JP5333760B2 - Sample container for centrifuge - Google Patents

Description

  The present invention relates to a centrifuge used in the fields of medicine, pharmacy, genetic engineering, chemical industry, food manufacturing, pharmaceutical manufacturing, etc., and has an angle rotor capable of increasing the amount of liquid sample that can be processed at one time. The present invention relates to a sample container for a centrifuge.

  A centrifuge used for separating a liquid sample includes a rotor for holding a plurality of sample containers containing liquid samples in sample container holding holes arranged uniformly on the circumference, and a motor for driving the rotor to rotate in the rotor chamber. The object is collected by centrifuging the liquid sample in the sample container by rotating the rotor at high speed under atmospheric pressure or reduced pressure in the rotor chamber. The centrifuge mainly targeted in the present invention has a maximum rotational speed of about 5,000 to 30,000 rpm, and a rotor with various specifications can be used depending on the application.

  Examples of liquid samples include various components such as blood components, culture fluids such as bacterial cells and viruses, biological components such as liquids containing DNA and RNA, polymer suspensions, inks, and food processing fluids. These liquid samples are centrifuged for various purposes in processes such as research, experiment, inspection, and production.

  A rotor for a centrifugal separator is known from Patent Document 1, for example. FIG. 21 shows a side view of a conventional angle-type rotor 130, and the left half shows a cross section thereof. In FIG. 21, the rotor 130 is formed with a plurality of holding holes 132 for sample containers (only one is shown in FIG. 21) at an equiangular pitch along the circumference, and each holding hole 132 has a liquid sample. The sample container 150 into which is injected is inserted. A rotor cover 140 is attached to the upper opening of the rotor 130, and the rotor cover 140 is fixed to the rotor body 131 by the handle 141 to seal the interior of the rotor 130. In addition, a drive shaft hole 131A is formed in the lower portion of the central shaft of the rotor body 131, and this drive shaft hole 131A is attached to a drive unit 112 connected to a drive shaft unit (not shown) of the centrifuge. The rotor 130 is rotated at a predetermined speed by the driving means.

  FIG. 22 is a perspective view showing the shape of a sample container 150 that is known from Patent Document 2 and is mounted in the holding hole 132 of the conventional rotor body 131. Usually, in a centrifuge using a sample container with a lid, the body portion 151 of the sample container 150 has a cylindrical shape. A screw-type lid 152 is attached to the upper portion of the body portion 151 to seal the liquid sample. The lid 152 includes an outer lid and an inner lid. Usually, the sample container 150 is a molded product using a plastic material such as polypropylene, polycarbonate, polystyrene, or polyethylene terephthalate, and is often reused many times. The body section 151 and the lid 152 have a circular cross-sectional shape, and can be arbitrarily set without being concerned about the rotational position with respect to the central axis in the longitudinal direction of the sample container 151 when inserted into the holding hole 132 of the rotor 130. It can be installed at the position. Here, the “cross section” refers to a section cut along a plane perpendicular to the vertical direction of the sample container.

  A sample container 150 with a lid used for the angle type rotor 130 has a capacity of about 2 ml / piece to 1,000 ml / piece depending on the application. Further, the number of the holding holes 132 for the sample container formed in the rotor 130 varies from about 4 / rotor to about 20 / rotor. The rotor 130 is generally manufactured using a lightweight, high-strength aluminum alloy, titanium alloy, carbon fiber composite material, or the like. These rotors 130 are, for example, rotors capable of accommodating six sample containers having a capacity of 300 ml (hereinafter referred to as “300 ml × 6”), 500 ml × 6 rotors, or 1,000 ml × 4-6 large ones. Capacitive angle rotors are commercially available, and the capacity of sample containers is increasing with the changing times. In addition, the size of the rotor body has increased with the increase in capacity of the sample container. For example, a rotor having a sample container capacity of 300 to 1,000 ml has a maximum rotor body diameter of approximately 300 mm.

  By the way, the operator attaches and detaches the rotor to and from the centrifuge, but the centrifuge manufacturers including the applicant have tried to reduce the weight of the rotor and improve the operability by contriving the structure of the rotor. . In addition, the sample volume that can be centrifuged at once has been increased by increasing the size of the sample container. In recent years, centrifuges using 1,000 ml × 4 large-capacity angle type rotors have been widely used. Further, the sample container has a lid as disclosed in Patent Document 2, and a through-hole 152A for removal is formed in the lid 152 to facilitate removal of the sample container, and the sample can be removed during centrifugation. A sample container that does not leak is disclosed.

JP 2008-119649 A JP 2004-290746 A

  In general, in order to efficiently collect a target object from a liquid sample in a centrifugal separation process, the centrifugal acceleration applied to the liquid sample is increased by increasing the rotational speed of the rotor, and the centrifugal effect is enhanced to quickly settle the target object. In addition to improving the recovery rate, the amount of sample that can be processed at one time is increased. In addition, the cost required for the centrifuge can be reduced by increasing the amount of sample that can be centrifuged at a time, as well as by constructing a centrifuge including a sample container and a rotor at a low cost. is important.

  In order to centrifuge a large amount of liquid sample at a time, it is effective to increase the number of sample containers used in the rotor and to increase the capacity of each sample container. However, in order to increase the capacity of the conventional cylindrical sample container, it is necessary to increase the outer diameter of the body portion 151 or to increase the height thereof, so that the holding hole of the sample container of the rotor is adjacent. Therefore, it is necessary to shift the arrangement position of the holding hole in the radial direction away from the rotation center (outer peripheral side). As a result, the rotor itself becomes larger in diameter and increases in mass, and the portability of the rotor and the attachment / detachment to / from the centrifuge by the operator are deteriorated.

  In addition, the increase in rotor diameter leads to an increase in air resistance (windage loss) when rotating at high speed in a centrifuge. Therefore, as a countermeasure, the output of a centrifuge drive device is increased, and a cooling device for cooling the rotor. Large output is required. Furthermore, it is necessary to increase the size of the rotor chamber (chamber) of the centrifuge as the diameter of the rotor increases, resulting in a problem that the installation area of the centrifuge increases and the price of the centrifuge increases. .

  In the process of solving these problems, the inventors viewed the rotor provided with the cylindrical sample container from above, and between the holding holes of the adjacent sample containers, the constituent parts of the rotor that cause weight increase ( In the following, focusing on the presence of “extra-wall”, an attempt was made to improve these surplus portions as much as possible. In the course of this improvement, it has been found that the surplus portion in the vicinity of the outer periphery of the rotor contributes to an increase in the mass of the rotor and causes the strength of the rotor to decrease due to the centrifugal load applied to this portion.

  The present invention has been made in view of the above-described background, and its object is to provide a sample container for a centrifuge capable of increasing the amount of a sample that can be centrifuged at one time while suppressing an increase in the diameter and weight of the rotor. Is to provide.

  Another object of the present invention is to provide a sample container for a centrifuge capable of improving the centrifuge characteristics and performing work efficiently in a short time.

  Still another object of the present invention is to provide a sample container for a centrifuge in which a large capacity and easy to use sample container can be mounted.

  The characteristics of representative ones of the inventions disclosed in the present application will be described as follows.

