JP2004130163A - Deodorizing device and control method therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To control the state of the gas discharged from the treatment apparatus main body of a biological waste treatment apparatus in parallel to the efficient and certain deodorizing treatment of the gas to enhance the reliability related to the offensive smell of the gas discharged to the atmosphere. <P>SOLUTION: The deodorizing device Y is constituted so as to deodorize the gas to be treated discharged from the treatment apparatus main body X of the biological waste treatment apparatus and provided with a condensation treatment device A a for condensing the steam contained in the gas to water to separate and remove the same and a neutralizing treatment device B for mainly neutralizing the ammonia gas contained in the gas to be treated from which steam is removed and dissolving the neutralized gas in a sulfuric acid solution S to absorb and remove the same. This deodorizing device Y is further equipped with an adsorbing treatment device D for mainly adsorbing the acidic and neutral gases having a residual offensive smell contained in the gas to be treated, from which the steam and the alkaline gas are removed, by adsorption of first and second activated carbon beds 42 and 43 to separate and remove them. The respective treatment devices A, B and D are connected in the passing direction of the gas to be treated in the above mentioned order. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a biological waste treatment apparatus for "composting""biologicalwaste" with microorganisms, and to a deodorizing apparatus for deodorizing gas released into the atmosphere during composting.
[0002]
[Prior art]
In the following description, the `` biological waste '' to be subjected to `` composting '' includes, for example, combustible garbage, kitchen garbage, and human waste classified as general waste, and natural animals and plants and their metabolites, It also refers to the residue of organic materials derived from living organisms, such as those treated residues. In the following description, "composting" means that each biochemical reaction proceeds in a complex chain by the action of microorganisms, and the organic matter in biological waste is converted into carbon dioxide and water (or water vapor) in the final process. Thus, the above-mentioned biological waste is converted into a compost product that is effective as a fertilizer and a soil conditioner for agricultural production.
[0003]
As such a composting treatment method and a management method for biological waste, the present applicant has disclosed in Japanese Patent Application No. 2002-19587 "Biological waste such as ammonia concentration, carbon dioxide concentration, temperature, moisture, and electric conductivity." Using a composting system equipped with various sensors to detect the various processing conditions of composting of system waste, the biological waste to be treated put into the treatment tank is composted by the action of microorganisms and oxygen. A method of treating, wherein the sample of the biological waste to be treated is composted using a composting experimental device, and the carbon dioxide concentration with respect to time is determined, whereby the water content of the biological waste to be treated is determined. The optimum value of various conditions necessary for the composting process such as the ventilation rate, the input timing of the new biological waste to be treated, and the like are obtained in advance, and the various sensors are used. Detecting the processing state at the point of time, comparing with each of the optimal values, if necessary, changing the processing conditions, stopping the processing, and performing the composting processing under the optimal value or a condition close thereto. A method for composting biological waste, characterized by the following characteristics. " Further, in the above-mentioned composting processing method, in the above-mentioned composting processing apparatus installed in, for example, a waste discharge company that performs this processing, the detection values of the various sensors indicating the processing status are transmitted via a communication line. This is a method that can be managed collectively by sending the data to a central management center. Then, the management center determines whether or not various processing situations are appropriate while comparing it with the pre-registered optimum value of the detection value. It is possible to go to a waste discharge company that owns the wastewater treatment equipment and modify the composting treatment conditions.
[0004]
By the way, in the process of composting, odorous (odorous) gas is generated as a by-product of microorganisms decomposing biological waste. This odorous gas is released into the atmosphere from the biological waste treatment equipment together with other generated gas such as carbon dioxide and excess air, etc., and has a significant effect on the environment. Give pleasure. As a typical example of the odorous gas, if biological waste is mainly garbage, ammonia gas generated according to the content of the protein component may be mentioned, but in fact, according to the type of biological waste. It is assumed that various odorous gases are generated. Therefore, the usual biological waste treatment equipment removes the odorous gas that is generated by composting separately from the main body that mainly performs the composting treatment, and removes the odorless harmless gas into the atmosphere. A deodorizing device is provided for discharging the air to the air. In the following description, a gas that is discharged from the processing apparatus main body as a result of composting and that passes through the deodorizing apparatus to be deodorized is referred to as a “gas to be processed”. The term "gas to be treated" indicates a gas to be treated when viewed from the side of the deodorizing device, but is discharged to the outside when viewed from the side of the processing device body. The "exhaust gas" to be processed, and both the terms "gas to be treated" and "exhaust gas" have the same meaning.
