JP2527812Z - - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for removing bacteria in an air compressor.
The present invention is suitable for use in a sterilization apparatus that removes bacteria while removing moisture contained in air compressed by an air compressor. As is well known, it is said that bacteria live in compressed air discharged from an air compressor. In addition, the compressed air contains moisture, and when attempting to remove bacteria with a general filter, drain water adheres to the filter surface when the compressed air passes through the filter. Could be generated. [0003] Accordingly, as shown in Japanese Patent Publication No. 3-31485, the present applicant sequentially pipes an air compressor, an air dryer, a dust remover, and a sterilizer in order from the upstream, and installs the pipes in the dust remover and the sterilizer. A disinfection device provided with a drain trap was previously proposed. According to the disinfecting apparatus described in Japanese Patent Publication No. 3-31485, first, compressed air discharged from an air compressor is dehumidified by an air dryer to remove moisture, and the moisture is removed. After the removal, the dust is removed by a dust remover, then the moisture is removed again by a sterilizer, and the bacteria are removed. For this reason, in the case of the above-mentioned disinfecting apparatus, since the dust remover and the filter of the disinfectant do not have much moisture,
The environment in which bacteria grow can be eliminated, and the bacteria can be better removed. However, in the case of the sterilization apparatus described in Japanese Patent Publication No. 3-31485, compressed air is sent from an air compressor to an air dryer, a dust remover, and a sterilizer. , The piping becomes longer as a whole,
There has been a problem that the equipment cost is increased and the maintenance is troublesome. Further, in the case of the sterilization apparatus described in Japanese Patent Publication No. 3-31485, the pressure of the compressed air finally discharged from the sterilization apparatus decreases due to the length of the piping. In some cases, it is difficult to obtain an accurate discharge pressure when it is required. [0007] In order to solve such a problem, for example, a dust remover should not be provided in front of the sterilizer as in a sterilizer shown as a reference example in FIG. It can be considered. Such a disinfection device is proposed in, for example, Japanese Utility Model Publication No. 2-44834. With this configuration, the length of the pipe can be shortened, so that the above-described problem is solved. However, in this case, there is only one filter for removing dust and bacteria in the compressed air, and therefore, compared with the disinfection device described in Japanese Patent Publication No. 3-31485 described above, the disinfection is performed. There was a problem that the ability was reduced. In view of the above-mentioned problems, the present invention makes it possible to satisfactorily sterilize the compressed air discharged from the air compressor after it is dehumidified, and to perform piping until the air is finally discharged from the air compressor. Is made as short as possible so that the difference between the discharge pressure of the air compressor and the final discharge pressure from the discharge port of the sterilizer can be made as small as possible. [0010] In order to achieve the above object, the present invention has the following technical means. That is, the present invention will be described with reference to the reference numerals in the accompanying drawings corresponding to the embodiments. The present invention provides a sterilization apparatus for removing bacteria contained in air compressed by an air compressor. An air dryer 2 is connected to the pipe 1, and the air dryer 2 and a sterilizer 4 having a drain trap 15 are connected via a pipe 3 to remove water that cannot be completely removed by the air dryer 2. 15, the compressed air from which the moisture has been removed is passed through a bacteria removal membrane 8 provided in the sterilizer 4 to remove the moisture, thereby removing bacteria. a filtering apparatus, first the inside of the air dryer 2 is partitioned by a partition plate 16 except for the bottom into two first divided region and a second divided region, located upstream A cooling pipe 18 for removing moisture in the compressed air is installed in the partitioned area, and a bacteria removal membrane 8 provided in the sterilizer 4 is provided in a second partitioned area located downstream. First and second compartments are provided by installing a bacteria removal membrane 19 having a similar configuration.
A sterilization apparatus for an air compressor, comprising a common drain drap 20 for removing drain generated in a region . Since the present invention comprises the above technical means, the compressed air discharged from the air compressor is dehumidified by the air dryer 2 and the dehumidified compressed air is removed by the two bacteria removing membranes 19 and 8. , The bacteria contained in the compressed air can be satisfactorily removed. Moreover, since the length of the pipe 3 can be made the same as that when only one bacteria removal membrane 8 is passed, the pipe until it is finally discharged from the air compressor can be made as short as possible. It is possible to minimize the difference between the discharge pressure of the air compressor and the final pressure discharged from the discharge port. Next, a preferred embodiment of the sterilization apparatus of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 shows a reference example for explaining the basic configuration of the sterilization apparatus of the present invention.
