ARRANGEMENT METHOD OF NOZZLE HOLES OF CAPTURING NOZZLE OF AIR-BORNE BACTERIA CAPTURING APPARATUS AND AIR-BORNE BACTERIA CAPTURING APPARATUS
In order to present an arrangement method of nozzle holes of a capturing nozzle of an air-borne bacteria capturing apparatus in which dents are hardly formed on the carrier in an operation by rotating a petri dish containing a carrier, and sticking air-borne bacteria contained in the air sucked from nozzle holes formed in a capturing nozzle on the surface of the carrier by inertia, nozzle holes 11 of a capturing nozzle 1 of an air-borne bacteria capturing apparatus characterized by rotating a petri dish 3 containing a carrier 2, and sticking air-borne bacteria contained in the air sucked from the nozzle holes 11 formed in the capturing nozzle 1 on the surface of the carrier 2 by inertia are arranged by uniform random numbers, and the density of the nozzle holes 11 per unit area is uniform.
The present invention relates to an arrangement method of nozzle holes of a capturing nozzle of an air-borne bacteria capturing apparatus used in measurement of environments of a bio-clean room, a manufacturing facility of aseptic foods, aseptic bottled beverage, or the like, by capturing or incubating bacteria, fungi, or other microorganisms floating in air (hereinafter called air-borne bacteria), and an air-borne bacteria capturing apparatus.
BACKGROUND ARTConventionally, to measure environments of a bio-clean room, a manufacturing facility of aseptic foods, aseptic bottled beverage, or the like, air-borne bacteria are captured and incubated, and the number of bacterial cells is counted by ATP measurement, and an air-borne bacteria capturing apparatus has been used for this purpose (see, for example, patent document 1).
However, in the air-borne bacteria capturing apparatus cited in patent document 1, conventionally, since nozzle holes of a capturing nozzle were arranged in a concentric pattern, the air flow rate passing per unit area differs partially because of fluctuations of the number of nozzles holes per unit area, and the culture medium is dried in a place of an abundant air flow rate and the capturing rate of air-borne bacterial tends to be lower, or if air-borne bacteria can be captured, and colonies may not be formed after incubation, or in a place of narrow nozzle hole pitches, captured air-borne bacteria are close to each other, and colonies may be overlaid when incubated, and the actual number of colonies may not be known, and to solve these problems, nozzle holes were arranged in a lattice pattern of specific pitches.
PRIOR ART LITERATURE Patent DocumentPatent document 1: Japanese Patent Application Laid-Open No. 2000-300246
SUMMARY OF THE INVENTION Problems to Be Solved by the InventionMeanwhile, in the method of arranging nozzle holes in a lattice pattern of specific pitches, it is an advantage that the density of nozzle holes per unit area is constant, so that a uniform suction is realized.
To the contrary, in the case of capturing for a long time, if continued to suck nozzle holes arranged in a lattice pattern, a carrier for capturing air-borne bacteria, such as agar culture medium, is promoted in drying of the carrier only beneath the nozzle holes exposed to air stream of high speed, and the volume of the carrier reduced in water content is decreased, and concave dents are generated on the carrier surface.
To decrease drying of the carrier in long-time capturing operation, even when the carrier is rotated, if the nozzle holes are arranged in a lattice pattern, plural nozzle holes are present on a same trace, concentric grooves for drying may be formed on the carrier.
This phenomenon is further described. When nozzle holes of a capturing nozzle of an air-borne bacteria capturing apparatus are arranged by N holes uniformly in a region of radius R, nozzle pitch P is expressed in formula 1.
[Formula 1]
P=2R/(4N/π)1/2 (formula 1)
Herein, formula 1 means that the area ratio of a circle of radius R shown in
4N/p=1.27N
and the square root of 1.27N is the number of nozzle holes of each side, and when arranged at a uniform pitch of 2N on one side, the pitch is P as expressed in formula 1.
In the meantime, an approximate structure of a suction head of the air-borne bacteria capturing apparatus is as shown in
The petri dish 3 is rotated by a motor (not shown) about a rotation shaft 4.
Observing the section of the carrier 2, the nozzle holes 11 draw a trace of a concentric circle about the rotation shaft by nozzle holes of an integer multiple of 4 is provided by 4 pieces or more in a square lattice, and the carrier 2 of the agar culture medium is dried only in the portions immediately beneath the trace, dents of concentric circles are formed.
