JP3993660B2 - Article sterilizer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to foods and drinks such as tea, juice and drinking water, containers (bottles) filled with chemicals, etc., or caps applied to the containers, etc.KillingIt relates to a fungus device.
[0002]
[Prior art]
As a method for sterilizing food containers filled with food and drink such as tea, juice, and drinking water, such as plastic bottles, a step of bringing hot water of 63 ° C. or higher into contact with at least the inner surface of the bottle, and a drug for sterilization of the bottle A method of combining at least the step of bringing into contact with the inner surface is known (see, for example, JP-A-7-291236). According to this sterilization method, fungi that can be sterilized only with warm water without using a large amount of sterilizing drug are sterilized with warm water in advance, and then sterilized with chemicals in the food filled in the bottle. It is said that all microorganisms that can grow in can be completely sterilized. That is, in the sterilization method, fungi that can be sterilized only with warm water are sterilized with warm water in advance, and only fungi that cannot be sterilized with warm water are sterilized with chemicals. Therefore, according to the sterilization method, Each of the sterilization acts to supplement the other sterilizing power, and can effectively sterilize all the microorganisms that can grow in the food filled in the bottle. .
[0003]
[Problems to be solved by the invention]
However, the above-described conventional sterilization method is not yet satisfactory, and has the following problems to be solved.
(1) The above-mentioned conventional sterilization method sterilizes at least the entire inner surface of the bottle with warm water and then sterilizes the inner surface by, for example, filling (filling) the medicine into the bottle. Since the medicine is injected into the bottle in the state, the medicine discharged from the bottle after sterilization and collected and reused is diluted by mixing with warm water, and the sterilization effect is reduced in a relatively short time. For this reason, the comparatively difficult management for maintaining the density | concentration of a chemical | medical agent appropriately is required.
(2) Due to the use of warm water, there is a possibility that the warm water is scattered around the warm water sterilizer. When hot water is scattered around the apparatus, fungi and other fungi are newly generated and the working environment is deteriorated. Therefore, relatively strict handling is required to prevent the hot water from splashing around the device.
(3) When the article to be sterilized using hot water is a cap, a part of the lubricant disposed on the liner portion of the top surface wall of the cap or the inner screw portion of the skirt wall may flow out along with discharge of the hot water. There is.
In order to solve the above problems, a method of performing a rinsing process after chemical sterilization and then performing a heat sterilization process with hot air is also conceivable, but this method also has the following problems to be solved.
(1) Bacteria that cannot be sterilized unless heated are accumulated in the drug solution, and the drug may be deteriorated.
(2) There is a high possibility that bacteria that cannot be sterilized only by chemicals will flow into the hot air for the heat treatment, and there is a possibility that a sufficiently reliable sterilization treatment cannot be performed.
[0004]
The present invention has been made on the basis of the above facts, and its main purpose is to perform a sufficiently reliable sterilization treatment without deteriorating the quality of articles and medicines while ensuring a sufficiently good working environment. An object of the present invention is to provide a sterilization method and sterilization apparatus for an article.
[0012]
[Means for Solving the Problems]
Of the present inventionOne aspectIn accordance with the present invention, there is provided a hot air heating sterilization device comprising a conveying flow path for conveying articles, and a hot air supply sterilization device disposed along the conveying flow path and connected to a hot air supply source. The apparatus includes hot air supply hole means for supplying hot air supplied from the hot air supply source to the hot air supply duct to the transport flow path, and the hot air supply hole means includes the hot air supply duct, the transport flow path, The direction of the hot air that is formed between the hot air supply ducts and supplied to the transport flow path from the hot air supply duct toward the transport direction of the article in the transport flow path is defined,
In addition to the hot-air heat sterilizer, the apparatus further includes a steam-heat sterilizer that is performed by bringing steam into contact with an article, and a chemical sterilizer, and the hot-air heat sterilizer is at least the steam-heat sterilizer in the transport channel. Disposed on the downstream side of the device, the chemical sterilization device is disposed on the downstream side of the hot air heating sterilization device,
The conveying channel includes a pair of side walls spaced apart from each other, a bottom wall disposed at the lower end of each of the side walls, and a ceiling disposed at the upper end of each of the side walls. The hot air supply duct is defined by a transfer space surrounded by a wall, and the hot air supply duct includes a first duct disposed along the outside of the transfer space so as to include one of each of the side walls as a part thereof. The first duct has at least an upstream end wall and a downstream end wall, and the hot air supply hole means cuts a part of the one side wall on which the first duct is disposed, and A plurality of first hot air supply holes each having an open end formed by projecting into the first duct, and each open end of each of the first hot air supply holes is in the conveying direction of the article. Positioned upstream,
The hot air supply duct further includes a second duct disposed along the outside of the transfer space to include the other of each of the side walls as a part thereof, the second duct being an upstream end wall. And the hot air supply hole means further cuts the other part of the side wall on which the second duct is disposed and protrudes into the second duct. A plurality of second hot air supply holes each having an open end formed, the open ends of each of the second hot air supply holes being positioned upstream in the conveying direction of the article;
The hot air heating sterilization apparatus includes an upstream heating region of the transfer flow path in which the hot air supply duct includes only the first duct, and the hot air supply duct includes the first duct and the second duct. A downstream heating region of the conveying flow path configured, and the steam heating sterilization device is disposed in the upstream heating region, and the steam heating sterilization device includes the other of the side walls as a part thereof. The side wall including a steam supply box extending further upstream from the upstream end wall of the second duct along the outside of the transfer space and connected to a steam supply source, the steam supply box extending At least one steam supply hole for supplying the steam supplied to the steam supply box to the transport channel is formed on the other side of the transport channel, and the upstream heating region of the transport channel is formed in the steam supply box. A steam heating region extending from the steam heating region And a preheating region extending in the upstream direction, the sterilizer of the article, characterized in that are provided.
