas contained in the gas is collected at the bottom of the processing apparatus. These are collected and taken out from the liquid discharging means 12.

The vibration generation amplification transmission means 13 includes a vibrator 8, a vibration expansion means 9, and a resonance transmission means 10. The vibrator 8 transmits vibration to the diaphragm so that vibration can be generated. In a specific example of the present invention, any material that can generate a vibration of about 10 to 100 [kHz] can be used as appropriate. In the present invention, a bolt-clamped Langevin type vibrator for 20 [kHz] (Japan Special Ceramics Co., Ltd., type D45520) is employed.
The vibration enlarging means 9 is a means for enlarging vibration, and a horn is used. The amplitude width may be appropriately determined. In the present invention, an exponential horn (thick end face 70 [mm], thin end face 10 [mm], length 150 [mm], duralumin) made by duralumin) having an amplitude expansion ratio of 7.5 times is used. Using. Furthermore, the resonance transmission means 10 is connected to the tip. In the present invention, a half-wavelength longitudinal resonance round bar (diameter 10 [mm], length 116 [mm], made of duralumin) is used. And the diaphragm 3 is being fixed to this point.

The gas removal method using this apparatus is as follows.
A gas containing gas to be removed is supplied into the processing facility 1 by the gas supply means 2. In the present invention, 10 [ml] ethanol (manufactured by Wako Pure Chemical Industries, Ltd., purity 99.5%) is placed in a container in the gas generation section, and blown with a fan so that the ethanol is vaporized (air volume 92 [cm ³ / s]). Since the rate of ethanol vaporization was not stable at the start of vaporization, it was left for 5 [min] as the time for this rate to be almost constant.
Next, the liquid is supplied from the supply port of the liquid supply means 4, and the liquid is supplied to the diaphragm 3. As a result, the atomized liquid is generated and supplied to the space, and the gas containing the gas to be removed comes into contact with the liquid. Due to the action of the diaphragm 3, the diaphragm 3 is made to stand by ultrasonic waves with respect to the gas and the mist liquid present in the space 5 for contacting the gas to be processed and the generated mist liquid. A wave field is formed, and this ultrasonic wave has a favorable effect on the contact between the gas and the liquid, and the gas is absorbed into the liquid. In the specific example of the present invention, it was drained as ethanol water. As a gas gas sensor after passing through the removal facility, a portable gas sensor (manufactured by Shin Cosmos Electric Co., Ltd., XP-329) was used as a measurement sensor for ethanol gas, and a numerical value corresponding to the gas concentration was recorded. Note that the gas sensor used for the measurement does not measure the gas concentration of the specific substance, but quantifies the strength of the odor in the measurement space with respect to a certain reference value.

The sound source installed in the removal device is a bolt-clamped Langevin type vibrator (Japan Special Ceramics Co., Ltd., model D45520) for 20 [kHz], an exponential horn (thick end face 70 [mm], 7.5 times the amplitude expansion ratio), Narrow end face 10 [mm], length 150 [mm], made by duralumin), half-wavelength longitudinal resonance round bar (diameter 10 [mm], length 116 [mm], made by duralumin) is attached, and lattice mode square is attached to the tip A flexible diaphragm (length of one side 217 [mm], thickness 3 [mm], made of duralumin) is screwed. The resonance frequency of the sound source is 19.74 [kHz]. In addition, in order to form a standing wave sound field in the removal device, plane reflectors were installed on both sides of the diaphragm of the sound source, and the distance between the upper reflector and the lower reflector was 42 [mm] and 14 [mm], respectively. .

Next, the experimental method will be described. First, in order to send the gas into the removal device, 10 [ml] ethanol (Wako Pure Chemical Industries, Ltd., purity 99.5%) is put into a container in the gas generation unit, and blown with a fan so that the ethanol is vaporized. (Air volume 92 [cm ³ / s]). Since the rate of ethanol vaporization was not stable at the start of vaporization, it was left for 5 [min] as the time for this rate to be almost constant. After this, electric input is applied to the sound source with an elapsed time of 0 [s], and airborne ultrasonic waves are generated. At the same time, water was dripped onto the diaphragm from a thin tube installed on the upper reflector, and water fog was generated by vibration. Adsorption of ethanol gas was increased by increasing the chance of contact between water fog generated by airborne ultrasonic waves and ethanol gas.