In
As the dents 21 are formed, and the depth grows along with duration of the capturing time, various defects are caused, for example, the tiny pitch of the surface of the carrier 2 and the nozzle holes 11 is changed, and when the pitch is increased, the air-borne bacteria colliding by inertia may not collide the carrier 2, but may pass through the carrier 2 together with the air, and the capturing efficiency of air-borne bacteria may be lowered.
The present invention is devised in the light of the problem of arrangement method of nozzle holes of a capturing nozzle of a conventional air-borne bacteria capturing apparatus, and it is hence a primary object thereof to present an arrangement method of nozzle holes of a capturing nozzle of an air-borne bacteria capturing apparatus, and an air-borne bacteria capturing apparatus.
Means for Solving the ProblemsTo achieve the object, the arrangement method of nozzle holes of a capturing nozzle of the air-borne bacteria capturing apparatus of the invention is an arrangement method of nozzle holes of a capturing nozzle of an air-borne bacteria capturing apparatus characterized by rotating a petri dish containing a carrier, and sticking air-borne bacteria contained in the air sucked from nozzle holes formed in a capturing nozzle on the surface of the carrier by inertia, in which nozzle holes are arranged by uniform random numbers, and the density of nozzle holes per unit area is uniform.
In this case, by utilizing the average of a plurality of uniform random numbers, the density of nozzle holes per unit area can be disposed in a normal distribution.
The air-borne bacteria capturing apparatus of the invention is an air-borne bacteria capturing apparatus characterized by rotating a petri dish containing a carrier, and sticking air-borne bacteria contained in the air sucked from nozzle holes formed in a capturing nozzle on the surface of the carrier by inertia, in which nozzle holes are arranged by uniform random numbers, and the density of nozzle holes per unit area is uniform.
In this case, by utilizing the average of a plurality of uniform random numbers, the density of nozzle holes per unit area can be disposed in a normal distribution.
Effects of the InventionAccording to the arrangement method of nozzle holes of a capturing nozzle of the air-borne bacteria capturing apparatus and the air-borne bacteria capturing apparatus of the invention, by utilizing the average of a plurality of uniform random numbers, the density of nozzle holes per unit area can be disposed in a normal distribution, and by rotating a petri dish containing a carrier, and sticking air-borne bacteria contained in the air sucked from nozzle holes formed in a capturing nozzle on the surface of the carrier by inertia, dents are hardly formed on the carrier, and it is possible to solve the problem of lowering of capturing efficiency of air-borne bacteria due to generation of dents on the carrier.
Also, by utilizing the average of a plurality of uniform random numbers, the density of nozzle holes per unit area can be disposed in a normal distribution, so that dents are hardly formed on the carrier more securely.
Embodiments of an arrangement method of nozzle holes of a capturing nozzle of an air-borne bacteria capturing apparatus and an air-borne bacteria capturing apparatus of the present invention are described below.
The air-borne bacteria capturing apparatus applying the arrangement method of nozzle holes of a capturing nozzle of the air-borne bacteria capturing apparatus is similar to a conventional air-borne bacteria capturing apparatus as shown in
The petri dish 3 is rotated by a motor (not shown) about a rotation shaft 4.
When capturing air-borne bacteria by using this air-borne bacteria capturing apparatus, while rotating a petri dish 3 containing a carrier 3, air-borne bacteria contained in the air sucked from nozzle holes formed in a capturing nozzle 1 are stuck on the surface of the carrier 2 by inertia.
In this air-borne bacteria capturing apparatus, the nozzle holes 11 of the capturing nozzle 1 are arranged as follows.
As shown in
The radius of the region for arranging the nozzle holes 11 is R.
In the flowchart shown in
Random numbers are generated in real number from −R to R, which are supposed to be X and Y. Judging whether X and Y to be present or not within a region of a circle of radius R, if out of the region, random numbers are generated again. Inside or outside of the circle can be easily judged in formula 2 and formula 3. That is, when formula 2 is satisfied, it is outside of the circle, and when formula 3 is satisfied, it is inside of the circle.
X2+Y2>R2 (formula 2)
X2+Y2≦R2 (formula 3)
This operation is repeated until N pieces of X-coordinate and Y-coordinate are obtained.