According to one aspect of the present invention, there is provided a sample container including a body portion that can store a sample and a cap portion that can be attached to the body portion, and the body portion has a substantially triangular outer shape when viewed from above. The upper part has a circular opening, and the cap part is configured to be detachably attached to the opening via a sealing member, and the center of the second vertex from the center of the first vertex of the body part And the outer shape of the body part is set so that the distance from the first vertex part to the third vertex part is the same distance, and the tangent line between the two sides sandwiching the first vertex part is formed When the angle is 45 degrees or more and less than 90 degrees, the first vertex portion is formed with the first radius of curvature (R1) when viewed from above, and the side portion between each vertex portion is viewed from above It was configured in an arc shape having a second radius of curvature (R2) gently on the outside. Further, when viewed from above, the outer shape positions of the first to third vertex portions and the side portions between the vertex portions are configured to be located outside the outer shape position of the opening. Furthermore, when viewed from above, the outer shape position of the body portion is configured to be outside the outer shape position of the cap portion, and the body portion has a non-cylindrical shape that is thicker than the lid.

  According to another feature of the present invention, the angle formed by the tangents of the two side portions sandwiching the first to third vertex portions is 60 degrees, and the shape of a substantially equilateral triangle in which the distance between the centers of the vertex portions is equal. To do. The opening has a third radius of curvature (R3), and each radius of curvature is configured to have a relationship of R1 <R3 <R2. The second radius of curvature (R2) is preferably 3 times or more of the third radius of curvature (R3), and the second radius of curvature (R2) is preferably 170 mm or more.

  According to still another feature of the present invention, the sample container is configured to have a shoulder connected to each apex from the opening. Further, the angle formed by the tangents of the two side portions sandwiching the first vertex portion is set to less than 60 degrees, and the distance from the second vertex portion to the third vertex portion is changed from the first vertex portion to the second and second vertex portions. You may comprise shorter than the distance to a 3rd vertex part. The sample container configured as described above has a height of 190 ml or less and a cap portion diameter of 100 mm or less, and the capacity of the sample container is 1500 ml or more.

  According to invention of Claim 1, the distance from the center of the 1st vertex part of the substantially triangular body part to the center of the 2nd vertex part, and the distance from the 1st vertex part to the 3rd vertex part The outer shape of the body part is set so that is equal, and the first vertex part is formed with a first radius of curvature (R1) when viewed from above, and the side part between each vertex part is A sample that can accommodate more samples than a conventional cylindrical sample container because it is configured in an arc shape having a second radius of curvature (R2) gently outward when viewed. A container can be realized. Moreover, since the body portion is configured by combining a plurality of shapes of curvature radii, the strength of the sample container can be improved.

According to the invention of claim 2, when viewed from above, the outer position of the first to third apex portions and the side portions between the apex portions are outside the outer position of the cap portion. Since the body part has a non-cylindrical outer shape, the capacity of the sample container is not only increased, but it is efficiently arranged on the centrifuge rotor. be able to.

  According to the invention of claim 3, the angle formed by the tangents of the two side portions sandwiching the first to third vertex portions is 60 degrees, and the distance between the centers of the respective vertex portions is equal. Since it has a body part, the position which fixes a sample container to the holding hole of a rotor is not limited to one place, but the sample container which is easy to mount | wear is realizable. In addition, since there are three positions to be fixed, it is possible to realize a sample container excellent in durability while suppressing deterioration of a specific portion.

  According to the invention of claim 4, the opening has a third radius of curvature (R3), and each radius of curvature is configured to have a relationship of R1 <R3 <R2. The radius R1 is smaller than the radius of the conventional cylindrical sample container, and a sample container excellent in strength can be realized.

  According to the invention of claim 5, since the second radius of curvature (R2) is three times or more than the third radius of curvature (R3), the capacity of the container is increased as compared with that of a plane, and the curved surface is Strength can be increased.

  According to the invention of claim 6, since the second radius of curvature (R2) is 170 mm or more, the sample container does not roll even when the sample container is placed horizontally, that is, when the side is placed downward. A sample container that can be stably placed horizontally can be realized.

  According to the seventh aspect of the present invention, the sample container is formed so as to have a shoulder portion connected to each apex portion from the opening portion, so that a sample container in which a neck support member can be easily attached to the shoulder portion can be realized. . In addition, a sample container having higher rigidity can be realized by having a shoulder.

  According to the invention of claim 8, the angle formed by the tangent lines of the two side portions sandwiching the first vertex portion is less than 60 degrees, and the distance from the second vertex portion to the third vertex portion is the first This is shorter than the distance from the apex portion to the second and third apex portions, so that it is possible to realize a sample container in which six or more can be arranged in the circumferential direction of the rotor.

  According to the ninth aspect of the invention, the height of the sample container is 190 mm or less, the diameter of the cap portion is within 100 mm, and the capacity of the sample container is 1500 ml or more. A sample container capable of securing the maximum capacity within the region where the rotor can be arranged can be realized.

  The above and other objects and novel features of the present invention will become apparent from the following description and drawings.

It is a front view of the centrifuge 1 which concerns on the Example of this invention, and shows the cross section in part. It is a longitudinal cross-sectional view of the rotor 30 in the Example of this invention. It is a perspective view which shows the external appearance of the sample container 50 which concerns on the Example of this invention. It is a perspective view of the rotor body 31 which concerns on the Example of this invention. It is a top view of the rotor body 31 which concerns on the Example of this invention. It is a top view of the state which mounted | wore the rotor body 31 which concerns on the Example of this invention with the sample container 50 mounted | worn. It is a top view of the sample container 50 which concerns on the Example of this invention, (1) shows the state which attached the cap part 52, (2) shows the state which removed the cap part 52. FIG. It is a longitudinal cross-sectional view of the sample container 50 which concerns on the Example of this invention. It is a figure which shows the shape of the neck support member 70 of FIG. 2, (1) is a perspective view, (2) is a top view. It is a top view which shows the state which mounted | wore the sample body 50 and the neck support member 70 to the rotor body 31 which concerns on the Example of this invention. It is a longitudinal cross-sectional view of the sample container 50 which concerns on the Example of this invention, and shows the state which put the maximum capacity | capacitance of the sample. It is a longitudinal cross-sectional view of the rotor 30 in the Example of this invention. It is sectional drawing of the AA part of FIG. It is a figure for comparing the positional relationship of the shape of the trunk | drum 51 of the sample container 50 by a present Example, and the shape 68 of the trunk | drum 151 of the conventional cylindrical sample container 150. FIG. It is a figure which shows the relationship between the horizontal surface cross-sectional shape of the holding hole 32 in the cross section of the AA part of FIG. 12, and the direction where a centrifugal force is applied. It is a schematic diagram which shows the centrifugal separation state by the sample container of this invention, and the conventional circular sample container. It is a figure which shows the state which set | placed the sample container 50 which concerns on the Example of this invention sideways. It is a top view of the state which mounted | wore with the sample container 50 and the neck support member 70 to the rotor 80 which concerns on the 2nd Example of this invention. It is a figure which shows the sample container 90 which concerns on the 3rd Example of this invention, (1) is a top view, (2) is a perspective view. It is a figure which shows the sample container 95 which concerns on the 4th Example of this invention, (1) is a top view, (2) is a perspective view. The side view of the conventional angle type rotor 130 is shown, and the cross section is shown in the left half. It is a perspective view which shows the shape of the conventional sample container 150. FIG.