[0005]
Some conventional deodorizing apparatuses for biological waste treatment apparatuses decompose the odorous gas with ozone. However, the gas has a small number of molecules per unit volume, and in order to be decomposed by ozone, both gases need to collide with each other in a molecular state, so that undecomposed odorous gas often remains. Therefore, in addition to the ozonolysis, an acid aqueous solution is sprayed on the gas to be treated, and an alkaline gas such as ammonia gas is neutralized to remove the gas (for example, see Patent Document 1). There is a device for neutralizing similarly using electrolytic water obtained by decomposition (for example, see Patent Document 2). However, when an acidic aqueous solution is sprayed, it is necessary to control the pH value of the acidic aqueous solution which increases with an increase in the amount of neutralization treatment. There is a problem in that not a small amount of electric energy is consumed in order to electrolyze.
[0006]
[Patent Document 1]
JP-A-10-174958
[Patent Document 2]
JP-A-6-239681
[0007]
DISCLOSURE OF THE INVENTION The present invention is to control the state of the gas discharged from the processing apparatus body of the biological waste processing apparatus in parallel with efficiently and reliably deodorizing the gas, and to control the atmosphere. It is an object to improve the reliability related to the odor of the gas released therein.
[0008]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention according to claim 1 is a biological waste treatment apparatus for composting biological waste, and when composting with the treatment apparatus, excess air, carbon dioxide, etc. A deodorizing apparatus for deodorizing a gas to be treated discharged to the outside of the processing apparatus main body together with the gas of the present invention, wherein the gas to be treated is cooled, and water vapor contained in the gas is condensed into water to be separated and removed. A treatment device, a neutralization treatment device for neutralizing a mainly ammonia gas contained in the gas to be treated after removing the water vapor, dissolving the gas in an acidic solution to absorb and remove the ammonia gas, And from the gas to be treated after the removal of the alkaline gas, mainly an acidic and neutral gas having a residual odor contained therein, and an adsorption treatment device for adsorbing the adsorbent to separate and remove the gas, Each of the above Device is characterized in that it is attached in the order in the direction of gas to be treated passes.
[0009]
According to the invention of claim 1, the gas to be treated discharged during the composting treatment of biological waste is first guided and passed through the inside of the condensation treatment device of the deodorization device, and cooled by a refrigerant or the like. By condensing the water vapor therein and separating the condensed water from other gases other than the water vapor, the water vapor can be removed. Therefore, the gas to be treated after the removal of water vapor has a high concentration of the alkaline gas occupying therein, and the gas to be treated passes through the neutralization treatment device connected next, so that it is a source of odor. The neutralized ammonia gas can be efficiently neutralized and quickly dissolved and absorbed as a "salt" in the acidic solution. In addition, since the water vapor has been removed before the neutralization treatment, the acidic solution absorbs the water vapor, which can be prevented from becoming a dilute aqueous solution. The frequency of work for adjusting the pH value to an appropriate value for neutralizing the alkaline gas can be reduced. Generally, most of the composition of biological waste is “water” (depending on the type of biological waste, but generally 80%), and water (steam) generated as a result of composting and composting A large amount of water vapor is contained in the gas to be processed during the composting process due to water vapor that evaporates as the temperature rises (depending on the type of biological waste, but about 50 to 60 ° C.). Therefore, it is particularly effective to remove water vapor before removing odorous gas. Further, the gas to be treated after the removal of the water vapor and the alkaline gas is brought into contact with the adsorbent filled in the adsorption treatment device to be adsorbed, so that the gas is mainly an acidic or neutral gas or a poorly water-soluble gas. And other odorous gases can be efficiently removed, and only odorless gases are released to the atmosphere.
[0010]
According to a second aspect of the present invention, in the first aspect of the present invention, the gas or atomized acidic solution is dissolved and removed between water between the neutralization treatment device and the adsorption treatment device. In addition, an acidic solution removing device is provided.
[0011]
In the neutralization treatment device, a part of the acidic solution may be gaseous or atomized and pass through the next device together with the gas to be treated after the neutralization treatment. For example, when the neutralization treatment is performed by spraying an acidic solution into the washing tower of the neutralization treatment device, the alkalinity generated corresponding to the treatment amount of a relatively large amount (approximately 50 kg) of biological waste is required. Although the neutralization capacity of the gas is improved, the possibility that the gas or atomized acidic solution passes through the next processing apparatus is increased. According to the invention of claim 2, in addition to the effect of the invention of claim 1, the gas to be treated after the removal of the alkaline gas is introduced into the interior of the acidic solution removal device and brought into contact with water to be contained therein. A slight gas or atomized acidic solution can be dissolved in water and removed. Therefore, it is possible to prevent the acidic gas or mist from acting on the metal device or the like through which the gas to be processed passes later, thereby preventing the device from being corroded.
[0012]
According to a third aspect of the present invention, in the second aspect of the present invention, the acidic solution removing device includes a sprayer for spraying water into the inside of the washing tower, so that the sprayed water is brought into contact with the gas to be treated. The gas or atomized acidic solution is dissolved and removed in spray water.