[0013]
In this invention, since the hot air for sterilization is supplied toward the conveyance direction of the article through the hot air supply hole means, the hot air sterilizes the article and conveys the article along the conveyance channel. be able to. Therefore, articles can be transported without installing a special transport device, and it is possible to achieve simplification and cost reduction of the device..
MaIn addition, after the steam heating sterilization process is performed by attaching vapor to substantially the entire surface of the article to be sterilized, the hot air heating sterilization process is performed by heating the article with hot air through the steam. Therefore, the non-uniform heating that tends to occur in the heat treatment using only hot air is eliminated, and the entire article is heated uniformly. Therefore, the sterilization effect is improved and the heating time is shortened as compared with sterilization using only hot air, and the production efficiency is improved. And since the chemical sterilization device is disposed downstream of the hot air heating sterilization device, the chemical sterilization device is carried in with the article completely dried, and therefore there is no possibility that the chemical is diluted with steam. .
Furthermore, the heat sterilization of the article transported through the transport channel can be performed with a relatively simple configuration. Furthermore, since hot air for sterilization is supplied toward the conveyance direction of the article through the hot air supply hole means, the hot air can sterilize the article and convey the article along the conveyance channel. . Accordingly, the articles can be conveyed without installing a special conveying device, and the simplification and cost reduction of the device can be achieved.
Furthermore, since the hot air is supplied to both sides of the article moving through the conveyance flow path, the heating efficiency is further improved. Further, articles can be transported without installing a special transport device, and simplification of the device and cost reduction can be achieved.
Furthermore, the article is first preheated with hot air in the preheating area of the upstream heating area, then heated by vapor deposition in the steam heating area of the upstream heating area, and then via the steam in the downstream heating area. Therefore, the improvement of the sterilizing effect, the shortening of the heating time, and the improvement of the production efficiency are surely achieved.
[0022]
According to the present invention, a partition wall is further disposed between the upstream heating region and the downstream heating region of the first duct, and the hot air supply duct is connected to the hot air supply via hot air supply pipe means. A hot air supply pipe means connected to a source, the upstream end of the preheating zone of the first duct, the upstream end of the downstream heating zone of the first duct and the upstream end of the second duct An article sterilization apparatus is provided, each opening in a section.
[0023]
In this invention, hot air is supplied to the upstream end of the preheating area of the first duct, the upstream end of the downstream heating area of the first duct, and the upstream end of the second duct. Sterilization and article transportation are efficiently performed, and production efficiency is improved.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of a sterilization method and a sterilization apparatus for a cap 200, which is an article constructed according to the present invention, will be described in more detail with reference to the accompanying drawings.
[0025]
First, with reference to FIG. 1, the whole structure of the sterilizer of the cap 200 is demonstrated. The sterilization device for the cap 200 includes a steam heat sterilization device 2, a hot air heat sterilization device 3, a drug sterilization device 4, and a filling / clamping device 6. Among these, in the medicine sterilization apparatus 4, the medicine sterilization process is performed by spraying the medicine onto the cap 200, and then the rinsing process is performed to wash away the medicine attached to the cap 200. In the filling / clamping device 6, the sterilized container is filled with beverage food, and the sterilized cap 200 is wound around the mouth of the container. The drug sterilization apparatus 4 and the filling / clamping apparatus 6 schematically described above do not constitute a novel feature of the present invention, and may be of a well-known configuration, so that the detailed description thereof will be described herein. Description is omitted. The cap 200 is composed of a well-known cap having a top wall and a skirt wall depending from the periphery of the top wall.