The sterilization apparatus of this reference example is configured by connecting an air dryer 2 and a sterilizer 4 in series to a discharge pipe 1 of an air compressor. Are sequentially passed to face a discharge end (not shown). The air dryer 2 is constituted by a refrigeration air dryer. The air dryer 2 can be an adsorption air dryer. The sterilizer 4 includes a top cover 7 and a housing 13 detachably mounted below the top cover 7, and a cylindrical bacterial removal having an opening is provided in the housing 13. A membrane support 9 is continuously provided below, and a cylindrical bacteria removal membrane 8 is detachably attached around the cylindrical bacteria removal membrane support 9. Further, the top cover 7 is formed with a compressed air inflow port 5 connected to an outer region thereof without being opposed to the cylindrical bacterium removal membrane 8, and a cylindrical bacterium removal membrane support 9. Outflow port 6 is formed to be connected to the inside. A drain reservoir 14 is formed between the bottom of the housing 13 and the lower end of the cylindrical bacteria-removing membrane 8, and a drain trap 15 is connected to the drain reservoir 14. I'm wearing In short, the compressed air inlet 5 is connected to the outer region without facing the cylindrical bacteria removing film 8, and the outlet 5 is provided only through the drain reservoir 14 and the bacteria removing film 8. 6. The means for making the cylindrical bacteria-removing membrane 8 detachable from the cylindrical bacteria-removing membrane support 9 includes a bolt 10 that can be screwed to the top cover 7 and a terminal of the bacteria-removing membrane support 9. Is configured to connect a nut 11 and a plate 11 capable of holding the nut from below. The above-mentioned bacterium-removing membrane 8 usually has a thickness of about 0.1 μm to about 5 μm. However, in order to remove bacteria such as general bacteria, mold, and yeast,
Use a thickness of about 0.1 to 0.4 micrometer. And
Examples of the bacterial removal membrane 8 include an ultrafiltration membrane, a membrane filter, a microporous hollow fiber membrane, and a microfiber filter. FIG. 3 shows a cross-sectional shape of the bacteria removing film 8. Next, the operation of the sterilization apparatus having the above configuration will be described. First, the compressed air generated by the air compressor flows into the air dryer 2 through the discharge pipe 1 of the air compressor. The compressed air is cooled and dehumidified by the air dryer 2, and the dehumidified compressed air flows into the sterilizer 4 through the pipe 3. The compressed air that has flowed through the inlet 5 of the sterilizer 4 flows into a region outside the cylindrical bacterial removal film 8 in the sterilizer 4, where it is cooled by the outside air or the bacteria are removed. Drain water is generated by resistance or the like when passing through the membrane 8, and the water that has become the drain water accumulates in the drain reservoir 14 and is discharged to the outside by the drain trap 15. On the other hand, the bacteria are trapped on the surface of the bacteria-removing membrane 8 by passing the compressed air through the bacteria-removing membrane 8, and the bacteria-free compressed air passes through the opening of the bacteria-removing membrane support 9, and becomes cylindrical. It flows out from the inside through the outlet 6 to the outside. Therefore, the bacteria removing film 8 is not clogged by the drain water particles contained in the compressed air, and the bacteria removing film 8 adheres to the drain water particles to cause an inconvenience such as a bacterial growth environment. Can be prevented. With the above configuration, according to this sterilization apparatus, after removing the moisture in the compressed air discharged from the air compressor to the outside through the drain trap 15, the water is contained in the compressed air. Bacteria to be removed are removed by the bacteria removal membrane 8, and the compressed air that has been sterilized is discharged to the outside, and the compressed air is circulated to the outside from the air compressor discharge pipe 1 through the air dryer 2 and the sterilizer 4. The pipe 3 can be made as short as possible. Therefore, the facility cost of the piping itself can be easily reduced, and maintenance can be facilitated. Further, since the piping is easily shortened, the pressure of the compressed air in the air compressor is maintained as it is, and the compressed air is easily discharged to the outside, that is, the pressure is hardly reduced by the piping. However, in the case of the sterilization apparatus shown in FIG. 1, since the compressed air discharged from the air compressor passes through the bacteria removal membrane only once, dust and bacteria in the compressed air are removed. There has been a limit in improving the ability to remove bacteria. The present invention has been made to solve such a problem, and the present invention will be described below in detail based on embodiments. First, a first embodiment of the present invention will be described. FIG. 2 shows a first embodiment of the present invention. Hereinafter, only differences from the reference example of FIG. 1 will be described. The lower portion of the air dryer 2 of this embodiment is removed by a partition plate 16.