[0013]
According to the third aspect of the invention, in addition to the effect of the second aspect of the present invention, by spraying water onto the gas to be treated, the contact area between the gas to be treated and water can be increased, so that the processing amount of composting can be increased. The gas or mist-like acidic solution which is likely to enter the acidic solution removing device can be surely dissolved and removed in accordance with the increase of the acid solution.
[0014]
According to a fourth aspect of the present invention, in the first to third aspects, the condensation treatment device includes a sprayer for spraying cooling water into a cooling tower, and sprays cooling water to spray the cooling water. It is characterized in that it is cooled by being brought into direct contact with the processing gas.
[0015]
According to the fourth aspect of the present invention, in addition to the effects of the first to third aspects, by spraying the cooling water onto the gas to be treated, the contact area between the gas to be treated and the cooling water as the refrigerant is large. Water can be condensed and efficiently removed to remove the water vapor generated in response to the treatment of relatively large amounts of biological waste, and water-soluble odorous gases can be dissolved and absorbed in the cooling water to remove it Can have a great deodorizing effect. In addition, since the gas to be treated also includes dusts of biological wastes generated in the composting process, the dusts can be removed by spraying cooling water, and deodorizing. Subsequent processing becomes easier.
[0016]
The invention according to claim 5 is a method for collectively managing the processing state of the neutralization processing device constituting the deodorizing device according to claim 1 in a central management center, wherein the neutralization processing device includes an alkaline gas. A pH sensor for detecting the pH value of the acidic solution that absorbs the water is attached, and the detected value is transmitted to the management center via communication means and compared with a predetermined pH value registered in the management center in advance. Then, it is determined whether or not the neutralization treatment is possible, and if it is determined that the neutralization treatment is not possible, the management technician goes to a waste discharge company or the like that owns the biological waste treatment apparatus related to the determination of the impossibility, The pH value of the acidic solution is adjusted to be equal to or less than a predetermined value.
[0017]
According to the invention of claim 5, a biological waste treatment apparatus installed in a waste discharge company or the like transmits the pH value of the acidic solution of the neutralization treatment apparatus to the management center via communication means. This enables the management center to track and manage the pH value. Therefore, when the treatment amount of the biological waste is cumulatively increased and the dissolved and absorbed amount of the alkaline gas in the acidic solution is increased, when the pH value of the acidic solution is increased to a predetermined value or more, for example, An instruction is given from the management center to the management technician to replace the acidic solution with a high concentration, and the pH value at which the neutralization reaction should proceed properly can be adjusted. Then, by absorbing the alkaline gas again into the adjusted acidic solution, the alkaline gas such as the ammonia gas can be reliably removed without imposing a burden on the trader or the like. Further, since it is possible to cope with a case where the pH value rises due to an unexpected situation or the like, the reliability related to deodorization of the biological waste treatment apparatus is increased.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
1 is a front cross-sectional view of the processing apparatus main body X, FIG. 2 is a cross-sectional view taken along line HH of FIG. 1, and FIG. 3 is a plan view showing the arrangement of the processing apparatus main body X and the deodorizing apparatus Y. is there. As shown in FIG. 3, on the back side of the processing apparatus main body X, a deodorizing apparatus Y described later for sucking and collecting gas (exhaust gas) generated in the processing apparatus main body X and performing deodorization processing is disposed. Have been. In FIG. 3, reference numeral 70 denotes a base plate on which the processing apparatus main body X and the deodorizing apparatus Y are mounted.
[0019]
First, the configuration of the processing apparatus main body X will be briefly described, and then the deodorizing apparatus Y according to the present invention will be described in detail. In the processing apparatus main body X, a rotating shaft 52 having a hollow structure is horizontally disposed at the center of the processing tank 51, and both ends thereof are rotatable by a pair of bearings 53 disposed outside the processing tank 51. Supported. A spiral stirring blade 54 is integrally attached to the rotating shaft 52, and a support ring 56 is integrally attached to both ends of the rotating shaft 52 via a plurality of arms 55. An air supply pipe 57 is supported by the pair of support rings 56 in parallel with the rotation shaft 52, and portions of the pair of support rings 56 that are 180 ° out of phase with the air supply pipe 57 are connected by a connecting rod 58. Thus, the connection rigidity of the pair of support rings 56 is increased. A large number of air ejection holes (not shown) are provided at predetermined intervals along the axial direction inside the air supply pipe 57 (the side facing the rotating shaft 52 in the arrangement state). Further, the rotary shaft 52 having a hollow structure and the air supply pipe 57 are connected via two connecting air supply pipes 59 having a hollow structure arranged in a direction perpendicular to the axis of the rotary shaft 52. On the other hand, a blower 61 is connected to one end of the rotating shaft 52, and the air sent from the blower 61 is sent to the air supply tube 57 via the rotating shaft 52 and the two connecting air supply tubes 59. The air is ejected toward the rotation shaft 52 from a number of air ejection holes provided in the air ejection hole.