[0026]
The steam heat sterilization device 2 and the hot air heat sterilization device 3 are disposed along the transport flow path 8 in which the cap 200 as an article is transported. The hot-air heat sterilizer 3 includes a hot-air supply duct that is disposed along the transfer flow path 8 and connected to a hot-air generator 10 that is a hot-air supply source through hot-air supply pipe means. The hot air generator 10 may have a configuration known per se. The upstream end portion of the transport channel 8 is connected to the alignment hopper 11 of the cap 200 which may be of a well-known configuration, and the downstream end portion is connected to the drug sterilization apparatus 4. The hot air supply duct includes a first duct 14 disposed along the outside of the one side wall 12 so as to include a part of one side wall 12 of the transport flow path 8, and the other side wall 16 of the transport flow path 8. A second duct 18 disposed along the outside of the other side wall 16 so as to include a part thereof, and a bottom wall 20 further downstream of the transport flow path 8 so as to include a part thereof. And a third duct 22 disposed along the line. The first duct 14 has an upstream end wall 24 and a downstream end wall 26, the second duct 18 has an upstream end wall 28 and a downstream end wall 30, and the third duct 22 has an upstream end wall 32 and a downstream end wall 30. An end wall 34 is provided.
[0027]
Between the hot air supply duct (the first duct 14, the second duct 18, and the third duct 22) of the hot air heating sterilizer 3 and the transfer flow path 8, the hot air generator 10 supplies the hot air to the hot air supply duct. Hot air supply hole means for supplying the hot air thus supplied to the transport channel 8 is included. Each direction of the hot air supply hole means is regulated so that hot air supplied from the hot air supply duct to the transport channel 8 is supplied in the transport direction of the cap 200 in the transport channel 8.
[0028]
More specifically, a plurality of hot air supplied from the hot air generator 10 to the first duct 14 is supplied between the first duct 14 and the transport channel 8 to the transport channel 8. A first hot air supply hole 36 is formed. Each of the first hot air supply holes 36 has an open end formed by cutting a part of one side wall 12 in which the first duct 14 is disposed and projecting into the first duct 14. Each of the open ends is positioned on the upstream side in the transport direction of the cap 200.
[0029]
In addition, a plurality of second hot air supply holes for supplying hot air supplied from the hot air generator 10 to the second duct 18 to the transport channel 8 are provided between the second duct 18 and the transport channel 8. 38 is formed. Each of the second hot air supply holes 38 has an open end formed by cutting a part of the other side wall 16 in which the second duct 18 is disposed and projecting into the second duct 18. Each of the open ends is positioned on the upstream side in the transport direction of the cap 200.
[0030]
Further, a plurality of third hot air supply holes for supplying hot air supplied from the hot air generator 10 to the third duct 22 to the transfer flow path 8 are provided between the third duct 22 and the transfer flow path 8. 39 is formed. Each of the third hot air supply holes 39 has an open end formed by cutting a part of the bottom wall 20 in which the third duct 22 is disposed and projecting into the third duct 22. Each of the open ends is positioned on the upstream side in the transport direction of the cap 200. The first hot air supply hole 36, the second hot air supply hole 38, and the third hot air supply hole 39 constitute a hot air supply hole means.
[0031]
The hot air heating sterilization apparatus 3 includes an upstream heating area A of the conveyance flow path 8 in which the hot air supply duct is configured only by the first duct 14, and the hot air supply duct is configured by the first duct 14 and the second duct 18. And a downstream heating region B of the transport channel 8 to be transported. A steam sterilizer 2 is disposed in the upstream heating area A. The steam sterilizer 2 includes a steam supply box 44 connected to a steam supply source 42. The steam supply source 42 can be easily secured by using a steam supply line known per se used in the factory in the embodiment. The steam supply box 44 is disposed so as to extend further upstream from the upstream end wall 28 of the second duct 18 along the outside of the transfer flow path 8 so as to include the other side wall 16 as a part thereof. At the other side wall 16 in which the steam supply box 44 extends, at least one steam supply hole for supplying the steam supplied to the steam supply box 44 to the transport flow path 8 is formed. In this embodiment, the steam supply hole is composed of two long holes.
[0032]
The upstream heating area A of the transport flow path 8 includes a steam heating area D facing the steam supply box 44 and a preheating area C extending further upstream from the steam heating area D. The steam heating region D includes the first duct 14 and the steam supply box 44, and the preheating region C includes the first duct 14. The hot air heating sterilization apparatus 3 further includes a most downstream heating region E of the conveying flow path 8 in which the hot air supply duct is configured by only the third duct 22. The most downstream heating area E is positioned further downstream of the downstream heating area B of the conveyance flow path 8.
[0033]
A partition wall 45 is disposed between the upstream heating area A and the downstream heating area B of the first duct 14. The hot air supply duct is connected to the hot air generator 10 through hot air supply pipe means. The hot air supply pipe means includes an upstream end of the preheating region C in the first duct 14, an upstream end of the downstream heating region B in the first duct 14, an upstream end in the second duct 18, and a third duct. 22 is opened at the upstream end of the most downstream heating region E.