  Embodiments of the present invention will be described below with reference to the drawings. In the following drawings, the same portions are denoted by the same reference numerals, and repeated description is omitted. Further, in this specification, it is assumed that the up / down / left / right direction of the centrifuge is the direction shown in FIG. 1, and the up / down direction of the sample container is the direction shown in FIG.

  FIG. 1 is a front view of a centrifuge 1 of the present invention, and shows a part thereof in cross section. The centrifuge 1 includes a rectangular box-shaped housing 2, and the housing 2 is partitioned into two upper and lower spaces by a horizontal partition plate 2A. In the partitioned upper space, a cylindrical chamber 3 having an open top surface is provided. A refrigerant circulation pipe (not shown) is bonded to the outer peripheral portion of the chamber 3, and an internal space of the chamber 3, i.e., the rotor chamber 4 is flowed by flowing a refrigerant supplied from a cooler (not shown) provided in the centrifuge 1. Cool down. A heat insulating material 9 and a protective wall 2B are provided around the chamber 3. An openable / closable door 10 is provided above the chamber 3, and the rotor chamber 4 is sealed by closing the door 10. The rotor 30 is accommodated in the rotor chamber 4. An operation / display unit 13 is provided on the upper and right sides of the housing 2.

  The drive unit 5 is attached to the partition plate 2A at the lower stage partitioned by the partition plate 2A in the housing 2. The drive unit 5 includes a motor housing 6, and an electric motor 7 as a drive source is provided inside the motor housing 6. The motor housing 6 is fixed to the partition plate 2 </ b> A via a damper 8. On the upper side of the motor housing 6, a shaft support portion 6 </ b> A is disposed so as to pass through a hole 3 </ b> B provided in the bottom portion of the chamber 3 and reach the rotor chamber 4. The rotating shaft 7 </ b> A of the motor 7 is rotatably supported by the shaft support portion 6 </ b> A and extends upward into the rotor chamber 4. A drive shaft portion 12 is provided at the upper end portion of the rotation shaft 7A, and a drive shaft hole 31A of the rotor 30 is fixed to the drive shaft portion 12. The rotor 30 is rotated by the motor 7 while the rotor 30 is configured to be detachable from the drive shaft portion 12. Usually, the rotor 30 having a holding hole corresponding to the sample container to be used is selected and mounted. A sample container 50 filled with a sample is mounted in the holding hole 32 of the sample container formed in the rotor 30.

  Next, the rotor and sample container of the present invention will be described with reference to FIGS. FIG. 2 is a longitudinal sectional view of the rotor 30 of FIG. A plurality of sample container holding holes 32 are formed in the rotor 30 at equal angular pitches in the circumferential direction. Each holding hole 32 is fitted with a sample container 50 into which a liquid sample has been injected. A liquid-sealed annular groove 31E is provided on the upper side of the rotor 30 to prevent liquid leakage from the rotor 30 if a sample leaks from the sample container 50 during centrifugation, and an opening 31F is formed above the groove 30E. Is done. A rotor cover 40 is attached to the opening 31 </ b> F, and the rotor 30 is sealed by screwing the rotor cover 40 to the rotor body 31 with a handle 41. A drive shaft hole 31 </ b> A for mounting on the drive shaft portion 12 of the drive portion 5 is formed below the central axis of the rotor body 31. It is important that the drive shaft hole 31A is fixed so as not to be relatively rotatable with respect to the drive shaft portion 12, and can be mounted using a fixing method known in the field of centrifuges. With this mounting method, the rotor 30 is rotationally driven by the motor 7 at a predetermined speed.

The sample container 50 has an opening 51A at the top, and a cap 52 is attached to the opening 51A. The cap part 52 includes an outer lid 53 and an inner lid 54, and the cap part 52 is screwed to seal the opening 51A. What is characteristic in this embodiment is that the distance L1 from the center line 35 in the vertical direction of the sample container 50 to the side wall on the inner peripheral side of the container is from the center line 35 to the side wall on the outer peripheral side of the container. This is much larger than the distance L2. On the other hand, in the opening 51A, the distance C1 from the center line 35 to the inside of the opening and the distance C2 to the outside are equal. These distances L1, L2, C1, and C2 are measured in the vertical direction from the center line 35. The center line 35 is a line passing through the center position of the cap portion 52 or the opening 51A. The center line 35, the center position of the bottom surface of the sample container 50 (or gravity) is a virtual line passing through the center position of the cap portion 52 (described later protrusions 54 A there is located), the center line 35 and the outer The upper surface of the lid 53 has a vertical positional relationship.

  FIG. 3 is a perspective view showing the appearance of the sample container 50, and shows a state where the cap portion 52 is removed. In FIG. 3, the sample container 50 is divided into a body portion 51 and a cap portion 52. The body 51 is a portion of a container for storing a liquid sample to be centrifuged. A circular opening 51A serving as a sample inlet / outlet is provided in the upper part, and a male screw part 51B is provided on the outer peripheral side of the opening 51A. It is formed. As the cross section of the cap 52 is shown in FIG. 2, an O-ring 57 (see FIG. 2) for sealing the opening 51A of the sample container 50 is attached to the inner lid 54 so as to cover them. An outer lid 53 is provided. On the inner surface of the outer lid 53, a female screw portion 52 </ b> B (described later) to be fastened to the male screw portion 51 </ b> B of the opening 51 </ b> A of the body portion 51 is formed. In the upper part of the outer lid 53, a plurality of through-holes 53A for extraction penetrating through the space formed by the convex portions 54A of the inner lid 54 are formed. With such a shape, a space in the cap can be secured between the outer lid 53 and the inner lid 54. This space is formed so that the gap between the outer lid 53 and the outer lid 53 becomes closer to the center of the outer lid 53, and the gap between the outer lid 53 and the inner lid 54 is set to a depth of about 3 to 10 mm so that an adult can hold it with a finger. It is. The through hole 53A can be grasped with the thumb and forefinger or the middle finger, and the sample container 50 attached to the holding hole 32 of the rotor body 31 can be easily pulled out.

  The shape of the through-hole 53A may be any shape and number as long as it is easy to take out, but it is desirable to have a size that allows an adult fingertip, particularly a thumb, to enter, and a diameter of about 20 mm is preferable. The through hole 53A is not necessarily required. In the case of the rotor 30 of this embodiment, the through hole 53A is provided because the sample container 50 can be pulled out from the rotor body 31 by grasping the outer peripheral side of the cap portion 52. It is not necessary. Protrusions 53B for preventing slippage are provided on the outer peripheral portion of the outer lid 53 at equal intervals in the circumferential direction so that an operator can easily hold the cap portion 52 by hand.

  The body 51 of the sample container 50 has a gentle convex shape with the cross-sectional shape of the equilateral triangle as a base, and the sides of the equilateral triangle (sides 56A, 56B, 56C: 56C will be described later). This is a container having a curved surface with a large radius of curvature and three apex portions (vertices 55A, 55B, 55C: 55B to be described later) of equilateral triangles connected by curved surfaces with a small radius of curvature. A horizontal shoulder 51D is formed on the outer side of the body 51 from the male thread 51B. The shoulder 51D has a substantially triangular outline shape when viewed from above.

