JPH10136954A - Sterilization of powder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To sufficiently disinfect a powder for a food or a feed and prepare a processed food or feed without any residual various germs by at least partially ionizing a gas or a mixture thereof with a liquid and bringing the resultant ionized mixture into contact with a powder. SOLUTION: A gas in a gas cylinder 1 is passed through a nebulizer 2 filled with a liquid such as H2 O2 and led to a hollow electrode 3. The resultant gas, together with a gas-liquid mixture fed from a blowoff port 4, is at least partially ionized in a plasma producing chamber 7. The ionized gas (or a mixture of the ionized gas with the liquid) is fed to a screw conveyor 10, passed through an air slide 9 and fed to a silo 12 while being brought into contact with a powder.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a method for sterilizing powders such as edible or feed powders.

[0002]

2. Description of the Related Art An ultraviolet irradiation method is widely used as a sterilization method, and it is possible to sterilize powder such as flour by irradiation with ultraviolet light. However, since the sterilizing power of ultraviolet rays is weak, sufficient sterilization cannot be performed, and various bacteria may remain in processed foods and feeds using these powders.

Accordingly, an object of the present invention is to provide a method for more efficiently sterilizing powders such as edible or feed powders.

[0004]

SUMMARY OF THE INVENTION The present invention relates to a method for sterilizing powder, which comprises contacting powder with a gas or a mixture of gas and liquid at least partially ionized by an electric field.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail. In the sterilization method of the present invention, a mixture of a gas or a gas and a liquid at least partially ionized by an electric field, or a mixture of a gas or a gas and a liquid at least partially ionized by an energy converter irradiated with electromagnetic waves. Used.

The method of the present invention includes, for example, the following 3
There are two methods. A method of passing a gas or a mixture of gas and liquid in an electric field to ionize at least a part of the gas or the mixture, and then contacting the gas or mixture with the at least partially ionized gas or mixture with the powder outside the electric field. (First method). A method in which at least a part of the gas is ionized by passing the gas through an electric field, the obtained at least a part of the gas is mixed with a mixture of a gas and a liquid, and the obtained mixture is brought into contact with a powder outside the electric field (No. Method 2). A method of introducing a mixture of a gas and a liquid into an electric field to ionize at least a portion of the mixture, and bringing the mixture at least partially ionized into contact with the powder in the electric field (third method).

[0007] In the method of the present invention, it is preferable to sterilize using a mixture of at least partially ionized gas and liquid using a pulse voltage to generate an electric field.

The rising speed of the pulse voltage is suitably in the range of 0.01 kV / ns to 10 kV / ns. Pulse voltage rise rate is 0.01
If it is less than kV / ns, the bactericidal effect tends to decrease.
If the rising speed of the pulse voltage exceeds 10 kV / ns, there is no adverse effect on the sterilizing effect, but it is difficult to generate a voltage. A preferable range of the rising speed of the pulse voltage is 0.
The range is from 1 kV / ns to 1 kV / ns.

The pulse width of the pulse voltage is 10 ⁻⁹ seconds to 1
It is appropriate in the range of 0 ^-1 seconds. Although the pulse width does not greatly affect the sterilizing effect, the pulse width that can be oscillated is in the above range. The preferred range of the pulse width is 10 ^-8 seconds
10 ^-6 seconds.

The peak voltage of the pulse voltage is 1 kVp to 10 kVp.
Suitably, it is in the range of 0 kVp. If the peak voltage is less than 1 kVp, the electric field strength is small and the peak voltage is 1 kVp.
If it exceeds 00 kVp, there is a problem that it is necessary to increase the size of the device. The preferred range of the peak voltage is 8 to 50
kVp.

The frequency of the pulse voltage is 1 Hz to 100 kHz.
Suitably, it is in the range of z. If the frequency is less than 1 Hz, the sterilization efficiency decreases, and if it exceeds 100 kHz, the temperature of the gas in the electric field increases significantly. The preferred range of the frequency of the pulse voltage is in the range of 50 Hz to 500 Hz.

The ionizing method includes a method of passing a gas or a mixture of a gas and a liquid in an electric field to ionize at least a part of the gas or the mixture (first and third methods); and a method of passing a gas in an electric field. There is a method (second method) of obtaining a mixture of a gas and a liquid, which is at least partially ionized, by mixing the obtained gas at least partially ionized and a mixture of the gas and the liquid outside the electric field.