[0034]
More specifically, the hot air supply pipe 46 connected to the hot air generator 10 branches into a hot air discharge pipe 48 and a hot air supply pipe 50 at the T-junction. The hot air discharge pipe 48 is provided with an electromagnetic opening / closing valve 52 and an exhaust blower 54. The hot air supply pipe 50 branches into hot air supply pipes 56, 58 and 60 at the crossroads. The hot air supply pipe 50 is provided with an electromagnetic opening / closing valve 53. The hot air supply pipe 56 branches into hot air supply pipes 62 and 64 at the T-junction. The hot air supply pipe 62 is opened at the upstream end wall 24 of the first duct 14, and the hot air supply pipe 64 is opened immediately downstream of the partition wall 45 of the first duct 14. The hot air supply pipe 58 branched at the cross road is opened to the downstream side of the upstream end wall 28 of the second duct 18, and the hot air supply pipe 60 is opened to the upstream end wall 32 of the third duct 22. ing. The hot air supply pipes 46, 50, 56, 58, 60, 62 and 64 constitute hot air supply pipe means.
[0035]
The steam supply box 44 has an upstream end wall 66 and a downstream end wall 68, and is connected to the steam supply source 42 via a steam supply pipe 70. The steam supply pipe 70 is inserted into the steam supply box 44 from the upstream end wall 66, and its downstream end is substantially blocked by the downstream end wall 68. The steam supply pipe 70 is disposed in the steam supply box 44 so as to extend along the outer side of the other side wall 16 of the transport flow path 8. A plurality of steam supply holes 72 are opened in the steam supply pipe 70 in the steam supply box 44 toward the transport flow path 8. Two elongated holes 75 extending in the transport direction of the cap 200 are formed in the other side wall 16 of the transport flow path 8 corresponding to the steam supply box 44. An electromagnetic opening / closing valve 76 is disposed in the steam supply pipe 70. The steam supply box 44 is connected to the upstream side of the exhaust blower 54 on the downstream side of the electromagnetic on-off valve 52 of the hot air discharge pipe 48 via the steam exhaust pipe 78. As a result, a part of the steam in the steam supply box 44 is always exhausted by the exhaust blower 54, and surplus steam is exhausted. The chamber 80 indicated by the two-dot chain line in FIG. 1 is maintained at a cleanliness of class 10,000 or higher, and the chamber 82 indicated by the two-dot chain line in FIG. The outside of the chambers 80 and 82 is in the atmospheric state.
[0036]
By opening the electromagnetic on-off valve 53 of the hot air supply pipe 50, the hot air from the hot air generator 10 is sent to the first duct 14, the second duct 18 and the third duct 22 through the hot air supply pipe means. And supplied from each upstream end. The hot air supplied into the first duct 14, the second duct 18, and the third duct 22 corresponds to the corresponding first hot air supply hole 36, second hot air supply hole 38, and third hot air supply hole 39. Is supplied to the inside of the transfer channel 8. Further, by opening the electromagnetic on-off valve 76 of the steam supply pipe 70, steam is supplied from the steam supply source 42 into the steam supply box 44 through the steam supply pipe 70. The steam supplied into the steam supply box 44 is supplied into the transfer channel 8 through the long hole 75 of the other side wall 16. The electromagnetic opening / closing valve 52 is normally closed.
[0037]
Next, the steam heating sterilization device 2 and the hot air heating sterilization device 3 of the cap 200 configured as described above will be described with reference to FIGS. 2 to 12, the same parts as those in FIG. 1 are denoted by the same reference numerals.
[0038]
First, referring to FIG. 2 to FIG. 4, in the hot air heat sterilizer 3, the transport flow path 8 in which the third duct 22 is disposed is disposed so as to extend substantially horizontally. 11 to the upstream portion of the transport channel 8 in which the third duct 22 is disposed, the transport channel 8 is disposed so as to be inclined toward the transport direction of the cap 200. 2 and 3, reference numeral 5 indicates an inspection rack for the alignment hopper 11.
[0039]
FIG. 5 shows a cross section of the transfer flow path 8 between the alignment hopper 11 and the transfer flow path 8 (the transfer flow path 8 in the preheating region C) in which the first duct 14 is disposed. The conveyance flow path 8 includes eight rod members 84 extending in the conveyance direction, and rectangular holding members that fix the rod members 84 at a distance from each other so that a substantially rectangular conveyance space is formed. 86. Each of the rod members 84 is fixed to the inside of the holding member 86 by welding. Although not shown, the transport flow path 8 connecting the downstream end of the downstream heating area B and the upstream end of the most downstream heating area E in which the third duct 22 is disposed is also the transport flow shown in FIG. The configuration is the same as that of the road 8.