[0020]
The driven sprocket 62 attached to the other end of the rotating shaft 52 and the driving sprocket 64 attached to the driving shaft 63a of the driving motor 63 are connected via a chain 65, and the rotating shaft 52 The motor 63 is rotated at a low speed in a predetermined direction by the driving force. For this reason, the processing target (biological waste) charged into the processing tank 51 from a charging port 66 described later is processed while being rotated by the action of the stirring blade 54.
[0021]
In addition, an inclined surface portion 51a is provided on the front side of the processing tank 51, and a rectangular input port 66 is provided on the inclined surface portion 51a so as to face obliquely upward, and the input port 66 is provided with biological waste. Is closed by a lid 67 hingedly connected to the upper end of the slant except when the is inserted. Inside the inlet 66, a suction pipe 68 is fixedly disposed along the periphery thereof, and the suction pipe 68 is suctioned via a connection pipe 69 disposed along the inner surface of the upper plate portion of the processing tank 51. It is connected to the fan 71. The overall shape of the suction pipe 68 is a square shape corresponding to the shape of the input port 66, and a plurality of suction holes (see FIG. (Not shown). Further, since the suction force of the suction fan 71 is exerted on the suction pipe 68 via the connection pipe 69, a suction airflow is constantly generated in the inlet 66. Therefore, gas generated during the processing of biological waste in the processing tank 51 in a substantially closed state is sucked by the suction pipe 68 and guided to the deodorizer Y, and the cover 67 is opened and the inlet 66 is opened. When the biological waste is charged into the treatment tank 51, the gas that is going to flow into the atmosphere from the open input port 66 is also sucked into the suction pipe 68 by the suction airflow that extends to the input port 66. Then, it is guided to the side of the deodorizing device Y and discharged. In this way, the exhaust gas containing the odorous gas (the gas to be treated as viewed from the deodorizing device Y) is prevented from being released into the atmosphere as it is. In addition, a filter (not shown) is attached to the connecting pipe 69 so that dust in the exhaust gas can be removed.
[0022]
A first sensor cylinder having sensors 72 and 73 for detecting the temperature and moisture in the processing tank 51 during processing is provided in a portion of the side plate part constituting the processing tank 51 below the rotation shaft 52. G ₁ Is installed, and the processing status can be monitored at a remote management center.
[0023]
Next, the deodorizing device Y that deodorizes the gas to be treated that is sucked by the suction pipe 68 of the processing device main body X and guided to the deodorizing device Y will be described in detail. FIG. 4 is a diagram schematically showing a deodorizing device Y according to the present invention. The deodorizing device Y is connected to the suction fan 71 of the processing device main body X via the pipe line 2 and removes water vapor contained in the gas to be processed by condensing it into water. A neutralization treatment device B connected to the condensation treatment device A via a passage 3 to neutralize and absorb and remove an alkaline gas contained in the gas to be treated with a sulfuric acid solution S; An acidic solution removing device C connected to the neutralization treatment device B for dissolving and removing the sulfuric acid solution S in the form of a mist slightly contained in the gas to be treated in spray water, and a pipe 5 An adsorption treatment device D connected to the acidic solution removal device C and adsorbing and removing residual odorous gas contained in the gas to be treated by activated carbon (adsorbent) described later is provided. Therefore, the gas to be treated can pass through the deodorizing device Y in the order of the condensation treatment device A, the neutralization treatment device B, the acidic solution removing device C, and the adsorption treatment device D. , The gas or the mist of the acidic solution, and the remaining odorous gases, mainly acidic and neutral gases, can be removed. Further, each solid line arrow shown in FIG. 3 and the like indicates the moving direction of the gas to be processed (exhaust gas), and the broken line arrow indicates that of the liquid.
[0024]
The condensation treatment device A is a device for guiding the gas to be treated into the inside thereof, cooling it with cooling water, and condensing and removing mainly water vapor therein. The condensing apparatus A is provided with a substantially cylindrical cooling tower 11 for performing a cooling operation of the gas to be treated and a nozzle portion 12a at the tip inside the cooling tower 11, and is attached substantially vertically to the top of the tower. The spray pipe 12 has a substantially straight pipe shape, and is attached to an opening at the bottom of the cooling tower 11 to store cooling water sprayed from above and falling, and water generated by condensation of water vapor in the gas to be treated. And a first water circulation path 15 for circulating the water W stored in the tank 13 and re-spraying it as cooling water. The cooling tower 11 is connected to the end and the beginning of each of the pipes 2 and 3 at the lower and upper openings of its peripheral wall, and has a nozzle 12a of the spray pipe 12 inside itself. A disk is provided on the outer peripheral surface of the spray pipe 12 disposed above and below the opening at the start end of the pipe 3 so that the passage of the gas to be treated toward the pipe 3 meanders. A plurality of baffle plates 14 formed by removing a part of the shape are attached. The baffle plate 14 is used to make it difficult for the cooling water sprayed and scattered from the nozzle portion 12a to pass upward together with the cooled gas to be processed. Further, the tank 13 is connected to the top of the spray pipe 12 via the first water circulation path 15, and the pump P ₁ , The water W can be circulated. In addition, 16 in FIG. 4 is a drain pipe for appropriately discharging the water W stored in the tank 13.
