JP2005140012A - Exhaust emission control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an exhaust emission control device for intensively and efficiently controlling exhaust emissions and intensively collecting reactants produced after emission control, while minimizing part replacing work for long time operation. <P>SOLUTION: The exhaust emission control device comprises an emission control device body for trapping high temperature exhaust gas and an exhaust flow path through which the gas is exhausted to the outside of the emission control device. The emission control device body is partitioned into upper and lower side sections with a partition wall. In the lower side section, an exhaust gas introduction port and a tank for storing exhaust gas control functioning solution are provided. A filter part is arranged on the upper face of the tank. The upper side section is communicated with the lower side section via an opening portion formed in the partition wall and also communicated with the exhaust flow path in which a dust collector is provided. The functioning solution, the opening portion of the partition wall and the dust collector are arranged in one line in the axial direction of the tank, and a waste water drain port is connected to the bottom of the tank. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an internal combustion engine using light oil as a fuel, such as a diesel engine, and more particularly to an exhaust gas purification device.

Internal combustion engines that use diesel oil as fuel, such as diesel engines, are solid components (Diesel Exhaust Particulate: DEP), organic compounds (Vaporized Organic Compound: VOC), inorganic compounds, NOx (NO, NO ₂ ), SOx (SO ₂ , SO ₃ ), CO, CO ₂ and other gaseous components are discharged. In recent years, it has been reported that DEP itself is a highly biohazardous substance, and has attracted attention.
NOx and SOx have already been identified as causative substances such as acid rain. Since NOx may cause biological damage when inhaled by humans, the emission amount is set within environmental standards.

  DEP is a soot-like substance produced in the process of burning light oil in an internal combustion engine, and is reported to be fine particles having a size of 2.5 μm or less. These fine particles can be said to be composite compounds in which a part of VOC, NOx, and SOx is adsorbed on the surface. And since DEP is a fine particle, it is said that it is taken into the body by breathing and penetrates deep into the oral cavity and lung cells, causing inflammation and damage.

  In particular, it has been reported that free radicals are produced in the process of elution of VOC, NOx, and SOx in tissues, resulting in biological disorders, for example, respiratory diseases, allergies, and reproductive functions. Therefore, in Japan, some local governments such as the Tokyo Metropolitan Government have set a regulation value for diesel engine vehicle exhaust gas from October 2003, and the diesel vehicles that do not pass the regulation value. The approach is to be regulated.

  Under such circumstances, development of a DEP removal device: Diesel Particular Filter (DPF) is underway. The DPF currently under development can be roughly divided into two types. One is a method in which DEP is collected with a ceramic filter, a certain amount of DEP is collected, and then incinerated and decomposed at a high temperature. While ceramic filters are arranged side by side, one of them is incinerated and decomposed. The other is a parallel processing system that collects.

The other method is an oxidation catalyst method that converts NO in the exhaust gas to NO ₂ and uses this to directly oxidatively decompose DEP. This method is characterized in that the mechanism is simple and can be manufactured at low cost. However, since the oxidation catalyst is deteriorated, the catalyst replacement cost is incurred if it is operated for a certain period of time.

  DPFs using the ceramic method and oxidation catalyst method have advantages and disadvantages, and the current situation is that they are not decisive for preventing environmental pollution caused by exhaust gas from diesel vehicles. A ceramic filter type DPF has a structure in which two filters are provided as described above, and the other one is thermally decomposed while one filter is collected. Since the collected DEP is burned and decomposed at a high temperature of 800 ° C. or higher, it is necessary to incorporate two series of ceramics and a combustion furnace, and the apparatus becomes more expensive. Further, technically, since the filter temperature, which is normal temperature when not in use, becomes 800 ° C. or higher during operation, it is necessary to overcome durability such as deformation and breakage of the ceramic due to temperature difference.

  On the other hand, in the oxidation catalyst system, there is a problem that the catalyst that promotes the oxidation of NO advances the oxidation of SOx that is the same exhaust gas component, resulting in a decrease in the catalyst function. As a countermeasure, when using an oxidation catalyst system, it is necessary to use low sulfur gas oil. In Tokyo and other countries, efforts are being made to spread low-sulfur diesel oil. As a problem of the oxidation catalyst system, when exhausted by an old engine, the exhausted DEP has a high concentration. Therefore, at present, this method is adopted from a new type of vehicle. Therefore, this method is not a problem solving means for application to old-type vehicles, which are said to be 3 million or 5 million.