The graph in
Herein, the graph in
Generation of random numbers is generally from 0 to 1 in the random number table or random number calculation function of table calculation software. To extend the range from −R to R, 0.5 is decreased from random numbers 0 to 1, and the result is multiplied by 2 times, random numbers from −1 to +1 are generated. When multiplied by R, the range can be extended from −R to +R.
Accordingly, the nozzle holes 11 are arranged by uniform random numbers, and the density of nozzle holes 11 per unit area is uniform, and therefore when the petri dish 3 containing the carrier 2 is rotated, the probability of achieving a same radius is smaller than in a geometrically symmetric lattice arrangement, and it is effective to decrease the troubles of dents concentrating on a specific location.
On the basis of the obtained coordinates, in the graph shown in
For this purpose, a territory T of each nozzle hole 11 for defining the minimum pitch of the adjacent nozzle holes 11 is determined.
The territory T covers a region of average pitch P′ shown in
P′=2R/(4N/π)1/2 (formula 4)
When the value of T for defining the territory is 0, the calculation method is same as in the flowchart in
The priority of determining the average pitch P′ in the first place lies in that one nozzle hole 11 each is disposed securely in the average pitch if T is not 0, and it is effective to eliminate deviation at less than the average pitch concerning the deviation of density of nozzle holes 11.
The value of T is adjusted and determined so that 2 to 5 times of the nozzle holes 11 may be spaced as a pitch of adjacent sections. For example, if the diameter of the nozzle holes is 0.5 mm, the minimum pitch of adjacent holes is defined at a machining limit T of 1.5 mm or more of three times of the diameter.
As characteristics of random numbers, plural random numbers are generated, and averaged, so that the distribution can be converted to a normal distribution. Mathematically, it can be explained by a central limit theorem.
A flowchart in the case of a normal distribution is shown in
In this case, the flowchart is same as in
In the standard deviation of a normal distribution, an arbitrary interval of the normal distribution can be settled in a circle of radius R, by multiplying by a specific coefficient and by adjusting the average number of times when calculating the average of random numbers of X and Y coordinates.
The graph shown in
In the normal distribution, meanwhile, the density of nozzle holes 11 is high in a central area of the petri dish 3 containing the carrier 2, and the density in a peripheral area can be heightened, as shown in the flowchart in
The graph shown in
Herein, the arrangement method of nozzle holes of the capturing nozzle of the air-borne bacteria capturing apparatus of the invention is explained in plural embodiments, but the invention is not limited to these illustrated embodiments alone, but may be changed or modified in various manners within a range not departing from the true spirit thereof, for example, by combining the structures of the examples.
INDUSTRIAL APPLICABILITYThe arrangement method of nozzle holes of the capturing nozzle of the air-borne bacteria capturing apparatus of the invention is characterized by rotating the petri dish containing the carrier, and sticking air-borne bacteria contained in the air sucked from nozzle holes formed in the capturing nozzle on the surface of the carrier by inertia, and therefore dents are hardly formed on the carrier, and the method is preferably applied in the air-borne bacteria capturing apparatus of the same system.
Description of the Reference Numerals1 capturing nozzle
11 nozzle hole
2 carrier
3 petri dish
4 rotation shaft
Claims
1. An arrangement method of nozzle holes of a capturing nozzle of an air-borne bacteria capturing apparatus characterized by rotating a petri dish containing a carrier, and sticking air-borne bacteria contained in the air sucked from nozzle holes formed in a capturing nozzle on the surface of the carrier by inertia, wherein nozzle holes are arranged by uniform random numbers, and the density of nozzle holes per unit area is uniform.
2. The arrangement method of nozzle holes of a capturing nozzle of an air-borne bacteria capturing apparatus according to claim 1, wherein by utilizing the average of a plurality of uniform random numbers, the density of nozzle holes per unit area can be disposed in a normal distribution.
3. An air-borne bacteria capturing apparatus characterized by rotating a petri dish containing a carrier, and sticking air-borne bacteria contained in the air sucked from nozzle holes formed in a capturing nozzle on the surface of the carrier by inertia, wherein nozzle holes are arranged by uniform random numbers, and the density of nozzle holes per unit area is uniform.
4. The air-borne bacteria capturing apparatus according to claim 3, wherein by utilizing the average of a plurality of uniform random numbers, the density of nozzle holes per unit area can be disposed in a normal distribution.
Type: Application
Filed: Jul 21, 2011
Publication Date: Jun 27, 2013
Inventor: Harumasa Yamamoto (Hyogo)
Application Number: 13/816,507