[0025]
Further, the neutralization treatment device B sprays a strongly acidic sulfuric acid solution S in order to guide the gas to be treated after removing the water vapor into the inside and mainly remove alkaline ammonia gas having an unpleasant odor, A device that dissolves and absorbs the "salt", i.e., ammonium sulfate, in the solution. Further, the acidic solution removing device C guides the gas to be treated after the removal of the alkaline gas described above into the inside, and converts the sulfuric acid solution S, which may be in a mist with the gas to be treated into the inside, into the spray water. It is a device that dissolves in and removes it. The neutralizing device B and the acidic solution removing device C have substantially the same configuration as the condensing device A, and are equivalent to the cooling tower 11 for spraying the sulfuric acid solution S and the water W. 21 and 31, spray pipes 22 and 32, tanks 23 and 33, baffles 24 and 34, etc., respectively. The sulfuric acid solution S and water W stored in the tanks 23 and 33 are continuously circulated. It has a sulfuric acid solution circulation path 25 and a second water circulation path 35 for spraying. The second water circulation path 35 includes a pump P ₃ Are connected, and the water W can be circulated by the power. Reference numeral 36 in FIG. 4 is a drain pipe similar to the drain pipe 16.
[0026]
On the other hand, the sulfuric acid solution circulation path 25 is provided with a pump P similarly to the first and second water circulation paths 15 and 35. ₂ The sulfuric acid solution S can be continuously circulated and sprayed, and a pH sensor 27 is attached in the middle of the circulation path 25 so that the pH value of the circulating sulfuric acid solution S can be changed in real time. Detectable. The pH sensor 27, together with the temperature and moisture sensors 72 and 73 attached to the processing apparatus main body X, cooperates with the detection value management means Z via a communication line 80, as described later. In the management center 90, the detection value of the pH sensor 27 can be monitored.
[0027]
Further, the adsorption treatment device D guides the gas to be treated after the removal of the acid solution by the acid solution removal device C, and converts the remaining mainly acidic and neutral odorous gas or poorly water-soluble gas into activated carbon. This is a device that is adsorbed, finally separated from other components of the gas to be treated having little odor problem, and discharges the deodorized gas to be treated from the exhaust pipe 6 to the atmosphere. The interior of the packed tower 41 of the apparatus D is roughly divided into two rooms, and each space is individually filled with first and second activated carbons 42 and 43, respectively. It is connected to the top of the tower 41. Each of the activated carbons 42 and 43 is an activated carbon that is subjected to a predetermined attachment process in addition to physical adsorption and can also be chemically adsorbed, and has a large adsorption action on an acidic gas and a neutral or amphoteric gas. Activated carbon having The exhaust pipe 6 has second sensors 7 and 8 for detecting the concentrations of carbon dioxide and ammonia gas in the gas to be treated released to the atmosphere after all the deodorizing processes. Tube G ₂ Is attached. Each of the sensors 7 and 8 for carbon dioxide and ammonia cooperates with the detection value management means Z similarly to the pH sensor 27 (not shown in FIG. 4), and the progress of composting and the release of the composting, respectively. Installed to keep track of gas odors. Reference numeral 46 in FIG. 4 denotes a drain pipe for appropriately discharging water or the like that is naturally condensed and accumulated at the bottom of the packed tower 41.