[0040]
FIG. 6 shows a cross section of the transport flow path 8 and the first duct 14 in the preheating area C of the upstream heating area A. The transport channel 8 is arranged at a pair of side walls 12 and 16 that are spaced apart from each other, a bottom wall 90 that is disposed at the lower ends of the side walls 12 and 16, and an upper end of the side walls 12 and 16. It is defined by a transfer space surrounded by the ceiling wall 92 provided. The side walls 12 and 16, the bottom wall 90, and the top wall 92 are each formed from a plate member. The conveyance space is substantially rectangular. A slight gap is formed between the ends of the bottom wall 90 and the top wall 92 and the side wall 12 on one side. These gaps function as hot air escape passages. The first duct 14 includes a channel member 94 disposed on the side wall 12 along the outside of the transfer space so as to include the side wall 12 on one side as a part thereof. The channel member 94 has mounting flange portions 94a and 94b extending in directions away from each other at its open end. The side walls 12 and 16 have upper mounting portions 12 a and 16 a extending further upward from the top wall 92, and lower mounting portions 12 b and 16 b extending further downward from the bottom wall 90.
[0041]
A plurality of block members 96 each having a substantially rectangular parallelepiped shape and formed with an internal thread portion are interposed between the upper mounting portions 12a and 16a of the side walls 12 and 16 at intervals in the conveying direction of the cap 200. On the other hand, the upper mounting portions 12a and 16a of the side walls 12 and 16 and the mounting flange portion 94a of the channel member 94 are fastened by two bolts 97, respectively. Similarly, a plurality of block members 98 that are substantially rectangular parallelepiped and formed with female thread portions are interposed between the lower mounting portions 12b and 16b of the side walls 12 and 16 at intervals in the conveying direction of the cap 200, and the blocks The lower mounting portions 12b and 16b of the side walls 12 and 16 and the mounting flange portion 94b of the channel member 94 are fastened to the member 98 by two bolts 97, respectively.
[0042]
A plurality of first hot air supply holes 36 each having an open end 36 a formed by cutting a part of the side wall 12 and projecting it into the first duct 14 are formed in the side wall 12 on one side. (See also FIGS. 8, 9 and 10). Each open end 36 a of the first hot air supply hole 36 is positioned on the upstream side in the transport direction of the cap 200. A plurality of long holes 75 extending in the conveying direction of the cap 200 are formed in the other side wall 16. These long holes 75 are provided in order to allow a stop pin (described later) of a stopper (not shown) that prevents the movement of the cap 200 to enter and exit the transfer space in the transfer flow path 8.
[0043]
FIG. 7 shows a cross section of the transport flow path 8, the first duct 14, and the steam supply box 44 in the steam heating area D in the upstream heating area A. Since the conveyance flow path 8 and the first duct 14 are obtained by extending those existing in the preheating region C and there is no substantial difference in configuration, description thereof will be omitted. The steam supply box 44 has substantially the same configuration as the first duct 14. That is, the steam supply box 44 includes a channel member 102 disposed on the side wall 16 along the outside of the transfer space so as to include the other side wall 16 as a part thereof. The channel member 102 has mounting flange portions 102a and 102b extending in directions away from each other at its open end, and is connected to the block members 96 and 98 via the mounting flange portions 102a and 102b in the same manner as described above. Each is fastened by two bolts 97. The steam supply pipe 70 disposed in the channel member 102 is attached to the bottom of the channel member 102 by two U-shaped rod members 104 and nuts 106 (see FIG. 11). As shown in FIG. 11, a drain pipe 108 is provided at the bottom of the downstream end of the channel member 102. Although not shown in the drawing, a drain pipe is also disposed at the bottom portion immediately upstream of the partition wall 45 (see FIG. 1) of the first duct 14.
[0044]
FIG. 8 shows a cross section of the transport flow path 8, the first duct 14, and the second duct 18 in the downstream heating region B. Since the conveyance flow path 8 and the first duct 14 are obtained by extending those existing in the preheating region C and there is no substantial difference in configuration, description thereof will be omitted. The second duct 18 has substantially the same configuration as the first duct 14. That is, the second duct 18 includes a channel member 110 disposed on the side wall 16 along the outside of the transport space so as to include the other side wall 16 as a part thereof. The channel member 110 has mounting flange portions 110a and 110b extending in directions away from each other at the open end thereof, and is connected to the block members 96 and 98 via the mounting flange portions 110a and 110b in the same manner as described above. Each is fastened by two bolts 97. A second hot air supply hole 38 having substantially the same configuration as the first hot air supply hole 36 is formed in the other side wall 16. That is, a plurality of second hot air supply holes 38 each having an opening end 38 a formed by cutting a part of the side wall 16 and projecting it into the second duct 18 are formed in the other side wall 16. (See also FIGS. 9 and 10). Each open end 38 a of the second hot air supply hole 38 is positioned on the upstream side in the transport direction of the cap 200.
[0045]
FIG. 12 shows a cross section of the conveyance flow path 8 and the third duct 22 in the most downstream heating region E. The conveyance flow path 8 and the third duct 22 have substantially the same configuration as those existing in the preheating region C. In the cap 200, the structure of the transport flow path 8 is defined so as to roll on the transport flow path 8 in the upstream heating area A and the downstream heating area B, but in the most downstream heating area E, the top surface wall is set upward. The structure of the transport flow path 8 is defined so that the transport end can be transported with the open end facing downward. Although not shown in the figure, this change in the transport mode is defined by the transport flow path 8 between the downstream heating region B and the most downstream heating region E. Due to this, the transport flow path 8 and the third duct 22 in the most downstream heating region E are transported in the preheating region C as can be easily understood by comparing FIG. 12 and FIG. The flow path 8 and the first duct 14 are rotated by 90 ° in the attached state in the counterclockwise direction in FIG.