  The portions from the shoulder portion 51D to the side portions 56A to 56C and the vertex portions 55A to 55C are connected by a gently curved surface having a small radius of curvature when viewed in a longitudinal section. This portion is a connecting portion from the shoulder portion to the side portion and from the shoulder portion to the apex portion, and is to increase the strength by making the shape as small as possible in the radius of curvature. Similarly, the portions from the bottom surface 51E to the side portions 56A to 56C and the apex portions 55A to 5C are connected by a gently curved surface having a small radius of curvature when viewed in a longitudinal section. It will be understood from the perspective view of FIG. 3 that the non-cylindrical sample container 50 in this embodiment is significantly different from the conventional cylindrical sample container 150 (FIG. 22). In the sample container 50, the cap portion 52 may have the same structure as the lid 152 of the conventional sample container 150. Therefore, if it has the same diameter as the lid 152 of the conventional sample container 150, it can be used as the cap part 52 as it is. If the same lid is used, it can be understood that the volume of the sample that can be accommodated is significantly increased because the body 51 is much thicker than the body 151 of FIG.

  The body portion 51 and the cap portion 52 of the sample container 50 are preferably manufactured from thermoplastic plastics such as polypropylene and polycarbonate as materials, and the body portion 51 can be easily manufactured by a blow molding method or an injection blow molding method. . The cap part 52 can be easily manufactured by an injection molding method. By forming with plastic, a sample container having good chemical resistance and easy handling can be realized. The O-ring 57 is suitably made of rubber, and a commercially available product can be used. The color of the body part 51 may be configured to be transparent, or may be configured to be colored so that the inside cannot be seen.

  Next, the shape of the rotor body 31 will be described with reference to FIGS. FIG. 4 is a perspective view of the rotor body 31 according to the embodiment of the present invention, and FIG. 5 is a top view of the rotor body 31. The rotor body 31 is provided with four non-cylindrical holding holes 32 for mounting the sample container 50. The holding hole 32 has a shape substantially the same as the outer shape of the sample container 50. The size of the holding hole 32 is preferably such that the sample container 50 can be attached and detached without difficulty and the gap is as small as possible. For example, the gap between the wall surface of the holding hole 32 and the outer surface of the body portion 51 of the sample container 50 is about 0.1 to 1 mm. If this gap is too large, the degree of deformation of the body 51 due to the hydraulic pressure applied to the sample container 50 or centrifugal force during centrifugation increases, and the durability of the sample container 50 may be reduced. The holding hole 32 includes a bottom portion 31C shown in FIG. 5 and two inner peripheral side wall portions 31B (two of the side portions of the sample container 50 mainly contact each other), and an outer peripheral side wall portion 31D shown in FIG. Two of the parts are mainly abutting). The outer peripheral side wall portion 31 </ b> D is a curved surface having a large curvature radius corresponding to the sample container 50, and is formed so that the curvature radius of the curved surface is substantially parallel to the curvature of the outer periphery of the rotor body 31. This is because, if formed in this way, an unnecessary increase in the thickness around the outer peripheral side wall 31D due to the difference in curvature can be suppressed, and the weight of the rotor 30 can be reduced. As shown in FIG. 3, the holding hole 32 is formed so as to cover almost the entire surface and bottom of the body portion 51 except for a part on the inner peripheral side. By enlarging the covered portion as much as possible, deformation of the sample container 50 itself during the centrifugal separation operation can be prevented.

  The rotor body 31 has a larger holding hole 32 corresponding to the increase in the capacity of the sample container 50, and the periphery of the holding hole 32 is thinned to reduce the volume of the metal part. Therefore, the weight can be reduced. . Furthermore, the rotor body 31 of the present embodiment. An undercut portion (thinned portion) 31G that was thinned so as to go down the central portion was formed. This is because the centrifugal load applied to the sample container 50 in the vicinity thereof is in the outer peripheral direction, and holding on the inner peripheral side is not important (this centrifugal load will be described later in FIG. 12). By forming the bore portion (thinned portion) 31G in this way, the weight of the upper central axis of the rotor body 31 can be reduced, and the rotor 30 can be further reduced in weight. In addition, the center of gravity of the rotor 30 can be lowered by providing the bore portion (thinned portion) 31G. In the center of the rotor body 31, a screw hole 31H for fixing the rotor cover 40 by screwing the handle 41 is formed.

  The rotor body 31 has an integral structure (solid type) manufactured by machining using an aluminum alloy or a titanium alloy material. It is also possible to manufacture with a CFRP composite material. When machining from a metal material, the holding hole 32 can be easily machined by using a milling machine and using an end mill as a blade. Since the outer dimension of the rotor body 31 is limited by the size of the chamber 3 (see FIG. 1), if it is configured in the same size as the conventional one, the conventional centrifugal separator also has the present embodiment. The rotor 30 can be used.

  FIG. 6 is a top view of a state in which the sample container 50 is mounted on the rotor body 31. In FIG. 6, a state in which a neck support member 70 (to be described later) is not attached is shown so that the mounting state of the sample container 50 can be understood. The rotor body 31 according to the present embodiment is a so-called angle rotor that is provided with a predetermined angle so that the bottom surface side 31C of the holding hole 32 is separated from the vertical center line of the rotor 30 (the axis of the rotating shaft). The angle angle is preferably 20 degrees or more and less than 25 degrees. In this embodiment, the angle angle is 23 degrees. Therefore, as shown in FIG. 6, it arrange | positions so that the upper surface of the cap part 52 of the container 50 may become diagonal toward a rotating shaft. When the sample container 50 is mounted in the holding hole 32, the shoulder 51D of each sample container 50 is exposed when viewed from above, and the outer peripheral side of the cap part 52 is not held by the outer peripheral wall of the holding hole 32. You will understand that.

  Next, the dimensions of the sample container 50 of the present invention will be described with reference to FIGS. FIGS. 7A and 7B are top views of the sample container 50, where FIG. 7A shows a state with the cap portion 52 attached, and FIG. 7B shows a state with the cap 52 portion removed. The numbers shown in parentheses in the figure are the dimensions (unit: mm) of the radius of curvature. In FIG. 7, the outer shape of the body portion 51 of the sample container 50 is a shape based on a substantially equilateral triangle when viewed from above, and the outer shape position of the body portion 51 is located outside the outer shape position of the cap portion 52. And three vertex portions 55A, 55B, and 55C and three side portions 56A, 56B, and 56C. The apex portions 55A, 55B, and 55C are not sharp corners, but the corners are connected with a small curvature radius R1. Further, the side portions 56A, 56B, and 56C are not in a straight line when viewed from above but in an arc shape having a large curvature radius R2 that protrudes outward from the sample container 50.

  The sample container 50 according to the present embodiment is formed by three curvature radii R1 and three curvature radii R2 when viewed from above, and the connection positions of the curves of the curvature radii R1 and R2 are black triangle marks in the drawing. Is shown. Thus, the three sides (side portions 56A, 56B, 56C) of the body portion 51 of the sample container 50 are formed with large arc-shaped surfaces, and the three apexes 55A, 55B, 55C are defined as small arc-shaped surfaces. A large increase in capacity could be achieved by using a cylindrical container having a substantially equilateral triangle in the state viewed from above or the cross section. Note that the three sides (side portions 56A, 56B, 56C) of the sample container 50 may be formed in a straight line shape instead of an arc shape. In addition, it is advantageous in terms of strength against the internal pressure received from the internal sample during the centrifugal separation operation.