Patent Documents 1 and 2 propose wet exhaust gas purification methods and apparatuses that do not depend on the above two methods.
The exhaust gas purification device of Patent Document 1 creates an exhaust gas flow in a container that stores an exhaust gas-absorbing chemical solution by an intake fan and an exhaust fan provided in the container, and blocks this exhaust gas flow. A baffle having an opening is erected. The baffle plate absorbs DEP contained in the exhaust gas that sucks upward the chemical solution stored in the container by utilizing capillary action and collides with the baffle plate.
Patent Document 2 discloses a device for removing harmful components in gas. This device has a storage tank for storing an essential oil-containing aqueous solution in a container having an exhaust gas inlet at one end and an exhaust gas outlet at the other end. It is the structure of being arranged. In this apparatus, the aqueous solution is vaporized by a heater, and the vaporized aqueous solution and the exhaust gas are mixed in a container to absorb DEP contained in the exhaust gas.

  Since the above two disclosed technologies are exhaust gas purification systems that are completely different from the ceramic system and the oxidation catalyst system, they solve the problems of the ceramic system and the oxidation catalyst system.

JP 2000-246056 A JP 2003-172130 A

In the exhaust gas purification method disclosed in Patent Document 1, the exhaust gas is introduced and discharged using a fan in the purification device, and the exhaust gas-absorbing chemical stored in the bottom of the purification device is installed inside the purification device. The liquid is sucked into the deflecting plate by utilizing capillary action, the chemical solution on the deflecting plate reacts with the exhaust gas, and the exhaust gas is purified. In this method, when the purification device is operated for a long time, the reaction product of the chemical solution and exhaust gas adheres to the deflector plate, the deflector plate becomes clogged, and the effect of increasing the chemical solution due to capillary action is lost over time. Therefore, it was necessary to replace the baffle regularly.
Further, in this method, the reaction between the exhaust gas and the chemical solution occurs only on the deflecting plate, so that the purification efficiency cannot be said to be good.
The exhaust gas purification method disclosed in Patent Document 2 is for spraying a mist-like exhaust gas-absorbing chemical solution into a purification device, reacting the exhaust gas with the chemical solution in the gas, and purifying the exhaust gas. . In this method, the reaction product between the exhaust gas generated in the purification apparatus and the chemical liquid is scattered in the container, the container is contaminated with the reaction product, and the scattered reaction product is also contained in the container. There has been a problem that the arranged filter is clogged and causes troubles that impede the long-term operation of the purification apparatus.
Further, in this method, the exhaust gas and the chemical liquid cause a reaction action in a state of being diffused in the container, and the exhaust gas and the chemical liquid are guided to a certain space to react intensively. Since it does not have, the purification efficiency was not so good.
The present invention has been made in view of the above problems, and exhaust gas can be intensively and efficiently purified, and reactants generated after purification can be intensively collected, so that parts replacement work for long-term operation can be performed. It is an object of the present invention to provide an exhaust gas purification device that can be minimized.

The invention according to claim 1 is a purification device for exhaust gas discharged from an internal combustion engine using light oil as a fuel, wherein the purification device is a purification device main body that takes in high-temperature exhaust gas discharged from the internal combustion engine. And an exhaust passage for exhausting the exhaust gas that has passed through the purifying device main body to the outside of the purifying device, the purifying device main body being partitioned vertically by a partition wall, the lower side formed by the partition wall The compartment is provided with an exhaust gas inlet for introducing exhaust gas into the compartment and a tank for storing a functional solution for purifying the exhaust gas, and a filter section having a number of small gaps is arranged on the upper surface of the tank. An upper section formed by the partition wall communicates with the lower section through an opening formed in the partition wall and also communicates with the discharge flow path. Is equipped with a dust remover The functional solution stored in the tank, the opening of the partition wall, and the dust remover are aligned in a line in the axial direction of the tank, and the exhaust gas particulate component dropped from the dust remover at the bottom of the tank The exhaust gas purifying device is characterized in that a sewage discharge port for discharging water is connected.
The invention according to claim 2 is characterized in that the tank and the purification device main body are formed in a cylindrical shape, and the exhaust gas inlet is directed in a tangential direction of the cylindrical shape. This is an exhaust gas purification device.
The invention according to claim 3 is characterized in that the tank is divided into small chambers by a plurality of partition plates having communication holes provided upright in the tank. This is an exhaust gas purification device.
The invention according to claim 4 is the exhaust gas purifying device according to any one of claims 1 to 3, wherein the functional solution contains eugenol and / or monoterpene.
A fifth aspect of the present invention is the exhaust gas purifying apparatus according to any one of the first to fourth aspects, wherein a cyclone type dust collecting unit is connected after the front discharge passage.
6. The exhaust gas purifying apparatus according to claim 1, wherein a functional solution replenishing unit for automatically supplying a functional solution is connected to the tank. Device.