[0046]
That is, in the conveyance flow path 8 in the most downstream heating area E, the top wall 92 of the conveyance flow path 8 in the preheating area C defines the side wall (92) on one side, and the bottom wall 90 is the side wall (90) on the other side. The side wall 12 on one side defines the bottom wall (12) and the side wall 16 on the other side is positioned to define the top wall (16). The third duct 22 includes a channel member 112 disposed on the bottom wall (12) along the lower outer side of the transfer space so as to include the bottom wall (12) as a part thereof. The channel member 112 has mounting flange portions 112a and 112b extending in directions away from each other at the open end thereof, and is connected to the block members 96 and 98 through the mounting flange portions 112a and 112b in the same manner as described above. Each is fastened by two bolts 97. A third hot air supply hole 39 having substantially the same configuration as the first hot air supply hole 36 is formed in the bottom wall (12). That is, the bottom wall (12) has a plurality of third hot air supply holes each having an open end 39a formed by cutting a part of the bottom wall (12) and projecting it into the third duct 22. 39 is formed. Each open end 39 a of the third hot air supply hole 39 is positioned on the upstream side in the transport direction of the cap 200.
[0047]
Next, with reference to FIGS. 1-4, the effect | action of the steam heating sterilization apparatus 2 and the hot air heating sterilization apparatus 3 of the cap 200 is demonstrated. The caps 200 sent out from the alignment hopper 11 to the transport flow path 8 in the state of being sequentially aligned are first preheated by hot air in the preheating area C in the upstream heating area A, and then in the steam heating area D in the upstream heating area A. Steam is blown in addition to hot air. The cap 200 to which the vapor has adhered is then heated by hot air in the order of the downstream heating region B and the most downstream heating region E. The cap 200 with the vapor substantially adhered to the entire surface is heated by hot air, thereby preventing local heating of the cap 200 and heating the entire cap uniformly. Therefore, the hot air heating sterilization of the entire cap 200 is sufficiently performed. Is done.
[0048]
The temperature of the hot air is supplied at about 98 ° C. from the hot air generator 10 and is introduced at about 85 ° C. at the inlets of the first duct 14, the second duct 18 and the third duct 22. Moreover, it is preferable that the atmospheric temperature of the downstream end of the downstream heating area | region B is about 72 to 73 degreeC. As a result, the cap 200 unloaded from the downstream heating region B can be transported to the most downstream heating region E while being kept at about 67 ° C. to 68 ° C. Similar temperature control is performed in the most downstream heating region E. In order to obtain a heat sterilization effect sufficiently reliably, it is important that the cap 200 is held at a minimum of 60 ° C. or more for 10 seconds to 15 seconds. Therefore, the hot air temperature sufficiently satisfies this temperature condition. . The time for the heat sterilization can be easily satisfied by controlling the time for passing through the upstream heating area A, the downstream heating area B, and the most downstream heating area E to 10 seconds to 15 seconds or more. The temperature of the steam may be about 100 ° C.
[0049]
Since the opening ends 36a, 38a and 39a of the first hot air supply hole 36, the second hot air supply hole 38 and the third hot air supply hole 39 are positioned on the upstream side in the transport direction, The hot air supplied to the duct 14, the second duct 18, and the third duct 22 is supplied to the transport flow path 8 from the respective open ends 36 a, 38 a, and 39 a toward the transport direction of the cap 200 (blows out). Therefore, the hot air can heat and sterilize the cap 200 and transport the cap 200 along the transport flow path 8. In the most downstream heating region E, the vapor attached to the cap 200 is completely evaporated and dried. The cap 200 that has been subjected to the steam and hot air heat sterilization process as described above is then conveyed toward the drug sterilization apparatus 4.
[0050]
The preheating area C of the conveying flow path 8 in the upstream heating area A defines a preliminary hot air heating sterilization process, and the steam heating area D defines a steam heating sterilization process. The downstream heating area B and the most downstream heating area E define the main hot air heating sterilization process. The chemical sterilization process performed on the cap 200 in the chemical sterilization apparatus 4 is performed by a chemical sterilization process positioned after the hot air heat sterilization process.
[0051]
When a trouble occurs in the transport line (for example, when the cap 200 stays longer than a predetermined time), the electromagnetic on-off valve 53 is closed and the electromagnetic on-off valve 52 is opened. The supply of hot air from the hot air generator 10 to the first duct 14, the second duct 18 and the third duct 22 is stopped, and the hot air from the hot air generator 10 is exhausted by the exhaust blower 54 via the hot air supply pipe 48. Discharged. This prevents excessive heating of the cap 200 and prevents problems such as liner deterioration.