[0028]
Next, a process of composting in the processing apparatus main body X of the biological waste processing apparatus and deodorizing in the deodorizing apparatus Y will be described first, and then a management method thereof will be described. FIG. 5 is a process chart showing a management method for composting biological waste. First, a specific waste discharger E ₁ , A biological waste having certain characteristics is generated. Biological waste, which has been subjected to a predetermined adjustment so as to be suitable for composting according to its characteristics, is charged into the processing tank 51 through the input port 66 of the processing apparatus main body X, and is uniformly mixed according to predetermined stirring conditions. Mix. Air containing oxygen necessary for composting is supplied to the inside of the processing tank 51 via the blower 61, the hollow rotary shaft 52, the connecting air supply pipe 59, and the air supply pipe 57, and the composting reaction is performed. Let it start. The air supply pipe 57 is set so as to be disposed at the bottom of the processing tank 51 except during stirring, and reliably supplies a predetermined flow rate of air into the biological waste so that active microbial activity can be achieved. Is to be maintained. In this way, the composting of the biological waste starts and progresses smoothly, and water and carbon dioxide generated as a result of the biological waste being decomposed by the activity of microorganisms inside the treatment tank 51 are generated. In addition, odorous gas and the like are generated, and the temperature inside the processing tank 51 rises from 50 ° C. to about 60 ° C. In addition, water vapor, in which a large amount of water originally contained in the biological waste is vaporized, is also generated. As a result of these composting processes, the generated gas, steam vaporized due to the rise in temperature, surplus air and other gases sent into the tank, and biological waste are pulverized into garbage dust. The suction tank 71 is sucked by the suction force of the suction fan 71 to the side of the deodorizing apparatus Y, and the processing tank 51 is connected to the processing tank 51 via the suction pipe 68 and the connection pipe 69 attached to the periphery of the charging port 66. Is discharged to the outside. Further, the temperature and moisture sensors 72 and 73 are attached to the processing tank 51, and a detection value management unit Z to be described later is connected to the processing tank 51 via a communication line 80 in order to track and manage the composting status in real time. Working together.
[0029]
Then, as described above, the exhaust gas discharged to the outside of the processing tank 51, that is, the gas to be deodorized by the deodorizing device Y, passes through the pipe 2 below the cooling tower 11 of the condensation processing device A. And is guided inside. Inside the cooling tower 11, cooling gas is sprayed from the spray pipe 12 to the gas to be treated moving further upward during the passage thereof, and the water vapor contained in the gas to be treated is cooled and condensed. And falls with the cooling water etc. and is stored in the tank 13. The stored water W is pump P ₁ Is continuously re-sprayed through the first water circulation path 15 by the power of. At the same time, fine dust and water-soluble gas other than water vapor that cannot be completely removed by the filter are taken into the cooling water and removed from the gas to be treated. As described above, the method of cooling the gas to be treated in the condensation treatment apparatus A is a method in which water as a refrigerant is brought into direct contact with the gas to be treated, and therefore, the gas generated according to the input amount of the biological waste to be composted. Regardless of the discharge amount of the processing gas, cooling can be performed efficiently, and impurities such as other dusts and water-soluble odorous gas can be removed. Further, the baffle plate 14 is disposed above the cooling tower 11, and the sprayed cooling water reaches the opening portion at the start end of the pipe 3 together with the gas to be treated, and It is difficult to pass toward.
[0030]
The gas to be treated, from which the water vapor has been mainly removed in this way, is introduced into the washing tower 21 of the neutralization treatment device B via the pipe 3, and is supplied to the tank 23 as in the case of the condensation treatment device A. Is continuously sprayed from the spray pipe 22. The odorous gas contained in the gas to be treated is supposed to be of a wide variety, but in particular, a large amount of gas generated therein and having a great odor discomfort is ammonia gas. It is a gas that is easily produced as a result of being decomposed into microorganisms according to the content of nitrogen components, for example, proteins and the like, in the system waste. The ammonia gas is neutralized by the sulfuric acid solution S and is combined with ammonium sulfate, and is dissolved and absorbed in the solution. Further, the neutralization treatment is effective for all alkaline gases, and alkaline gases other than ammonia gas are also removed. Since a large amount of water vapor contained in the gas to be neutralized has been substantially removed by the condensation treatment device A and the dust and the like have been removed at the same time, the sulfuric acid solution circulation path 25, the concentration and purity of the sulfuric acid solution S circulating through 25 can be maintained satisfactorily over a long period of time, and the neutralization treatment can be efficiently and promptly advanced. Further, the pH sensor 27 attached in the middle of the sulfuric acid solution circulation path 25 in which the sulfuric acid solution S circulates transmits its detection value to the detection value management means Z, and the detection value is determined by the water content and the water content. The temperature is tracked and managed in the same manner as the temperature sensors 72 and 73.
[0031]
Then, the neutralized gas to be treated is prevented from being mixed with the sulfuric acid solution S sprayed into the inside of the gas to be treated by the baffle plate 24 installed in the washing tower 21. The sulfuric acid solution S which is prevented and guided through the pipe 4 to the inside of the washing tower 31 of the acidic solution removing device C but cannot be prevented by the baffle plate 24 is partially converted into the acidic solution removing device as it is. There is a risk of infiltration into the interior of the cleaning tower 31 of C. Here, inside the washing tower 31, water W is sprayed from the spray pipe 32 in the same manner as in the case of the treatment apparatus A, and the slight mist of the sulfuric acid solution S in the gas to be treated is dispersed in the water W. Can be dissolved and removed. Since the sulfuric acid is easily dissolved in water, the atomized sulfuric acid solution S is quickly removed from the gas to be treated by spraying the water W so as to increase the contact area between the two. Therefore, it is possible to prevent the portions of the sensors 7 and 8 of, for example, carbon dioxide and ammonia, through which the gas to be processed later passes, from being corroded by the sulfuric acid solution S.