According to the first aspect of the present invention, the functional solution in the tank heated by the high-temperature exhaust gas is vaporized, and the filter unit having a large number of small gaps in which the vaporized functional solution is disposed in the upper portion of the tank. to go into. The vaporized functional solution in the filter part adheres as water droplets to the wall surface constituting the small gap of the filter part, and fills as gas in the small gap.
Further, the vaporized functional solution further enters the dust remover located above, similarly fills the fine space in the dust remover, and adheres as water droplets to the wall surface inside the dust remover constituting the space.
Since the exhaust gas introduced into the purification device is at a high temperature, it is directed upward into the purification device and guided into the filter portion by the partition wall.
Therefore, the vaporized functional solution and the exhaust gas are concentrated in the filter unit, and the reaction between the functional solution and the exhaust gas is promoted very actively, thereby improving the purification efficiency.
Furthermore, the reaction product of the functional solution and the exhaust gas collected by the dust remover falls below the dust remover and is collected in a tank that stores the functional solution. The reaction product is recovered outside the purification apparatus from the sewage discharge port connected to the tank.
Therefore, since the reaction product is not scattered in the purification device and is collected in a concentrated manner, it is not necessary to clean the inside of the purification device, and a failure caused by the scattered reaction product is avoided. can do. Furthermore, since the reaction product in the dust remover or the filter unit falls into the tank, clogging of the dust remover or the filter unit can be avoided.
According to the invention described in claim 2, the exhaust gas introduction port is directed in the tangential direction of the cylindrical tank, and the mixing chamber formed by the tank and the main body wall becomes a cylindrical space. The exhausted gas rises in a spiral streamline on the outer peripheral surface of the tank. Therefore, as a result of efficient warming of the tank, it is possible to obtain a purified liquid that is efficiently vaporized. Therefore, the functional solution vaporized at a high concentration fills the small gap in the filter portion, and the purification efficiency is further increased.
According to the invention described in claim 3, since the tank is divided into the small chambers by the partition plate having the communication hole, the functional solution does not wave in the tank even when the vehicle equipped with the purification device is accelerated or decelerated. .
According to the invention described in claim 4, since the functional solution contains eugenol and / or monoterpene having high exhaust gas purification efficiency, the exhaust gas can be purified with higher efficiency.
According to the fifth aspect of the present invention, the exhaust gas after passing through the dust remover further passes through the cyclone type dust collecting unit, where the exhaust gas is purified, so that the exhaust gas released to the outside air is further harmful substances Will not be included.
According to the sixth aspect of the invention, since the purification liquid is automatically supplied into the tank, the purification device can be continuously operated.

Embodiments of an exhaust gas purifying apparatus according to the present invention will be described below with reference to the drawings. FIG. 1 is a view showing an example of an exhaust gas purifying apparatus according to the present invention. FIG. 1A is a schematic view of the purification device of the present invention, and FIG. 1B is a view of the inside of the purification device of the present invention as viewed from above with the partition wall removed.
In FIG. 1 (a), the exhaust gas purification device (1) is connected to a dust collection unit (A) and a functional solution replenishment unit (B).