[0052]
Next, an operation sequence (starting sequence) before the steam heating sterilization device 2 and the hot air heating sterilization device 3 of the cap 200 start a steady operation will be described with reference to FIG. In FIG. 4, reference numeral S <b> 1 is a first fullness detection sensor of the cap 200, and is disposed at the downstream end of the downstream heating region B. Reference numeral S <b> 2 is a second fullness detection sensor of the cap 200, which is disposed slightly upstream of the preheating region C. The first and second fullness detection sensors S1 and S2 are each composed of a transmissive optical sensor known per se. Reference numeral ST <b> 1 is a first stopper of the cap 200 and is disposed at the downstream end of the downstream heating region B. Reference numeral ST <b> 2 is a second stopper of the cap 200 and is disposed slightly upstream of the steam heating region D. The first and second stoppers ST1 and ST2 include a so-called pen cylinder and a stop pin mounted on the output side thereof. Each of the stop pins protrudes into the transport space of the transport flow path 8 to prevent the cap 200 from moving (the stopper is in a closed state), and moves away from the transport space of the transport flow path 8 to move the cap 200. Are attached to the corresponding pen cylinders so as to be movable between the non-acting positions (the stopper is in the open state).
[0053]
The start and steady operation of the steam heating sterilization device 2 and the hot air heating sterilization device 3 are performed based on signals from various switches (not shown) and various sensors, and a controller (not shown) outputs each of the steam heating sterilization device 2 and the hot air heating sterilization device 3. This is performed according to a predetermined program by sending an output signal to the unit. Before starting, the first stopper ST1 is closed and the second stopper ST2 is open. Hot air is supplied from the hot air generator 10 to the first duct 14, the second duct 18, and the third duct 22, and steam is supplied from a steam supply source 42 to a steam supply box 44. First, when a start switch of an operation panel (not shown) is turned on, the alignment hopper 11 starts to operate, and the cap 200 is aligned and fed to the transport flow path 8. When the second full detection sensor S2 detects that the cap 200 is full, the second stopper ST2 is changed from the open state to the closed state. 20 seconds after the second stopper ST2 is closed, the first stopper ST1 is changed from the closed state to the open state. During the time of 20 seconds, the cap 200 retained in the upstream heating area A and the downstream heating area B is sterilized by heating.
[0054]
When the first stopper ST1 is in the open state, the cap 200 retained in the upstream heating area A and the downstream heating area B in the transport flow path 8 is started to be transported in the downstream direction in the aligned state. After 1.8 seconds have elapsed since the first stopper ST1 is opened, the first stopper ST1 is changed from the opened state to the closed state. After 0.2 seconds have elapsed since the first stopper ST1 is closed, the second stopper ST2 is changed from the closed state to the open state. The steam heat sterilizer 2 and the hot air heat sterilizer 3 repeat the above sequence by the controller, and then when the first full detection sensor S1 continuously detects the cap 200 for 1 second, the operation is shifted to the steady operation. Both the first stopper ST1 and the second stopper ST2 are held in the open state, and the automatic supply control of the cap 200 is performed by the alignment hopper 11 by the second full detection sensor S2.
[0055]
When the second full detection sensor S2 continuously detects the cap 200 for 120 seconds, the controller determines that a trouble has occurred in the transport line of the cap 200. Based on this determination, as described above, the electromagnetic on-off valve 53 shown in FIG. 1 is closed and the electromagnetic on-off valve 52 is opened. The supply of hot air from the hot air generator 10 to the first duct 14, the second duct 18 and the third duct 22 is stopped, and the hot air from the hot air generator 10 is exhausted by the exhaust blower 54 via the hot air supply pipe 48. Discharged.
[0056]
The preferred embodiments of the sterilization method and sterilization apparatus for articles constructed according to the present invention have been described above with reference to the accompanying drawings, but the present invention is not limited to the above-described embodiments, and the scope of the present invention is not limited thereto. Various changes or modifications can be made without departing. For example, in the above embodiment, the steam heat sterilization device 2 and the hot air heat sterilization device 3 of the cap have been described. However, the article to be sterilized is not limited to the cap, and other food and drink such as a plastic container (bottle). Or the packaging material used for a chemical | medical agent etc. is also contained as the object. Moreover, in the said embodiment, although the most downstream heating area | region E comprised by the conveyance flow path 8, the 3rd duct 22, the hot air supply hole 39 grade | etc., Is provided, the upstream heating area | region A and the downstream heating area | region B are equipped. If a sufficiently reliable sterilizing effect can be obtained, this may be omitted. In some cases, the preheating zone C in the upstream heating zone A and the first duct 14 in the steam heating zone D are omitted, and only the steam heating zone is used.