The electric field can be generated, for example, by using at least one pair of a high voltage electrode and a ground electrode, and applying a certain voltage or more between the electrodes. Such an electric field generator can use the high-voltage electrode and the ground electrode used for corona discharge or the like as they are, for example,
At least one of the high voltage electrode and the ground electrode may be coated with a solid dielectric.
There is no particular limitation on the solid dielectric, but, for example, ceramics such as quartz, or a laminate of Hypalon rubber, polyethylene terephthalate, or the like can be used. Further, both the high-voltage electrode and the ground electrode may be metal electrodes.

The number and shape of the high-voltage electrode and the ground electrode are not particularly limited, and can be appropriately determined depending on whether it is necessary to ionize a gas or a mixture of a gas and a liquid passing through the generated electric field. . For example, when the flow rate of a gas or a mixture of a gas and a liquid is large, for the purpose of ionizing at a certain rate or more, it is possible to adjust so that the residence time in an electric field becomes longer. A plurality of ground electrodes may be provided in parallel, or at least one of the high voltage electrode and the ground electrode may be formed in a band shape. Further, in order to increase the surface area of the high-voltage electrode for the purpose of preventing local discharge, the electrode may be provided with protrusions, irregularities, or the like.

In the first and third methods for obtaining an ionized body of a mixture of gas and liquid in the present invention, the gas of "mixture of gas and liquid" passing through an electric field is a gas capable of being ionized in the electric field. It is. Such gases include, for example, oxygen, nitrogen, rare gases (argon, helium, and neon), hydrogen, air, and the like. Among rare gases, argon is preferable because it is easily ionized and is excellent in cost. Helium is preferable from the viewpoint that ionization is likely to be continuous. In particular, argon can be more preferably used because it has a specific gravity closer to air than helium and is easy to handle under atmospheric pressure. Further, two or more of the above gases may be mixed and used in combination.

The liquid is, for example, water, hydrogen peroxide,
It can be hydrogen peroxide solution, peracetic acid, ethanol, a mixture of ethanol and water, and the like. When using aqueous hydrogen peroxide, the concentration of hydrogen peroxide is preferably, for example, 50% or less in terms of hydrogen peroxide concentration from the viewpoint of being commercially available and easily available. At a concentration lower than that, a commercially available aqueous solution of hydrogen peroxide can be diluted with water to appropriately adjust the concentration in consideration of sterilization conditions and the like. However, considering the sterilizing effect, it is preferable to use 1% or more of hydrogen peroxide solution.

The liquid used to ionize at least a part of the photocatalyst can be water irradiated with excitation light to the photocatalyst in the presence of the photocatalyst. The photocatalyst used here converts water into hydroxyl ions (OH ⁻ ) and hydrogen ions (H
⁺ ) Can be used without particular limitation as long as they have the ability to dissociate. Examples of the photocatalyst include titania, strontium titanate, zinc oxide and cadmium sulfide. These photocatalysts
They can be used alone or in combination.

Furthermore, the photocatalyst is one or more selected from the group consisting of titania, strontium titanate, zinc oxide and cadmium sulfide, and one or more selected from the group consisting of platinum, rhodium, ruthenium oxide and nickel oxide.
It can also be a complex (support) with two or more species. For example, Pt / TiO ₂ , Rh / SrTiO ₂ , R
u / SrTiO ₂ , Pt / SrTiO ₂ , RuO ₂ / T
iO ₂ / Pt, may be mentioned RuO ₂ / TiO ₂ or the like. Further, the photocatalyst and the metal or metal oxide serving as the carrier can be used together without being complexed.

The excitation light of the photocatalyst varies depending on the type of the photocatalyst, but is usually ultraviolet light having a wavelength of 200 to 400 nm. The amount of the photocatalyst with respect to the unit amount of water, the contact time between the photocatalyst irradiated with the excitation light and the water, the temperature, etc. are determined by the amount of water dissociated by the action of the photocatalyst (produced hydroxyl ion (OH ⁻ ) H ⁺ ). Further, water hydroxide ion (OH ^-) and hydrogen ions (H ⁺⁾
Since the amount of A has an effect on the germicidal effect, it is appropriately adjusted in consideration of the desired germicidal effect.

The shape and structure of the photocatalyst are not particularly limited. For example, the photocatalyst may be in the form of a powder or a plate. The powdery photocatalyst has a particle size of, for example, 20 to 5 particles.
000 Angstroms.