Hereafter, the outline of a structure of the purification apparatus (1) based on this invention is demonstrated.
The purification device (1) according to the present invention has a box-shaped purification device main body (2) that forms the outer surface of the purification device (1).
A partition wall (3) that divides the interior of the purification device main body (2) vertically is disposed inside the purification device main body (2). In the present specification, the lower compartment is the mixing chamber (21), and the upper compartment is the purification chamber (22).
Connected to the mixing chamber (21) is an exhaust gas inlet (4) for introducing high-temperature exhaust gas into the mixing chamber (21). A tank (5) is disposed inside the mixing chamber (21). A porous surface (51) having many openings is formed on the upper outer surface of the tank (5).
Exhaust gas that has passed through the mixing chamber (21) flows into the purification chamber (22) through an opening (31) provided in the partition wall (3). The exhaust gas flowing into the purification chamber (22) passes through the discharge passage (6) communicating with the purification chamber (22) and the dust remover (7) disposed in the discharge passage (6). To the outside of the purification device (1).

Details of each of the above configurations will be described below.
In the embodiment shown in FIG. 1, the purifier main body (2) and the tank (5) have a bottomed double cylindrical structure connected together. The purification device main body (2) and the tank are made of stainless steel.
The inner cylinder shown in Fig. 1 is a tank (5), in which a functional solution (8) (Functional solution of diesel smoke: FSDS) that can remove particulates and gas components in diesel exhaust gas is stored. ing.
Inside the tank (5), a plurality of partition plates (52) having communication holes are erected and divided into small chambers. Thereby, the undulation of the functional solution (8) accompanying the acceleration / deceleration of the vehicle on which the purification device (1) is mounted is prevented. The upper surface opening of the tank (5) is covered with a filter part (53) having a structure in which punching metals are laminated. The size of the opening provided in the filter portion (53) is preferably about 10 mm. With this size, as will be described later, the high-density DEP produced by the reaction between the exhaust gas and the functional solution (8) is not prevented from falling into the tank. Moreover, you may arrange | position the stainless steel wool which has a coarse mesh of about 200 micrometers on the lamination | stacking intermediate surface of a filter part. If it does in this way, the high-density DEP produced | generated by reacting in a filter part will be removed by a filter part.
The side surface of the filter portion (53) forms the porous surface (51).

In this embodiment, the functional solution (8) stored in the tank is 0.5% or more of eugenol, 0.5% or more of monoterpene, or 0.5% of the components of eugenol and monoterpene. The liquid contained above is used.
Monoterpene is a component obtained from tree essential oil obtained by steam distillation. Eugenol is known to be contained in a large amount in tree essential oils such as clove oil, cassia oil, pimento oil, bay oil and camphor oil.
These components do not use any surfactant or the like, and are obtained from natural plant-derived essential oils and the like, so that high safety can be ensured for animals and plants including humans.
Further, these components exhibit a very high exhaust gas removing action as will be described later.

As shown in FIG.1 (b), the exhaust-gas inlet (4) is connected to the outer periphery of the bottom part of the purification apparatus main-body part (2). Exhaust gas from the diesel engine is introduced into the space between the tank (5) and the purifier main body (2) through the exhaust gas inlet (4).
In this embodiment, the exhaust gas introduction port (4) is directed in the tangential direction of the cylindrical tank (5). As a result, the exhaust gas flows upward while turning in the circumferential direction of the tank (5) in the space between the tank (5) and the purifier main body (2).
Since the introduced exhaust gas has a high temperature (for example, several hundreds of degrees Celsius), the exhaust gas flows upward while turning in the circumferential direction of the tank (5), so that the tank (5) is uniformly warmed. The functional solution (8) is warmed efficiently. Further, since the exhaust gas is used as a heating means, it is not necessary to supply additional energy for heating, which is economical.
The warmed functional solution (8) is vaporized, and the vaporized functional solution (8) is directed to the filter part (53) disposed above the tank, and fills the small gap in the filter part (53). Some of them adhere to the walls of the gap as water droplets.
In order to warm the tank (5) or the functional solution (8), other heating means such as a heater may be used.

A disk-shaped partition wall (3) having an opening (31) at the center is disposed on the upper surface of the filter (53) so as to be attached to the inner peripheral surface of the purifier main body (2). Yes. This partition wall (3) seals the ceiling of the space formed between the tank (5) and the purification device main body (2), and guides the exhaust gas to flow toward the filter (53). To do. In addition, the partition wall (3) fixes the filter part (53).
Thereby, exhaust gas is filled in the filter part (53).