[0032]
Then, the gas to be treated after the removal of the mist of the sulfuric acid solution S is introduced into the packed tower 41 of the adsorption treatment apparatus D via the pipe 5. In the inside of the packed tower 41, the gas to be treated comes into contact with the first and second activated carbons 42, 43 in order, and is neutralized with an acidic gas such as hydrogen sulfide or methyl mercaptan, and a neutral gas such as methyl sulfide or methyl disulfide. Is adsorbed by the activated carbons 42 and 43 and removed from the gas to be treated. In this adsorption treatment step, other poorly water-soluble odorous gases and the like can be similarly adsorbed and removed. In this way, the gas to be treated discharged from the treatment apparatus main body X is subjected to a neutralization treatment for removing ammonia gas, and various treatments before and after the condensation and dissolution of the acidic solution, and finally, the residual odor. The volatile gas is removed, and the odorless gas is released to the atmosphere from the exhaust pipe 6. Further, the carbon dioxide and ammonia sensors 7 and 8 are attached to the exhaust pipe 6 to detect the concentration of each gas in the released gas to maintain the reliability of composting and deodorization. And is tracked and managed as described below.
[0033]
Next, a management method performed in parallel with the composting and deodorization processing will be described mainly on a part relating to deodorization. The management related to the deodorization is mainly performed based on the detection value of the pH sensor 27 of the neutralization treatment device B. As shown in FIGS. 4 and 5, the detection value of the pH sensor 27 is transmitted to the management center 90 of the detection value management means Z via the communication line 80 in real time. In the management center 90, the waste discharger E ₁ The upper limit pH value of the sulfuric acid solution S necessary for neutralizing the ammonia gas, which is assumed to be generated in accordance with the normal characteristics and the amount of waste of biological waste, is registered in advance, and the pH sensor 27 is used. Can be compared with the registered value. For example, after a certain period of the composting treatment, the amount of neutralization treatment of the alkaline gas increases cumulatively, the concentration of the sulfuric acid solution S in the tank 23 decreases, and its pH value rises above the registered value. The detection value management means Z includes a waste discharger E ₁ Local administrative office G ₁ In such a case, the management center 90 ₁ To return the pH value to the initial value. ₁ Technician F ₁ Can be sent to replace the tank with another tank storing concentrated sulfuric acid. Further, not only in the case described above, but also in the case where the pH value of the sulfuric acid solution S rises in various situations, the neutralization capacity of the ammonia gas is reduced, and the ammonia gas having a predetermined concentration or more is released, and the Before giving a pleasant sensation, it is possible to make a comprehensive judgment while referring to the detection values of the other sensors and take appropriate measures, so that the reliability relating to the deodorization is improved.
[0034]
The ammonia pipe 8 connected to the detection value management means Z, like the pH sensor 27, is attached to the exhaust pipe 6 connected to the adsorption treatment apparatus D. The concentration of the ammonia gas is detected and monitored by the management center 90. In the management center 90, the general concentration of ammonia gas that can be ignored odor is set as a registered value, and it can be confirmed that the detected value of the ammonia sensor 8 is equal to or less than the registered value. Therefore, the odor-related reliability of the ammonia gas can be more reliably maintained.
[0035]
The temperature and moisture sensors 72 and 73 and the carbon dioxide sensor 7 are attached to the processing tank 51 and the exhaust pipe 6, and cooperate with the detection value management means Z similarly to the sensors 27 and 8. Are tracked and managed. The detection values of these sensors 72, 73, and 7 are numerical values to be used as barometers of the activity of the microorganism, and are registered in the management center 90 so that the composting process proceeds stably and efficiently over a long period of time. The values are compared by reference. Then, when each numerical value is different from the specified range, there is a possibility that the activity of the microorganism may be inhibited for some reason. Therefore, the management center 90 makes a comprehensive judgment including a countermeasure, and Management Office G ₁ To the technician F ₁ Is dispatched to perform predetermined repair work. It should be noted that the waste discharger En in FIG. ₁ Indicates that there are a plurality of operators similar to the above, and the management office Gn and its technician Fn are arranged correspondingly.