The plate-shaped photocatalyst is effective for continuously generating photodissociated water, and is composed of ultraviolet light (254 nm, 400 nm).
When W) is used, for example, dissociated water obtained by contacting a photocatalyst having an area of 100 cm ² with 1 liter of water for about 60 to 180 minutes can be used. Alternatively, photodissociated water can be obtained by irradiating excitation light to a column or the like filled with photocatalyst particles and further flowing water.

In the present invention, water is photodissociated, but additives may be added to the water as long as the photodissociation of water is not hindered. For example, examples of the additive include alcohol and hydrogen peroxide.

The liquid is preferably in the form of a mist,
The atomized liquid can be generated by passing the gas as a carrier gas through a nebulizer connected to a liquid supply. Further, the atomized gas can also be generated by bubbling a carrier gas into these. Also, "mixture of gas and liquid"
Can also be prepared by using a part of gas as a carrier gas and mixing the mist obtained by the gas and the carrier gas with the remaining gas.

Gas (all gases including carrier gas)
The ratio between the liquid and the liquid is not particularly limited, but is preferably in the range of 1 mg to 100 mg per liter of gas from the viewpoint of the duration of discharge and the pressure on the material to be sterilized. Further, the particle size of the mist is preferably in the range of, for example, about 5 to 3000 μm from the viewpoint of preventing local discharge.

In the second method for obtaining an ionized body of a mixture of a gas and a liquid in the present invention, the gas passing through the electric field is a gas which can be ionized in the electric field. Such a gas can be appropriately selected from the gases that can be used for the “mixture of gas and liquid”. In the second method, at least a partly ionized gas and a mixture of a gas and a liquid are mixed to obtain a mixture of a gas and a liquid at least partially ionized. The mixing ratio of the gas at least partially ionized and the mixture of the gas and the liquid can be appropriately determined depending on the desired degree of sterilization.

At least a part of the gas or the mixture of the gas and the liquid to be passed through the electric field needs to be ionized. Therefore, the flow rate of a gas or a mixture of a gas and a liquid, the amount of voltage and current (electric power) to be applied to generate an electric field, the number and shape of electrodes, and the like can be at least partially ionized in a gas or a mixture of a gas and a liquid. As appropriate. Further, the gas pressure is usually preferably around the atmospheric pressure because the operation is easy. However, from the viewpoint that the sterilization effect can be enhanced by operating the sterilization container so that the inside of the sterilization container is slightly pressurized from the atmospheric pressure (positive pressure from the atmospheric pressure to a maximum of 1 atm) as described later. preferable.

The at least partially ionized gas or the mixture of gas and liquid obtained by the above method is brought into contact with powder. This contact is performed such that the gas or mixture having been at least partially ionized contacts the entire surface of the powder.
Such contact is preferably performed in a state where the powder is fluidized, from the viewpoint of increasing the contact efficiency and improving the sterilization efficiency. As a method of fluidizing the powder, a known method can be appropriately used, and for example, a gravitational flow, a mechanically forced flow, an oscillating flow, a flow accompanying a fluid, and the like can be used.
The powder fluidized in this way is brought into contact with the gas or the mixture at least partially ionized.For example, the powder falls while fluidizing the powder in the gas or the mixture at least partially ionized. Can be sterilized. In addition, a gas or a mixture that is at least partially ionized can be used as a fluid, and the fluid can be used to fluidize and sterilize the powder.

The contact with the powder is performed outside the electric field in the first and second methods, and is performed in the electric field in the third method. Further, including the fourth method, the contact with the powder can be performed in a sterilization chamber other than the ionization chamber. In addition, it is preferable to operate the inside of the sterilization chamber so as to be slightly pressurized (at most 1 atmospheric pressure) from the atmospheric pressure from the viewpoint that the sterilizing effect can be enhanced. Further, by setting the inside of the chamber to a positive pressure, it is possible to maintain an aseptic state in the chamber.