  In FIG. 7 (2), the crossing angle θ obtained by extending the tangent lines of the side portions 56B and 56C sandwiching one apex portion is 60 degrees. Although the tangent lines of the side portions 56A and 56B and the tangent lines of the side portions 56C and 56A are not shown in the drawing, the outer shape of the body portion 51 is a substantially equilateral triangle. Degree. Further, the distances between the centers of the apexes 55A, 55B, and 55C (the positions indicated by arrows in FIG. 7A and the center positions between black triangle marks) are equal. The opening 51A provided at the upper part of the body part 51 has a radius R5, a male screw part 51B is formed on the outer peripheral side of the opening 51A, and the outer peripheral radius of the male screw part 51B is R3. . Thus, since the trunk | drum 51 formed the opening part 51A sufficiently smaller than an external shape, the shoulder part 51D from the opening part 51A to the side parts 56A-56C and the vertex parts 55A-55C is formed. The shoulder 51D is a surface that becomes horizontal when the sample container 50 is placed vertically. By forming the shoulder portion 51D, the strength of the body portion 51 can be further increased. Moreover, it becomes easy to attach the neck support member 70 mentioned later by providing shoulder part 51D.

  FIG. 8 is a longitudinal sectional view of the sample container 50 according to the present embodiment, in which dimensions (unit: mm) of each part are entered. The vicinity of the junction between the vertical part of the body part 51 and the shoulder part 51D is a gently curved surface with a radius of curvature R6, and the bottom part 51E and the vertical part of the body part 51 below the body part are gently curved with a radius of curvature R7. It is made into a shape. Further, the vicinity of the center portion of the bottom surface portion 51E has a shape slightly raised upward, and the radius of curvature R8 is about 240 mm. With this configuration, when the sample container 50 is placed vertically on the mounting table or the like (placed in the state shown in FIG. 8), the area of contact between the lower side of the bottom surface and the mounting table is reduced, and the sample container 50 is placed. When it stabilizes. In the present embodiment, the meaning that the shape of the floor surface is substantially triangular means not the area of the contact portion with the floor surface but the shape of the upper portion of the floor surface, that is, the inner surface side of the body portion.

  The dimensions of a commercially available cylindrical sample container 150 (see FIG. 22) were an outer diameter (diameter) of the body portion 151 of 98 mm, a body portion length of 133 mm, and a sample volume of 900 ml. Only the R2 dimension is changed so that the sample container 50 of this embodiment circumscribes the outer diameter of the conventional cylindrical sample container 150, and the container height, opening diameter, outer lid and inner lid are the same as the sample container 150. Then, the internal volume becomes 1075 ml, and the capacity that can be accommodated can be increased by 19.5%. By making the volume increase effect, R2 size, and container height as shown in FIG. 8 substantially triangular, the target capacity of 1200 ml, which is 20% capacity increase from the conventional nominal 1000 ml, can be greatly cleared. In this example, a capacity of about 1500 ml can be achieved.

  Next, the neck support member 70 will be described with reference to FIG. 9 is a view showing the shape of the neck support member 70 shown in FIG. 1, wherein (1) is a perspective view and (2) is a top view. As shown in FIG. 1, the neck support member 70 is installed between the cap portion 52 of the sample container 50 and the holding hole 32, and the cap portion 52 of the sample container 50 is deformed in the centrifugal force direction. It works to prevent

  In the centrifuge 1, the rotor 30 rotates at a high speed. In the centrifuge 1 of the present embodiment, the distance between the outer peripheral portion of the cap portion 52 and the outer peripheral side wall portion 31D of the rotor body 31 is large, and there is no portion that holds the outer peripheral side of the cap portion 52. The centrifugal load of the cap part 52 may cause damage to the vicinity of the opening 51A of the container 51 and the shoulder part 51D. In the case of the conventional cylindrical sample container 150 shown in FIG. 21, since the body 151 and the lid 152 have the same outer shape, the outer peripheral side of the lid 152 can be held by the wall surface of the holding hole 132. Such a phenomenon could not occur. Therefore, in the present embodiment, in order to support the outer peripheral portion of the cap portion 52, the neck support member 70 that acts to fill the gap between the cap portion 52 and the holding hole 32 is provided.

  The neck support member 70 is shaped so that the outer shape is fitted to the holding hole 32 of the rotor body 31 and the gap with the holding hole 32 is about 0.1 to 1 mm. Further, a lid insertion hole 70 </ b> A larger than the outer diameter of the cap portion 52 of the sample container 50 by about 0.1 to 1 mm is formed inside the neck support member 70. The thickness of the neck support member 70 is sufficient if it is sufficient to support the cap portion 52, and does not necessarily have to be the same thickness. In the present embodiment, the strength of the cap portion 52 is also taken into consideration, and is set to about 50% of the height (thickness) of the cap portion 52.

  As a method of using the neck support member 70, the sample container 50 is mounted on the rotor body 31, and then placed on the shoulder 51D so as to surround the cap portion 52 from above. The neck support member 70 need only be placed on the sample container 50. By using the neck support member 70, it is possible to prevent the cap portion 52 from being deformed in the centrifugal force direction during the centrifugation. Similar to the material of the container 51, the neck support member 70 can be made of thermoplastic plastic such as polypropylene or polycarbonate, and can be easily manufactured by an injection molding method. However, it is important that the neck support member 70 is made of a material having no elasticity.

  Originally, the neck support member 70 can achieve its original purpose by holding only the substantially half (outside) of the outer peripheral side of the cap portion 52. In this embodiment, however, as shown in FIG. In addition, the sample container 50 has substantially the same shape and has a vertex portion 71A and a side portion 71B. In this way, the neck support member 70 can be attached to the holding hole 32 of the rotor body 31 at three positions in the circumferential direction, so that attachment is facilitated. The shape of the neck support member 70 does not have to be particular to the shape shown in FIG. 9, and various modifications are possible.

  FIG. 10 is a top view showing a state in which the sample container 50 and the neck support member 70 are mounted on the rotor body 31. Since the holding hole 32 of the rotor body 31 is formed with a predetermined angle, the sample container 50 and the neck support member 70 are not perpendicular to the rotor body 31 but are attached obliquely by the angle. As described above, after the neck support member 70 is mounted, the rotor cover 40 is covered and the centrifugal separation operation is started.

  As described above, in this embodiment, the capacity of the sample container 50 is increased by setting the cross-sectional shape of the sample container 50 to be non-circular, so that the weight of the rotor 30 to which the sample container 50 is attached increases. However, when the sample increase and the rotor volume decrease are converted into mass, the rotor body 31 of the present invention can delete the surplus portion around the sample container holding hole while increasing the amount of the sample. Since the sample increase can be accommodated in the part, the rotor can be prevented from increasing in diameter and mass compared with the conventional rotor 131 having the same outer diameter.