As described above, the vaporized functional solution (8) and the exhaust gas are filled in the filter portion (53). These two gaseous substances react in the filter part (53).
By employing the above structure, the vaporized functional solution (8) and the exhaust gas are concentrated in the filter portion (53). Therefore, the reaction between the functional solution (8) and the exhaust gas is further promoted.
In addition, since the filter part (53) has a structure having a large number of small gaps inside, the vaporized functional solution (8) and the exhaust gas are confined in a narrow space, so that the reaction is further promoted.
Further, the vaporized functional solution (8) is a flow in the axial direction of the tank (5), the exhaust gas is a flow in the radial direction of the tank (5), and two gases having different flow directions are passed through the filter section (53). ) Will collide. As a result, convection is generated in the filter part (53), and the reaction is further promoted.
As will be described later, the filter unit (53) captures a part of the reaction product of the exhaust gas and the functional solution (8) generated therein, and the functional solution (8) below the filter unit (53). ) The trapped reactant is dropped in.
In this embodiment, the structure in which the filter part (53) is disposed on the tank (5) is adopted. However, in place of the filter part (53), many small holes are formed on the outer peripheral surface of the tank (5). May be provided to form a porous surface. With such a structure, the vaporized functional solution (8) and the exhaust gas entering from the porous surface convect and react in the space between the liquid surface of the functional solution (8) and the upper surface of the tank (5). Will do.

The upper surface of the purification device main body (2) is closed by the lid (23), and the purification device main body (2) forms a closed box shape. A discharge port is provided at the center of the lid (23), and a discharge channel (6) is connected to the discharge port. In the discharge channel (6), a dust remover (7) is packed in a connection portion between the discharge channel (6) and the lid (23). In this embodiment, a coarse filter (for example, about 200 μm) stainless steel filter is used for the dust remover (7).
As will be described later, the dust remover (7) captures a reaction product generated by the reaction between the functional solution (8) and the exhaust gas from the exhaust gas passing through the inside thereof, and performs dust removal of the exhaust gas.
In addition, it is preferable that the connection part of a discharge flow path (6) and a cover part (23) is located just above the opening part (31) of a partition wall (3). As a result, the vaporized functional solution (8) that has passed through the filter part (53) and the mixed gas of the exhaust gas are directed to the discharge flow path (6) at a straight shortest distance, so that high discharge efficiency is obtained.

  The other end of the discharge channel (6) is connected to a cyclone type dust collection unit (A). The dust collecting unit (A) includes a cylindrical portion (101) connected to a discharge passage (6) for introducing exhaust gas discharged from the purification device (1), and gradually downward from the cylindrical portion (101). The conical portion (102) having a smaller diameter and the bottom dust storage portion (103) provided at the lower end of the conical portion (102). Moreover, the filter part (153) which has the structure which laminated | stacked the punching metal similar to the filter part (53) used with the purification apparatus (1) is provided in the intermediate part of the cone part (102).

  The upper part of the cylindrical part (101) is sealed. Further, the distal end portion of the exhaust pipe (104) is inserted through the sealing end about the length of the cylindrical portion (101). The exhaust gas removed by the dust remover (7) is discharged from the dust collection unit (B) through the exhaust pipe (104).

  The functional solution replenishment unit (B) is provided for replenishing the functional solution (8) according to the decrease of the functional solution (8) in the tank (5). The functional solution replenishment unit (B) is connected to a replenisher tank (202) having a level gauge (201), a bottom outlet of the replenisher tank (202), and stored in the replenisher tank (202). The pipe (203) for sending the functional solution (8) toward the tank (5) and the purifier main body (2) are penetrated, the tip is opened in the tank (5), and the pipe (203) is connected. And a liquid pipe (204). The pipe (16) and the liquid injection pipe (204) are connected to the upper end of the liquid level gauge (54) provided in the tank (5).