The sterilization method of the present invention can be carried out, for example, by the apparatus shown in FIG. FIG. 1 is an explanatory view partially showing a cross section. In the figure, 1 is a carrier gas cylinder, and 2 is a nebulizer filled with a liquid such as hydrogen peroxide. Reference numeral 3 denotes a hollow metal electrode (high-pressure electrode) and a supply pipe for a gas-liquid mixture, which has an outlet 4 for the mixture. 5 is a quartz-coated electrode, 6 is a metal electrode constituting a ground electrode, and 7 is a plasma generation chamber.
The ionized gas generated in the plasma generation chamber 7 is transferred to a sterilization chamber 11 including an air slide hopper with a screw for contact with the powder to be sterilized. The powder to be sterilized is supplied from the hopper 8 to the screw conveyor 10, and the ionized gas is supplied to the screw conveyor 10 via the air slide 9.
Contact with the moving powder to be sterilized. The sterilized powder is separated from the waste gas and stored in the sterile silo 12. Separation of the sterilized powder and the waste gas can be performed using a saquilon or a filter, if necessary.

For contact between the ionized gas and the powder to be sterilized, a vibrating slider 14 having a vibrating body 13 as shown in FIG. 2 can be used instead of the air slide hopper with screw. In the vibration type slider 14, the powder to be sterilized is supplied together with the ionized gas from the hopper 8, and is sterilized by contact with the ionized gas on the vibration type slider. The sterilized powder is separated from waste gas and stored in a sterile silo 11 (not shown) as in FIG.

FIG. 3 shows an apparatus using pressurized ionized gas. Reference numeral 20 denotes a compressor pump, which pressurizes the ionized gas prepared by the apparatus shown in FIG. The pressurized ionized gas is stored in the pressurized tank 21. The pressurized tank 21 has a pressure gauge 22 and an electrode 23 for applying a pulse discharge for maintaining the ionized state of the ionized gas being stored. The same pulse voltage as in the preparation of the ionized gas can be applied to the electrode 23. The pressurized ionized gas in the pressurized tank 21 is supplied to the sterilization container 25 from the outlet 26 through the cock 24. In the sterilization container 25, the powder to be sterilized is fluidized and sterilized by blowing up the ionized gas. By appropriately opening and closing the cock 24, it is possible to maintain the internal pressure of the pressurized tank and obtain a blowout of an appropriate pressure.

There is no particular limitation on the microorganisms that can be sterilized by the method of the present invention. According to the method of the present invention, for example, E. coli, Salmonella typhi (Sal.
typhi), B. subtilis, Staphylococcus aurea
us), Aspergillus niger (Asp.
r) and the like can be sterilized.

According to the present invention, various edible or feed powders can be sterilized easily and efficiently. In the present invention, the powder refers to, for example, an aggregate of particles having a particle diameter of 100 μm or less. However, according to the method of the present invention, 50 μm
Even an aggregate of the following particles can be easily and efficiently sterilized. Examples of the powder that can be treated by the method of the present invention include starch (eg, corn starch, potato starch, sweet potato starch, tapioca starch), buckwheat starch,
Udon flour, flour, rice flour, shiratama flour, spice flour (for example,
Spice powder for curry powder) and the like.

[0034]

The present invention will be further described below with reference to examples. Example 1 Corn starch was sterilized using the apparatus shown in FIG.
As a power source, a pulse generator (using a pulse of 19 kV ns peak voltage, a pulse rising speed of 0.1 to 1 kV / ns, and a pulse width of 10 ^-7 seconds) was used. A nebulizer was used for mixing the gas and the liquid, oxygen or argon gas was used as a carrier gas, and 10% or 35% aqueous hydrogen peroxide or 75% ethanol was used as a liquid. The liquid mixed with the carrier gas was supplied into the electric field of the plasma generation chamber 7 by a nebulizer, and the obtained ionized gas was supplied to the sterilization chamber 11 including an air slide hopper with a screw. In addition, as a material to be sterilized, corn starch (particle diameter 6 to 21 μm, average particle diameter 15 to 5 × 10 ⁶ / g) adhered Bacillus subtilis spores.
μm). Table 1 shows the experimental conditions such as the type and flow rate of gas, the type and concentration of liquid, the processing amount (the processing speed of corn starch powder), and the number of residual spores after the processing.

Evaluation Method (Inspection of Number of Residual Spores) 1 g of the powder subjected to the sterilization test was immersed in 10 ml of sterilized 0.2% Tween 80 physiological saline for 1 hour and then stirred to extract residual spores. . The obtained residual spore extract was cultured at 35 ° C. for 48 hours using a standard agar medium. After culturing, the number of remaining spores per gram of powder was calculated from the number of colonies that appeared. Table 1 shows the results. In Table 1, the number of remaining spores of the control is 3.0 × 10 ⁷ (spore number / g).