Is partitioned into two came, refrigerator 17 in the first compartment area located upstream forming a normal air dryer is installed a cooling pipe 18 connected. A bacteria removal film 19 having the same configuration as the bacteria removal film 8 provided in the sterilizer 4 is provided in the second partitioned area located on the downstream side. Note that a drain trap 20 is provided below the air dryer 2. In the case of the sterilization apparatus of the present embodiment, the compressed air flowing into the air dryer 2 is cooled and dehumidified by the cooling pipe 18, and the lower opening of the partition plate 16 is formed as described above. , The water is removed by the bacteria removing membrane 19 in the same manner as the sterilizer 4, and then the bacteria are removed. At this time, the drain water pools downward and is removed by the drain trap 20. As described above, since the compressed air is dehumidified by the air dryer 2, the bacteria are removed by the bacteria removing film 19, and then the bacteria are removed again by the sterilizer 4. be able to. In addition, since the bacteria removing film 19 is installed inside the air dryer 2, the length of the piping 3 of the entire apparatus can be prevented. Therefore, in the case of the sanitizing apparatus of the present embodiment, the facility cost of the piping can be reduced, and the maintenance can be easily performed. Further, since the length of the pipe is short, the pressure of the compressed air finally discharged to the outside can be prevented from being significantly reduced with respect to the pressure of the compressed air discharged from the air compressor. Thereby, an accurate discharge pressure can be obtained, and the range of use of the bacterial device in the air compressor can be expanded. As described in detail above, according to the present invention, the compressed air discharged from the air compressor is dehumidified by the air dryer, and the compressed air in the compressed air dehumidified by the air dryer is removed. Bacteria are removed by passing the bacteria through the bacteria removal membrane twice so that the bacteria can be better removed. Of course, the piping of the entire device can be easily shortened, so that the equipment cost of the piping can be reduced and maintenance can be performed. Can be facilitated. Further, since the compressed air piping can be shortened, the compressed air discharged from the air compressor can be finally discharged to the outside without much lowering the pressure.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram of a sterilization apparatus showing a reference example. FIG. 2 is a configuration diagram of a sterilization apparatus according to a first embodiment of the present invention. FIG. 3 is a cross-sectional view showing an example of a bacteria removal membrane used in the present invention. [Description of Signs] 2 Air dryer 3 Piping 4 Sterilizer 8 Bacteria removal membrane 15 Drain trap 19 Bacteria removal membrane 20 Drain trap

Claims (1)

[Claim 1] In a sterilization apparatus for removing bacteria contained in air compressed by an air compressor, an air dryer 2 is connected to a discharge pipe 1 of the air compressor. The air dryer 2 and a sterilizer 4 having a drain trap 15 are connected via a pipe 3, and water that cannot be removed by the air dryer 2 is removed from the sterilizer 4 via the drain trap 15. A sterilizing apparatus that removes the moisture and removes the moisture by passing the compressed air through a bacteria removing membrane 8 provided in the sterilizer 4 to remove bacteria. Except for the lower part, the inside is partitioned into two parts, a first partitioned area and a second partitioned area, by a partition plate 16. Installing a cooling pipe 18 for removing
A bacteria-removing membrane 8 provided in the sterilizer 4 is provided in a second partitioned area located on the downstream side.
Drain generated in bacterial removal membrane 19 installed first and second divided areas same configuration as
A disinfecting apparatus for an air compressor, comprising a common drain trap 20 for removing air.