In such a configuration, an exhaust pipe of a diesel engine is connected to the exhaust gas introduction port (4) through, for example, a flexible tube. When exhaust gas from the diesel engine is introduced into the space between the tank (5) and the purification device main body (2) via the exhaust gas inlet (4), the exhaust gas is stored in the tank as described above. It flows upward while turning in the circumferential direction in the space between (5) and the purifier main body (2). When the exhaust gas reaches the lower surface of the partition wall (3), since it is sealed, it does not rise any further, and flows into the filter part (53) disposed at the upper part of the tank (5).
In the process so far, the exhaust gas of high temperature (for example, several hundreds of degrees Celsius) exhausted from the engine flows along the outer peripheral portion of the tank (5), and therefore is stored in the tank (5) and the tank (5). Heat is transferred to the functional solution (8). Moreover, the temperature of exhaust gas falls by this heat transfer. The functional solution (8) warmed by the exhaust gas in this way is actively evaporated and becomes a gaseous functional compound (VFC). The functional substance having the feature rises in the tank and flows into the filter unit (53).
In the filter unit (53), as described above, exhaust gas and functional substances flow in, and these gaseous substances are mixed and reacted. The high temperature exhaust gas flowing into the purification device (1) makes it possible to maintain a high temperature suitable for the reaction in the purification device (1). If desired, the temperature in the mixing chamber (23) may be controlled to be controllable by a heating control means such as a heater or a thermostat in order to promote the reaction. Furthermore, a heat insulating material may be lined on the inner wall surface of the purifier main body (2) to enhance the heat retaining effect in the mixing chamber.
In addition, a fin etc. may be provided in the outer peripheral surface of the tank (5), the surface area of the tank (5) may be increased, and the heat exchange efficiency between exhaust gas and the tank (5) may be improved. In addition to performing heat exchange using exhaust gas, various types of heat exchanger structures may be used.

  In the filter part (53), DEP (for example, about several μm to 10 μm in diameter) contained in the exhaust gas reacts with the gaseous functional substance and aggregates to form particles that are 10 to 100 times larger in size. It changes to a substance (here, about 200 μm or more is called high density DEP, and less than that is called medium density DEP). A part of the high-density DEP is captured by the filter unit (53), falls into the functional solution (8) located below the filter unit (53), and is taken in. Then, it settles in a tank (5). This dust removal action is called primary removal ability. This DEP-derived substance is recovered as an oily solution from the sewage outlet (55) connected to the bottom of the tank (5).

The exhaust gas that has undergone the mixing reaction process in the filter part (53) is urged by the rising air flow generated by the evaporation of the functional solution (8) in the tank (5), and is formed in the central part of the partition wall (3). It flows into the purification chamber (22) through the section (31). Then, the exhaust gas flows into the discharge flow path (6) located directly above the opening (31).
In the discharge channel (6), a dust remover (7) having coarse eyes of about 200 μm is provided. Therefore, most of the high-density DEP contained in the exhaust gas flowing into the discharge channel (6) is captured by the dust remover (7). The captured high-density DEP falls into the purification chamber (22), and further passes through the filter part (53) and falls into the functional solution (8) in the tank (5). This function is called secondary removal capability.
In the process so far, most of the high-density DEP in the exhaust gas is removed.
In order to lengthen the reaction time between the vaporized functional solution (8) and the exhaust gas, it is preferable to lengthen the filter part (53) as much as possible.
As described above, the functional solution (8) in the tank (5), the filter part (53), the opening (31) of the partition wall (3), and the dust remover (7) in the discharge channel (6). Are aligned in a line in the axial direction of the tank (5), and the trapped high-density DEP eventually falls into the functional solution (8) in the tank (5), so that the purification device (1) The inside is not contaminated by high-density DEP, and the problem of deterioration of the purification function due to the contamination is eliminated.
Further, the sewage discharge port (55) connected to the bottom of the tank (5) can collect the high-density DEP in a concentrated manner, and the purification device can be maintained efficiently and easily.
In the present embodiment, a stainless steel filter having a passage size of about 200 μm was used for the dust remover (7). However, if the size of the eye is too small, clogging will occur. Therefore, it is preferable to use a stainless steel filter having a relatively coarse density.