The results were as follows.
In order to see the effect of removing ethanol gas, the gas concentration with respect to the elapsed time was determined for the presence or absence of electrical input to the vibrator (0,50 [W]) and the presence or absence of water (0,75 [cm ³ / min]). It was measured.
The result is shown in FIG. In the figure, the vertical axis represents the gas sensor instruction value indicating the ethanol gas concentration, and the horizontal axis represents the elapsed time. According to FIG. 2, when the electric input was 0 [W] or when the amount of water supplied for atomization was 0 [cm ³ / min], the gas sensor indicated value hardly changed over time. However, when the electrical input is 50 [W] and the supply water volume is 75 [cm ³ / min], the gas sensor reading decreases rapidly until the elapsed time is about 30 [s], and gradually after 30 [s]. There is a tendency to decrease. Therefore, it was found that the removal of ethanol gas can be effected by water fog and airborne ultrasonic waves.
Next, in order to examine the effect of removing ethanol and the amount of water supplied for atomization, the relationship between the amount of water supplied and the indicated value of the gas sensor at the elapsed time of 180 [s] was obtained. The results are shown in FIG. In the figure, the vertical axis represents the indicated value of the gas sensor, the horizontal axis represents the amount of supplied water, and the electrical input is a parameter. From the figure, it can be seen that the effect of removing ethanol is not seen when the electrical input is 0 [W], but when the electrical input is added, the greater the amount of water supplied at any input, the greater.
Furthermore, the results in Fig. 3 were redrawn to see the relationship between the electrical input and the ethanol removal effect. The results are shown in FIG. In the figure, the indicated value of the gas sensor is plotted on the vertical axis, the electrical input is plotted on the horizontal axis, and the amount of water supplied is a parameter. From the figure, it can be seen that the removal of ethanol gas has a large effect until the electric input is about 20 [W], but the effect hardly changes when the electric input exceeds 20 [W].
Here, ethanol is used as an example of the gas to be removed, and the investigation of the gas removal promotion effect when the water mist generated by the diaphragm is made to act on the water mist to cause the water mist to adsorb the gas. went. As a result, it was found that the larger the amount of water supplied for atomization, the greater the effect of removal, and it was found that a larger amount of water should be supplied in order to efficiently remove gas into water.

The figure which shows the outline of the present invention Diagram showing the removal effect of ethanol gas Diagram showing the relationship between the amount of water supply and the effect of removing ethanol gas Diagram showing the effect of electrical input and ethanol gas removal

Explanation of symbols

1 Processing equipment (processing vessel) consisting of water droplet forming means that vibrates liquid to form water droplets, and a space for contacting water droplets and gas
2 Gas supply means 3 to be treated 3 Diaphragm 4 Absorbing liquid supply means 5 Space for supplying liquid to the lower part and bringing the gas to be treated into contact with the generated mist liquid 6 Gas discharge means 7 Treatment Analyzing means 8 for analyzing how much the gaseous substance to be removed from the generated gas has been removed 8 vibrator 9 vibration expanding means 10 resonance transmitting means 11 reflecting plate 12 liquid discharging means 13 vibration generating amplification transmitting means

Claims (6)

  In the method of absorbing and removing the gaseous substance by bringing a gas containing the gaseous substance to be absorbed and removed into contact with a liquid that absorbs the gaseous substance, the gas in a state where the liquid exists in a mist form. The liquid containing the gaseous substance, which is brought into contact with the liquid while being subjected to ultrasonic vibration by the vibration plate, and the liquid that absorbs the gas, and the gaseous substance is absorbed and removed by the liquid A method of absorbing and removing the gaseous substance by bringing a gas containing the gaseous substance to be absorbed and removed into contact with a liquid that absorbs the gaseous substance.   The gas containing the gaseous substance to be absorbed and removed and the liquid that absorbs the gaseous substance according to claim 1, wherein the gas containing the gaseous substance to be absorbed and removed contains a fine powdery solid substance. A method of absorbing and removing the gaseous substance by contacting the substrate.   The absorption removal according to claim 1, wherein the state in which the liquid is present in a mist form is due to the mist-like liquid generated by ultrasonic vibration of the diaphragm for the liquid that absorbs the gaseous substance. A method of absorbing and removing the gaseous substance by bringing a gas containing the gaseous substance to be in contact with a liquid that absorbs the gaseous substance.   In an apparatus for absorbing and removing the gaseous substance by contacting a gas containing the gaseous substance to be absorbed and removed with a liquid that absorbs the gaseous substance, the space part in which the liquid exists in a mist form, A vibration plate for applying ultrasonic vibration to the gas and liquid at the bottom, means for supplying a gas containing gaseous substances to be absorbed and removed, gas discharging means for absorbing and removing gaseous substances, and absorbing gaseous substances An apparatus for absorbing and removing the gaseous substance by bringing it into contact with a gas containing the gaseous substance to be absorbed and removed and a liquid that absorbs the gaseous substance, characterized by having a liquid discharging means.   5. The gas containing a gaseous substance to be absorbed and removed and the liquid that absorbs the gaseous substance according to claim 4, wherein the gas containing the gaseous substance to be absorbed and removed contains a fine powdery solid substance. An apparatus for absorbing and removing the gaseous substance by bringing the gas into contact with each other. The liquid supply means for absorbing the gaseous substance is disposed above the space where the liquid is present in the form of a mist so that the liquid supplied from the liquid supply means for absorbing the gaseous substance can be supplied to the diaphragm. The liquid containing the gaseous substance to be absorbed and removed is brought into contact with the liquid that absorbs the gaseous substance by contacting the gaseous substance with the gaseous substance. A device that absorbs and removes substances.

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