  Next, the centrifuge state in the centrifuge 1 of a present Example is demonstrated using FIGS. FIG. 11 shows a state in which the sample 60 is put up to the upper limit position 58 of the sample container 50. In the sample container 50 of the present embodiment, when the sample 60 is put up to the upper limit position 58, the capacity becomes 1500 ml. Even if the sample is completely inserted up to the upper limit position 58, a space 59B is formed between the inner lid 54 and the upper limit position 58, and air exists in this portion. FIG. 12 is a cross-sectional view illustrating the centrifugal separation operation performed in this state. FIG. 12 further shows the size of each part of the rotor 30 accommodating a capacity of 1500 ml, and the unit is mm. The diameter of the rotor body 31 is preferably 350 mm or more and 450 mm or less, and the thickest part is 397 mm in this embodiment. The height of the rotor body 31 is preferably not less than 200 mm and not more than 250 mm. In this embodiment, the height is 225 mm. The diameter of the opening of the rotor body 31 is 276 mm. The angle angle θ of the sample container 50 is 23 degrees. The distance between the innermost peripheral portions between the sample containers 50 is 52.2 mm, and the distance between the innermost peripheral portions between the neck support members 70 is 32.7 mm. The rotor 30 having this size is limited by the size of the accommodated chamber 3 (see FIG. 1). In this embodiment, the inner diameter of the chamber 3 is 430 mm, and the inner maximum height is 276 mm. is there.

  When the rotor 30 rotates, the sample 60 moves to the outer peripheral side by centrifugal force as shown in FIG. The longitudinal sectional view of the rotor 30 shown in FIG. 12 shows the state of the rotor 30 rotating at the target rotational speed, and the liquid level 61 of the sample 60 becomes vertical due to centrifugal force. Further, the air inside the sample container 50 moves, and as a result, a space 62 in which the moved air exists is formed on the inner peripheral side of the liquid surface 61. When a centrifugal load is applied to the sample 60, each part of the sample container 51 is subjected to pressure due to the centrifugal load as indicated by a plurality of arrows on the right side of FIG. At this time, the skirt portion 54B of the inner lid 54 is deformed in the outer peripheral direction by its centrifugal load and this pressure, so that it can be strongly adhered to the inner surface of the opening portion 51A of the body portion 51. Further, the flange portion 54C and the outer lid 53 formed on a part of the inner lid 54 are deformed so as to press the O-ring 57 against the body portion 51 side by a centrifugal load applied to the inner lid 54. The sample 60 does not leak from the cap portion 52 to the outside because it is in close contact with the opening 51A of the sample container.

  A force is applied to the outer peripheral side of the sample container 50 so that the liquid is pushed out of the container. On the other hand, in the space 62, a load is applied in such a direction that the wall portion of the sample container 50 is pushed outward by centrifugal force. Usually, when the centrifugal load applied to the wall portion of the sample container 50 increases, the sample container 50 is destroyed in the worst case. However, in the present embodiment, the portion of the sample container 50 to which this load is applied is in the vicinity of the apex portion on the inner peripheral side, and the apex portion is configured with a small radius of curvature R1, and has high rigidity and no edges. There is no stress concentration, and it is strong against centrifugal loads. In addition, the opening 51A of the sample container 50 is circular, and is further squeezed inward to attach the cap 52, and a shoulder 51D is formed. Therefore, in the sample container 50 of the present embodiment, the rigidity of the portion where the space 62, which is a portion where load is applied, is particularly high, so that the strength of the sample container can be increased while increasing the capacity. As a result, the sample container 50 having excellent durability can be realized.

  13 is a cross-sectional view taken along line AA in FIG. As can be seen in FIG. 13, the liquid level 61 can be in the position shown in the figure, and the space 62 can be on the inner peripheral side. Therefore, the apex portion 55A located in the space 62 in the body portion 51 of the sample container 50 does not have a force that acts on the apex portion 55A from the hydraulic pressure generated by the centrifugal force so as to inflate the apex portion 55A. A force (load) for deforming the apex portion 55A to the inside of the body portion 51 is applied. Therefore, the apex portion 55A located in the space 62 can withstand a centrifugal load only with its own rigidity. Since the radius of curvature of the apex is smaller than the radius of curvature of the conventional cylindrical sample container 150 even in a cross-sectional view, the strength is remarkably high. Furthermore, by forming the apex portion 55 with a radius of curvature R1 (semi-circular shape), edges are eliminated and stress concentration can be prevented.

  FIG. 14 is a diagram for comparing the positional relationship between the shape of the body portion 51 of the sample container 50 according to the present embodiment and the shape 68 of the body portion 151 of the conventional cylindrical sample container 150. The outer contour of the bottom of the holding hole 32 is indicated by a fine dotted line 32. The shape 68 is indicated by a dotted line with a wide interval. The cross-sectional shape of the body portion 51 according to the present embodiment (however, since it is a cross-section of the AA portion of FIG. Is a substantially triangular shape. An elliptical shape 68 indicated by a dotted line is a shape of a conventional cylindrical sample container. A hatched portion between the shape 68 of the conventional body portion 151 and the sample container 50 of the present invention is an increase in the amount of sample. If this portion is a metal, it becomes an extra space 67. Further, the surplus space 67 also represents an area corresponding to the mass decrease of the holding hole 32 of the rotor body 31. By making the sample container 50 and the holding hole 32 into a substantially triangular shape, when the conventional cylindrical sample container 150 is used, the mass of the rotor itself is increased, and the centrifugal force applied to the rotor itself is increased. The extra space 67, which is the portion where the load has been increased, can be deleted. As a result, the processing capacity of the sample can be increased without increasing the diameter of the rotor 31, and on the other hand, the mass of the rotor 30 can be reduced.

  Next, the relationship between the horizontal cross-sectional shape of the holding hole 32 (cross section taken along the line AA in FIG. 12) and the direction in which the centrifugal force is applied will be described with reference to FIG. When an imaginary line 69 passing through the center of the inner peripheral side apex portion 55 </ b> A of the body part 51 accommodated in the holding hole 32 and the center hole of the rotor body 31 is drawn, the inner wall of the body part 51 is perpendicular to the imaginary line 69. When the distance up to, i.e., the horizontal widths a1 to a8 are viewed, the width gradually increases from the innermost point to the outer peripheral side. When the phantom line 69 is viewed as a reference, the width is expanded to at least half or more from the inner peripheral side, in this embodiment, to a position of 68% exceeding 2/3. The sample container 51 that spreads in the lateral direction as it goes in the direction of centrifugation is useful for performing efficient and highly accurate centrifugation. In other words, since the particles hardly move along the container wall, the particles can move smoothly, the centrifugation time can be shortened, and a band with uniform specific gravity can be cleaned in a short time. .

FIG. 16 further explains this state. FIG. 16 is a view showing a state of centrifugal separation by the sample container 50 of the present invention and the conventional circular sample container 150, and the particles are schematically drawn large for understanding of the invention. In addition, the size of the rotor (related to the radius R16 in the figure) and θ ₀ and θ ₁ are shown at the same angle. The cross section shown by the left ellipse shows the body part 151 of the sample container 150, and the right rice ball-shaped substantially triangular crossing shows the body part 51 of the sample container 50 according to this embodiment. In the centrifuge operation, the particles present in the body portions 151 and 51 of the sample container move to the outer peripheral side due to the centrifugal force accompanying the rotation of the rotor. A point 77 indicates the rotation center position on the sample container 150 side, and a point 78 indicates the rotation center position on the sample container 50 side. The point 78 coincides with the position of the screw hole 31H shown in FIGS.