  Most of the high density DEP is removed from the exhaust gas that has passed through the dust remover (7), and the medium contains a large amount of medium density DEP of 20 to 200 μm. This medium density DEP is blown into the dust collection unit (A) by the exhaust gas pressure. Medium density DEP has a weight 10 to 100 times higher than the original DEP produced by the engine. Therefore, the medium density DEP blown into the dust collection unit (A) decreases in speed while rotating in the dust collection unit (A), and falls in the conical portion (102). The medium density DEP passes through the filter part (153) disposed at the intermediate position of the conical part (102) and reaches the bottom dust storage part (103). Even if the medium density DEP that has reached the bottom dust storage part (103) is caused to rise again, it is prevented from rising by the filter part (153) and therefore does not reach the exhaust port. In this way, the medium density DEP is accumulated in the bottom dust storage part (103). This accumulation action of medium density DEP is called tertiary removal ability.

  The fine particles accumulated in the bottom dust storage unit (103) are compressed by a compression mechanism (104) provided in the bottom dust storage unit (103) and collected as a solid matter in an appropriate cycle. This solidified DEP is detoxified by the functional solution. However, it is preferable to perform a secondary treatment after recovery.

  A functional solution replenishment unit (B) is provided to replenish the functional solution (8) in the tank (5) of the purification device (1) and continuously perform the exhaust gas purification treatment. The replenisher tank (202) of the functional solution replenishment unit (B) automatically supplies the functional solution. The liquid level gauge (54) provided in the replenishing tank (202) and the tank (5) can constantly monitor the amount of the functional solution in the replenishing tank (202) and the tank (5). Become.

  The purification apparatus (1) according to the present invention having the above-described structure was actually mounted on a diesel vehicle and a running experiment was conducted. The mounted vehicle is a 5-ton truck manufactured by Hino Motors, and has a displacement of 7620 cc and a travel distance of 599108 km. The measuring instrument used for the measurement is a black smoke measuring device (smoke meter) DSM-10N. The measurement was performed by sucking exhaust gas through the filter paper and optically measuring the degree of contamination of the filter paper with black smoke.

Table 1 shows the data obtained in the above experiment. The temperature of the functional solution (8) measured in this experiment was 69.7 ° C.

As shown in Table 1, when the purification device (1) according to the present invention is installed, the black smoke cut rate is 80% or more, and it is understood that many pollutants contained in the exhaust gas are removed.
Moreover, in the said experiment, when the purification apparatus (1) which concerns on this invention was mounted, it was also confirmed that the temperature of exhaust gas falls. As an example of the measurement result, when the purification device (1) was not attached, the temperature at the muffler outlet was 142.5 ° C. at an engine speed of 2000 rpm. On the other hand, when the purification device (1) was installed, the temperature at the muffler outlet was 102.2 ° C., and a decrease in temperature of 40.3 ° C. was measured. At an engine speed of 1000 rpm, a temperature drop from 92.15 ° C. (non-mounted) to 67.16 ° C. (mounted) was measured.
In this experiment, it was confirmed that the vaporized gas temperature of the functional solution (8) is preferably in the range of 60 to 100 ° C. When the temperature of the vaporized gas is 60 ° C. or lower, the reaction with the exhaust gas is not promoted, and the black smoke cut rate decreases. Further, when the temperature is 100 ° C. or higher, the upward air flow generated by the vaporization of the functional solution (8) becomes too strong, and the time required for the vaporized gas and the exhaust gas of the functional solution (8) to pass through the filter part (53). As a result, the reaction time between the vaporized gas and the exhaust gas of the functional solution (8) is shortened, so that the black smoke cut rate is lowered.

  FIG. 2 is data showing that the monoterpene removes free radicals contained in the exhaust gas. The data shows the quantitative change before and after the reaction of each component contained in the tree essential oil aqueous solution by reacting DEP with the tree essential oil aqueous solution and gas chromatography. FIG. 2 (a) shows before the reaction, and FIG. 2 (b) shows after the reaction.