[0057]
【The invention's effect】
According to the article sterilization method and the sterilization apparatus of the present invention, it is possible to perform a sufficiently reliable sterilization process without deteriorating the quality of the article or medicine while ensuring a sufficiently good working environment. Further, the bactericidal effect is improved and the heating time is shortened, so that the production efficiency is improved. Furthermore, simplification and cost reduction of the apparatus can be achieved.
[Brief description of the drawings]
FIG. 1 is a configuration diagram schematically showing a main part of an embodiment of an article sterilization apparatus configured according to the present invention.
FIG. 2 is a schematic front view showing a main part of an embodiment of an article sterilization apparatus constructed according to the present invention.
FIG. 3 is a view of FIG. 2 as viewed from the left, with a part thereof omitted.
4 is a diagram showing in more detail the main part of the article sterilization apparatus shown in FIG. 2. FIG.
5 is a cross-sectional view taken along the line AA in FIG. 4;
6 is a cross-sectional view taken along the line BB in FIG.
7 is a cross-sectional view taken along the line CC in FIG. 4;
8 is a cross-sectional view taken along the line DD in FIG. 4;
9 is a cross-sectional view taken along the line EE in FIG.
10 is an enlarged cross-sectional view of a part A in FIG.
11 is a perspective view showing a steam supply box that is a part of the steam heat sterilizer shown in FIG. 4. FIG.
12 is a cross-sectional view taken along the line F-F in FIG. 3;
[Explanation of symbols]
2 Steam heat sterilizer
3 Hot air heating sterilizer
4 drug sterilizer
6 Filling and tightening device
8 Transport channel
10 Hot air generator
11 Alignment hopper
14 First duct
18 Second duct
22 Third duct
36 First hot air supply hole
38 Second hot air supply hole
39 Third hot air supply hole
36a, 38a, 39a Open end
40 Steam heat sterilizer
42 Steam supply source
44 Steam supply box
54 Exhaust blower
A Upstream heating area
B Downstream heating area
C Preheating area
D Steam heating area
E The most downstream heating zone

Claims (2)

A hot air heating and sterilizing device including a conveying channel through which an article is conveyed and a hot air supply duct disposed along the conveying channel and connected to a hot air supply source. Hot air supply hole means for supplying hot air supplied from a supply source to the hot air supply duct to the transport flow path, the hot air supply hole means being formed between the hot air supply duct and the transport flow path The direction of the hot air supplied from the hot air supply duct to the transport flow path is defined so as to be supplied toward the transport direction of the article in the transport flow path,
In addition to the hot air heat sterilizer, the apparatus further includes a steam heat sterilizer that is performed by bringing steam into contact with an article, and a chemical sterilizer, and the hot air heat sterilizer is at least the steam heat sterilizer in the transport channel. Disposed on the downstream side of the apparatus, the chemical sterilization apparatus is disposed on the downstream side of the hot-air heat sterilization apparatus, and the transport flow path includes a pair of side walls spaced apart from each other, and the side walls Each of the side walls is defined by a conveying space surrounded by a bottom wall disposed at each lower end portion and a top wall disposed at each upper end portion of the side walls, and the hot air supply duct is A first duct disposed along the outside of the transfer space so as to include one of them as a part thereof, the first duct having at least an upstream end wall and a downstream end wall, and supplying the hot air A hole means is a part of the one of the side walls in which the first duct is disposed. A plurality of first hot air supply holes each having an open end formed by cutting and projecting into the first duct, the open ends of each of the first hot air supply holes being the article; Is positioned upstream in the transport direction of
The hot air supply duct further includes a second duct disposed along the outside of the transfer space to include the other of each of the side walls as a part thereof, the second duct being an upstream end wall. And the hot air supply hole means further cuts the other part of the side wall on which the second duct is disposed and protrudes into the second duct. A plurality of second hot air supply holes each having an open end formed, the open ends of each of the second hot air supply holes being positioned upstream in the conveying direction of the article;
The hot air heating sterilization apparatus includes an upstream heating region of the transfer flow path in which the hot air supply duct includes only the first duct, and the hot air supply duct includes the first duct and the second duct. A downstream heating region of the conveying flow path configured, and the steam heating sterilization device is disposed in the upstream heating region, and the steam heating sterilization device includes the other of the side walls as a part thereof. The side wall including a steam supply box extending further upstream from the upstream end wall of the second duct along the outside of the transfer space and connected to a steam supply source, the steam supply box extending At least one steam supply hole for supplying the steam supplied to the steam supply box to the transport channel is formed on the other side of the transport channel, and the upstream heating region of the transport channel is formed in the steam supply box. A steam heating region extending from the steam heating region Extending upstream direction and a preheating area,
An article sterilization apparatus characterized by the above. A partition wall is disposed between the upstream heating area and the downstream heating area of the first duct, and the hot air supply duct is connected to the hot air supply source via hot air supply pipe means, and the hot air supply Pipe means open to the upstream end of the preheating zone of the first duct, the upstream end of the downstream heating zone of the first duct and the upstream end of the second duct, respectively. The sterilizing apparatus for articles according to claim 1 .

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