  In the conventional sample container shown on the left side, the particles 72A located on the inner peripheral side move to the outer peripheral side by the rotation of the rotor, pass through the position of the particle 72B, and further move to the position of the particle 72C on the outer peripheral side. On the other hand, the particles 73A in the vicinity of the side surface in the circumferential direction of the sample container 150 similarly move to the position of the particle 73B, hit the wall of the sample container 150, and move along the wall like particles 73C and 73D. Thus, the high density particle | grains (heavy particle | grains) contained in a sample move to the outer peripheral side, and accumulate | store as the pellet 74. FIG.

  In the sample container according to the present embodiment shown on the right side, the particles 75A located on the inner circumferential side move to the outer circumferential side by the rotation of the rotor, pass through the position of the particles 75B, and further to the position of the outer circumferential side particles 75C. Moving. On the other hand, the particles 76A in the vicinity of the circumferential side surface of the sample container 50 similarly move to the positions of the particles 76B and 76C, collide with the wall of the sample container 50, and move along the wall like particles 76D. Thus, the high density particle | grains (heavy particle | grains) contained in a sample are accumulate | stored as the pellet 77 by moving to an outer peripheral side.

  Here, when comparing the two, since the conventional sample container 50 has a circular wall, since the particles gather in the middle along the wall at the positions of the particles 73B to 73D, the particles are difficult to move due to friction with the wall. Centrifugation is required. On the other hand, when the sample container 50 has a substantially triangular shape as in this embodiment, the degree of hitting the wall of the particle 76C is remarkably small. Even if there are particles that move along the wall, the distance to move along the wall is reduced, so the centrifugation time can be shortened, and if the same sample is separated, the centrifugal effect is improved. .

In many cases, after the centrifugal separation operation, the pellet 77 that has settled in the sample container 50 is taken out with the container lying on its side. FIG. 17 shows a state in which the cap portion 52 of the sample container 50 of the present embodiment is removed and the body portion 51 is placed horizontally on the placement surface 65. In the figure, the pellets 77 that have precipitated are not shown, but when they are laid down, they can be placed on the floor with the side where the pellets 77 are accumulated facing down. At this time, since the cross-sectional shape of the body portion 51 is substantially triangular, the sample container 50 does not roll, so that the work can be stably performed on the placement surface 65, and thus workability is good. In particular, when scraping the pellet and transferring it to another container, it is advantageous to lay the body part 51 sideways because it is easier to scrape the pellet. In order to prevent the sample container 50 from rolling, the curvature radius R2 of the side portions 56A, 56B, and 56C is preferably set to 170 mm or more.

  As described above, by using the rotor 30 and the sample container 50 according to this embodiment, a large volume of samples can be processed at one time. In addition, since the sample container 50 according to the present embodiment has a structure that expands toward the outer circumferential direction, the position of the particle near the wall that reaches the wall surface is closer to the outer periphery, and the influence of the friction that the particles receive when moving along the wall surface is affected. Can be reduced. Furthermore, since the outer shape of the body portion 51 of the sample container 50 is made to be a substantially triangular shape instead of a circle, it is easy to rotate the operator when holding the body portion 51 with one hand and turning the cap portion 52 with the other hand. can get. In particular, after the centrifugation operation, the rotor chamber 4 is often cooled and the sample is often cooled, and water droplets may be attached to the sample container 50 taken out. However, even the wet sample container 50 has an advantage that the body portion 51 can be easily grasped by the three apex portions 55A, 55B, and 55C.

  Next, a second embodiment of the present invention will be described with reference to FIG. FIG. 18 shows a configuration in which the holding holes 82 formed in the rotor 80 are narrowed so that six sample containers 50 can be accommodated. With this configuration, the interval between the adjacent holding holes 82 is further reduced, and the useless space is reduced. The mounting angle of the sample container 50 according to the second embodiment is preferably smaller than that in FIG. 12, and is preferably 15 degrees or more and less than 20 degrees. In this embodiment, the setting is set to 17 degrees so that the sample container 50 is mounted slightly upright to prevent interference with the adjacent sample container 50 during mounting and desorption. As a result, when the diameter of the thickest part of the rotor 80 is 431 mm, the innermost peripheral distance between the opposing neck support members 70 is about 104.9 mm as shown in the drawing. As described above, according to the second embodiment, since six sample containers 50 having a capacity of 1500 ml can be mounted on one rotor 80, a sample of 9 liters can be centrifuged in one centrifugation operation. Can do.

  Next, a sample container 90 according to a third embodiment of the present invention will be described with reference to FIG. The sample container 90 has a substantially fan shape when viewed from above, and is arranged such that the lower side in the figure is the rotation center of the rotor. In FIG. 19 (1), the sample container 90 expands the angle of the first apex portion 93A located on the inner peripheral side, and does not constitute the first apex portion 93A with one curvature radius, but has two curvatures. Radius 93AA, 93AC and side part 93AB which connects them were comprised. The reason why the side portion 93AB is formed is that the side portion 93AB is attached close to the rotating shaft side of the rotor. The outline of the side portion 93AB may be linear or a gentle curve.

  The side portions 94A and 94B connected to both sides of the first apex portion 93A are configured in a planar shape in the present embodiment, but may be formed in a gently curved shape. The side portion 94C located at the outer peripheral portion is formed of a curved surface having a gentle R on the outside, and the second vertex portion 93B and the third vertex portion 93C located on both sides of the side portion 94C are the outer shape of the cap portion 92. It is formed of a curved surface having a radius of curvature smaller than the radius of curvature of.

  FIG. 19 (2) is a perspective view of the sample container 90. The sample container 90 according to the present embodiment was configured in an optimum shape for mounting four on the rotor. In the case of using the sample container 90, the mounting direction of the holding hole of the rotor is limited to only one specific direction, but instead of this limited demerit, it is the maximum in the volume of the limited rotor. The merit that a limited sample container capacity can be achieved can be obtained. Further, by using the sample container 90, the degree of flatness of the rotor shape can be increased, and the stability during rotation can be improved.

  Next, a sample container 95 according to a fourth embodiment of the present invention will be described with reference to FIG. The sample container 95 has a substantially isosceles triangle shape when viewed from above, and is arranged so that the lower side in the figure is the rotation center of the rotor. In FIG. 20 (1), the sample container 95 is such that the angle of the first apex portion 98A located on the inner peripheral side is narrowed, and the inner angle formed by the tangent lines of the side portions 99A and 99B connected to both sides thereof is 52 degrees. did. The side portions 99A and 99B are formed in a very gentle curved surface shape, but may be a flat surface shape. The side portion 99C located at the outer peripheral portion is formed of a curved surface having a gentle R on the outer side, and the second vertex portions 98B and 98C located on both sides of the side portion 99C are larger than the radius of curvature of the outer shape of the cap portion 97. It is formed of a curved surface having a small radius of curvature.