[0036]
In the above-described embodiment, as the condensation treatment device A, a condensation device of a type in which cooling water as a refrigerant is directly sprayed onto the gas to be treated is exemplified. Other refrigerants that can be used can also be used, and a device that indirectly contacts the refrigerant and the gas to be treated to exchange heat can be used. Further, in order to remove the target water vapor, ammonia gas, and sulfuric acid solution in the form of a mist, each absorption liquid of water or sulfuric acid solution is sprayed, that is, dispersed in the gas to be treated containing the gas to be removed, that is, the gas phase. Although the respective apparatuses of the system (condensation and neutralization processing apparatuses A and B, and the acidic solution removing apparatus C) are illustrated, conversely, the above-mentioned absorption liquid is used as a continuous phase, and the gas to be processed is dispersed as bubbles in the liquid. It can be replaced with a device that absorbs the gas to be removed. The acidic solution has low volatility and easily dissolves in (spray) water, and sulfuric acid is exemplified as an easily available solution having strong acidity, but other acidic solutions can be used instead.
[0037]
The condensing device A and the acidic solution removing device C both have respective circulation paths 15 and 35 for the water W, and each individual pump P ₁ . P ₂ , But can be shared. Further, in a waste discharge company that emits a small amount of biological waste to be composted, the height of the washing tower of the neutralization treatment device is secured without connecting the acidic solution removal device C, thereby preventing the waste. In some cases, the treatment of removing the acidic solution can be sufficiently performed by a procedure such as mounting a large number of plates.
【The invention's effect】
[0038]
According to the present invention, the deodorizing device is connected in the order of the condensation, neutralization, and adsorption treatment devices, so that the odorous gas in the gas to be treated discharged from the treatment device body is condensed beforehand. It can be removed by neutralization and adsorption treatment, so that the odorous gas removal treatment can be performed efficiently and reliably, and odorless gas can be released into the atmosphere.
[0039]
At the management center, the deodorization status of the gas to be treated is monitored by the sensor at the pH value of the acidic solution in the neutralization treatment device and the concentration of ammonia gas in the gas released into the atmosphere. It is done while. Therefore, the reliability of the deodorizing treatment can be further improved while reducing the burden on each waste discharger.
[Brief description of the drawings]
FIG. 1 is a front sectional view of a processing apparatus main body X.
FIG. 2 is a sectional view taken along line HH of FIG.
FIG. 3 is a plan view showing an arrangement of a processing apparatus main body X and a deodorizing apparatus Y.
FIG. 4 is a diagram schematically showing a deodorizing device Y.
FIG. 5 is a process chart showing a management method for composting biological waste.
[Explanation of symbols]
A: Condensing device
B: Neutralization treatment device
C: Acid solution removal device
D: Adsorption treatment device
E ₁ , En: Waste discharger
F ₁ , Fn: Technician (management technician)
S: sulfuric acid solution (acid solution)
X: Processing unit body
Y: Deodorizing device
W: Water
27: pH sensor
42: 1st activated carbon (adsorbent)
43: Second activated carbon (adsorbent)
80: Communication line (communication means)
90: Management Center

Claims (5)

In a biological waste treatment apparatus for composting biological waste, when the composting is performed by the treatment apparatus, the gas to be treated discharged to the outside of the treatment apparatus main body together with surplus air or gas such as carbon dioxide is deodorized. A deodorizing device,
A condensation treatment device that cools the gas to be treated, condenses water vapor contained in the gas into water, and separates and removes the water.
From the gas to be treated after the removal of water vapor, mainly ammonia gas contained in the gas, a neutralization treatment device for neutralizing, dissolving in an acidic solution to absorb and remove,
An adsorption treatment device is provided for adsorbing an adsorbent to separate and remove mainly acidic and neutral gases having residual odor contained therein from the gas to be treated after the removal of the water vapor and the alkaline gas, and separating and removing the same. hand,
The deodorizing apparatus, wherein the processing apparatuses are connected in the above order in a direction in which the gas to be processed passes. An acid solution removing device is disposed between the neutralizing device and the adsorption device to dissolve and remove the gaseous or atomized acidic solution in water. 2. The deodorizing device according to 1. The acidic solution removing device is provided with a sprayer for spraying water inside the washing tower, and makes the spray water and the gas to be treated come into contact with each other to dissolve and remove the gas or atomized acidic solution in the spray water. The deodorizing device according to claim 2, characterized in that: The said condensation treatment apparatus is provided with the atomizer which sprays cooling water in the inside of a cooling tower, and cools by spraying cooling water and making it directly contact with the said to-be-processed gas, The cooling characterized by the above-mentioned. The deodorizing device according to 1. A method for collectively managing a processing state of a neutralization processing device constituting a deodorizing device according to claim 1 in a central management center,
The neutralization treatment device is provided with a pH sensor for detecting the pH value of an acidic solution that absorbs an alkaline gas, and transmits the detected value to the management center via communication means. By comparing with a predetermined pH value registered in advance, it is determined whether the neutralization process is possible,
When it is determined that the pH value of the acidic solution is not more than a predetermined value, the management technician goes to a waste discharge company or the like that owns the biological waste treatment apparatus related to the determination and determines that the pH value of the acidic solution is equal to or less than a predetermined value. A method for managing a deodorizing device, comprising:

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