[0036]

[Table 1]

Example 2 A spice powder was sterilized using an apparatus using a vibration type slider hopper shown in FIG. A pulse generator (using a peak voltage of 18.5 kV ns pulse, pulse rising speed of 0.8 kV / ns, and pulse width of ^10-8 seconds) was used as a power supply. A nebulizer was used for mixing the gas and the liquid, oxygen or argon gas was used as a carrier gas, and 10% or 35% aqueous hydrogen peroxide or 75% ethanol was used as a liquid. The liquid mixed with the carrier gas was supplied to the electric field of the plasma generation chamber by the nebulizer, and the obtained ionized gas was supplied to the sterilization chamber 14 including the vibration type slider hopper. Also,
As a material to be sterilized, spices for curry (particle size: 2 to 60 μm, average particle size: 3 × 10 ⁵ / g)
0 μm). The evaluation method (residual spore count test) was the same as in Example 1. Experimental conditions such as gas type and flow rate, liquid type and concentration, processing amount (spice powder processing speed),
Table 2 shows the frequency (frequency) of the hopper and the number of residual spores after the treatment.

[0038]

[Table 2]

Example 3 Rice flour (shiratama flour) was sterilized using the apparatus shown in FIG.
Pulse generator (18.5kV ns peak voltage pulse used, pulse rise speed 0.8kV / ns, pulse width 10)
^-7 seconds). A nebulizer was used for mixing the gas and the liquid, oxygen or argon gas was used as a carrier gas, and 10% or 35% aqueous hydrogen peroxide or 75% ethanol was used as a liquid. The liquid mixed with the carrier gas is supplied into the electric field of the plasma generation chamber by the nebulizer,
The obtained ionized gas was pressurized using a press machine and stored in a pressurized tank. The pressure during storage was 6 kg / cm ² , and the ionized gas during storage was given an ns pulse discharge with a peak of 30 kV as needed to maintain the ionized state. The ionized gas was supplied from the pressurized tank to a rotating container (rotation speed: 5 times / min to 20 times / min) filled with the material to be sterilized. The supply rate of the pressurized ionized gas was 2 L / min to 5 L / min. Further, as an object to be sterilized product, 2 × 10 ⁵ cells / g rice flour adhering Bacillus subtilis spores (glutinous rice) (particle size 3
-8 μm, average particle size 5 μm). Table 3 shows the experimental conditions such as the type and flow rate of gas, the type and concentration of liquid, the processing amount (the processing speed of rice flour (white powder)), and the number of residual spores after the processing. Table 4 shows the pressure of the pressurized tank, the supply amount of the pressurized ionized gas from the pressurized tank to the rotating container, and the presence or absence of pulse discharge for maintaining the ionized state.

[0040]

[Table 3]

[0041]

[Table 4]

[0042]

According to the present invention, it is possible to provide a method for more efficiently sterilizing powders such as edible or feed powders.

[Brief description of the drawings]

FIG. 1 is a schematic explanatory view of an apparatus used for carrying out a sterilization method of the present invention.

FIG. 2 is a schematic explanatory view of an apparatus used for carrying out the sterilization method of the present invention.

FIG. 3 is a schematic explanatory view of an apparatus used for carrying out the sterilization method of the present invention.

[Explanation of symbols]

 1 ·················································································· Metal electrode (ground electrode). 7 ··· Plasma generating chamber 8 ··· Hopper 9 ···· Air slide 10 ··· Screw conveyor 11 ··· Sterilization chamber 12 ··· Sterile silo 13 ··· Vibrating body 14 ··· Vibration Type slider 20 ・ ・ ・ Compressor pump 21 ・ ・ ・ Pressurized tank 22 ・ ・ ・ Pressure gauge 23 ・ ・ ・ Electrode 24 ・ ・ ・ Cock 25 ・ ・ ・ Sterilization container 26 ・ ・ ・ Outlet

Continuation of front page (72) Inventor Masanori Nagata 1-4-16, Nihonbashi Bakurocho, Chuo-ku, Tokyo Inside Fujimori Industry Co., Ltd.

Claims (3)

[Claims] 1. A method for sterilizing powder, comprising bringing a powder into contact with a gas or a mixture of a gas and a liquid at least partially ionized by an electric field. 2. The method according to claim 1, wherein the electric field is generated by a pulse voltage. 3. The method according to claim 1, wherein the powder is edible powder or feed powder.