  FIG. 20 (2) is a perspective view of the sample container 95, and six sample containers 95 can be mounted on the rotor. In this case, the angle is set to about θ = 23 degrees similarly to the angle angle θ shown in FIG. can do. In the case of using the sample container 95, the direction of mounting in the holding hole of the rotor is limited to one specific direction, but instead of this limited demerit, the maximum volume within the limited rotor volume. Sample container capacity can be achieved. In this embodiment, since the angle of the apex portion 98A located on the inner peripheral side is less than 60 degrees, specifically 52 degrees, it is possible to realize a rotor for a centrifuge that can be arranged in the circumferential direction by six or more.

  As described above, according to the embodiment of the present invention, the outer peripheral portion of the bottom of the sample container is set so as to keep a curved parallel to the outer radius of the rotor, and the positional relationship of the holding hole with respect to the rotor is effectively used. As a result, it is possible to effectively remove the surplus portion of the rotor and to increase the amount of centrifugal separation. In addition, the sample container having a substantially equilateral triangular cross-sectional shape is advantageous in maintaining the strength of the rotor because the distance between adjacent holding holes in the rotor does not decrease much despite the increase in the amount of sample that can be accommodated. is there.

  Furthermore, if it is the structure of this invention, the hole holding a sample container can be formed by the same process as a rotor. In general, in order to realize a non-cylindrical holding hole, the container is configured to hold the container through an adapter or the like made of resin or the like in the cylindrical hole. However, in the rotor body according to this embodiment, no additional adapter is required. Therefore, it is possible to provide a relatively inexpensive rotor for a centrifugal separator with a small number of parts.

  In addition, since the body part of the sample container has a substantially equilateral triangle, there are three orientations for insertion into the rotor, so the apex part exposed to the space 62 during centrifugation and the side part where the pellets gather are specified. Therefore, the problem that only a specific part deteriorates is unlikely to occur even when it is repeatedly used many times.

  Furthermore, since the radius of curvature of the apex portion of the sample container is relatively small, the rigidity of this portion is very high, the amount of sample during centrifugation is small, and there is a large air layer inside the rotor toward the center. Even if the centrifugal separation operation is performed in this state, it is advantageous in strength.

  In realizing the present embodiment described above, the rotor itself is not subjected to major changes except for the strength of the rotor itself against the centrifugal load applied to the rotor as the capacity increases and the strengthening of the motor. The capacity can be increased relatively easily by simply changing the sample container.

  As mentioned above, although demonstrated based on the Example which shows this invention, this invention is not limited to the above-mentioned Example, A various change is possible within the range which does not deviate from the meaning. For example, in the above-described embodiment, the rotor is manufactured by integral molding, but may be manufactured separately. In addition, the member that defines the holding hole for holding the container may be configured by an adapter that is a separate member from the rotor body, and the adapter may be configured to be detachable from the rotor body.

  Furthermore, in the present embodiment, a sample container having a substantially triangular cross-sectional shape has been realized. However, not only a triangular shape but also a sample container based on an odd-angled shape such as a pentagon or a heptagon is realized in the same manner. it can. Moreover, even if it is a quadrangle, if the length of the side on the inner peripheral side is short, the length of the side on the outer peripheral side is long, and the interval between the sides connecting these is widened to the outer peripheral side as shown in FIG. A similar effect can be obtained.

DESCRIPTION OF SYMBOLS 1 Centrifuge 2 Housing | casing 2A Partition plate 2B Protective wall 3 Chamber 3B (chamber) hole 4 Rotor chamber 5 Drive part 6 Housing 6A Shaft support part 7 Motor 7A (motor) rotating shaft 8 Damper 9 Heat insulation part 10 Door 12 Drive shaft section 13 Operation / display section 30 Rotor 31 Rotor body
31A Drive shaft hole 31B Inner peripheral side wall part 31C Bottom part 31D Outer peripheral side wall part 31E Liquid seal annular groove 31F Opening part 31G Round part (thinning part) 31H Screw hole 32 Holding hole 32A (of holding hole) Bottom imaginary line 40 Rotor cover 41 Handle 50 Sample container 51 Body 51A Opening 51B Male thread 51C Restriction 51D (Sample container) Shoulder 52 Cap 52B Female thread 53 Outer lid 53A (For removal) Through hole 53B Anti-slip projection 54 Lid 54A Convex part 54B Skirt part 51C Collar part 55A, 55B, 55C Vertex part 56A, 56B, 56C Side part
57 O-ring 58 Upper limit position 59A, 59B Space 60 Sample 61 Liquid level 62 Space 65 Placement surface 67 Extra space 68 Cylindrical sample container outer diameter imaginary line 70 Neck support member 70A Lid insertion hole 70B Outer peripheral part 70C Flat part 71A Vertex Part 71B Side part 74, 77 Pellet 80 Rotor 81 Rotor body 82 Holding hole 90 Sample container 91 Body part 95 Sample container 96 Body part 112 Drive part 130 Rotor 131 Rotor body 131A Drive shaft hole 132 Holding hole 140 Rotor cover 141 Handle 150 Sample Container 151 Body 152 Cover 152A Through hole

Claims (9)

A centrifuge sample container comprising a body part capable of storing a sample and a cap part attachable to the body part,
The trunk portion has a substantially triangular outer shape when viewed from above, and has a circular opening above.
The cap is configured to be detachable with a screw type via a sealing member in the opening,
The distance between the center of the first vertex and the center of the second vertex of the body and the distance from the first vertex to the third vertex of the body is equal. Set the outline,
The angle formed by the tangents of two sides sandwiching the first vertex is 45 degrees or more and less than 90 degrees,
The first vertex is formed with a first radius of curvature (R1) when viewed from above;
The side portions between the vertex portions are configured in an arc shape having a second radius of curvature (R2) gently when viewed from above ,
When viewed from above, the outer peripheral position of the first to third apex parts and the side part between the apex parts is located outside the outer position of the opening. Sample container. The external position of the side part between the first to third vertex parts and the vertex parts when viewed from above is outside the external position of the cap part. The sample container for a centrifuge as described. The angle formed by the tangents of the two sides sandwiching the first to third vertexes is 60 degrees,
The sample container for a centrifuge according to claim 1 or 2, wherein the distance between the centers of the respective apexes is equal. The opening has a third radius of curvature (R3);
The sample container for a centrifuge according to claim 3, wherein each of the radii of curvature is configured to satisfy a relationship of R1 <R3 <R2.   The sample container for a centrifuge according to claim 4, wherein the second radius of curvature (R2) is at least three times the third radius of curvature (R3).   The sample container for a centrifuge according to claim 5, wherein the second radius of curvature (R2) is 170 mm or more.   The said sample container has a shoulder part connected to each vertex part from the said opening part, The sample container for centrifuges as described in any one of Claims 1-6 characterized by the above-mentioned. The angle formed by the tangents of two sides sandwiching the first vertex is less than 60 degrees,
The distance from the second apex to the third apex is shorter than the distance from the first apex to the second and third apex. The sample container for a centrifuge as described. The height of the sample container is 190 mm or less, the diameter of the cap part is within 100 mm,
The sample container for a centrifuge according to any one of claims 2 to 8, wherein a capacity of the sample container is 1500 ml or more.

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