The above data was collected by the following procedure.
First, 5 ml of tree essential oil is added to 500 ml of ultrapure water and stirred in an ultrasonic cleaner (28 kHz 10 min) to prepare a tree essential oil aqueous solution. 50 mg of DEP was added to the aqueous tree oil solution, sealed and stirred with a stirrer for 2 weeks. After that, the gas in the head space of the stirrer was sampled with a syringe, and the components in the gas were measured with a gas chromatograph. It is.
The gas chromatograph used was a 311 portable gas chromatograph manufactured by HNU Systems.
In the measurement, the inlet temperature is maintained at 160 ° C. and the column temperature is 100 ° C. for 10 minutes, then the gas is injected at 10 ° C./min, the temperature is raised to 150 ° C., and then maintained for 7 minutes 30 seconds. The measurement time is 22 minutes and 30 seconds, and nitrogen is used as the carrier gas.

  The monoterpene is a portion surrounded by a circle in FIGS. 2 (a) and 2 (b). Comparing DEP with the monoterpene before and after the reaction, the shapes showing the peaks are greatly different, indicating that the monoterpene reacted with the exhaust gas. That is, it shows that the monoterpene in the tree essential oil has an exhaust gas removing action.

FIG. 3 is data showing that eugenol removes carbon-centered radicals contained in exhaust gas.
In FIG. 3, the aroma components obtained from tree essential oil and the like are compared with the removal rate of the carbon center radicals of eugenol.
This data is obtained by making each fragrance component into an aqueous solution and reacting with DEP, and then measuring the carbon center radical in DEP with an ESR spectrometer.

  As shown in FIG. 3, eugenol eliminates more carbon-centered radicals than other aroma components. In this experiment, the removal rate is about 80%. That is, if a liquid containing a large amount of eugenol is used in the purification device, the purification device can remove more carbon-centered radicals.

  The present invention is preferably applied to a purification device for exhaust gas discharged from an internal combustion engine using light oil as a fuel, such as a diesel engine.

It is a figure which shows an example of the purification apparatus of the exhaust gas which concerns on this invention. (A) is the schematic of the purification apparatus which concerns on this invention, (b) is the figure which looked at the inside of the purification apparatus of this invention from the upper side in the state which removed the partition wall. It is data which shows the exhaust gas removal effect | action of a monoterpene. It is data which shows the removal effect | action of the carbon center radical of eugenol.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Purification apparatus 2 ... Purification apparatus main-body part 3 ... Partition wall 31 ... Opening part 4 ... Exhaust gas inlet 5 ... Tank 53 ··· Filter part 55 ··· Sewage outlet 6 ··· Discharge flow path 7 ··· Dust remover 8 ··· Functional solution A ··· Cyclone type collection Dust unit B ... Functional solution replenishment unit

Claims (6)

A device for purifying exhaust gas discharged from an internal combustion engine using light oil as fuel,
The purification device includes a purification device main body portion that takes in high-temperature exhaust gas discharged from the internal combustion engine, and a discharge passage that exhausts exhaust gas that has passed through the purification device main body portion to the outside of the purification device,
The purification device main body is partitioned vertically by a partition wall,
The lower compartment formed by the partition wall is provided with an exhaust gas inlet for introducing exhaust gas into the compartment and a tank for storing a functional solution for purifying the exhaust gas. A filter part having a large number of small gaps is disposed,
The upper partition formed by the partition wall communicates with the lower partition through an opening formed in the partition wall, and also communicates with the discharge channel,
A dust remover is provided inside the discharge channel,
The functional solution stored in the tank, the opening of the partition wall and the dust remover are aligned in a line in the axial direction of the tank,
An exhaust gas purifying apparatus, wherein a waste water discharge port for discharging exhaust gas particulate components dropped from the dust remover is connected to the bottom of the tank. The tank and the purification device main body are formed in a cylindrical shape,
2. The exhaust gas purifying apparatus according to claim 1, wherein the exhaust gas inlet is directed in a tangential direction of the cylindrical shape.   3. The exhaust gas purifying device according to claim 1, wherein the tank is divided into small chambers by a plurality of partition plates having communication holes provided upright in the tank.   The exhaust gas purifying device according to any one of claims 1 to 3, wherein the functional solution contains eugenol and / or monoterpene.   The exhaust gas purifying device according to any one of claims 1 to 4, wherein a cyclone type dust collecting unit is connected to the exhaust passage. The exhaust gas purifying device according to any one of claims 1 to 6, wherein a functional solution replenishing unit for automatically supplying a functional solution is connected to the tank.

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