JP4297757B2 - Adapter for fixing centrifuge - Google Patents

Description

The present invention relates to a centrifugal separator fixing adapter.

  At the time of blood collection, for the purpose of effective use of blood and reduction of burden on blood donors, the blood sample is separated into each blood component by centrifugation, etc., and only the components necessary for the transfuser are collected. Ingredients are collected to return the ingredients to the blood donor.

  In such component blood collection, for example, when obtaining a platelet preparation, blood collected from a donor is introduced into a blood component separation circuit, and plasma, white blood cells are collected by a centrifuge called a centrifuge bowl installed in the blood component separation circuit. The platelets and red blood cells are separated into four components, and the platelets are collected in a bag to obtain a platelet preparation, and the remaining plasma, white blood cells and red blood cells are returned to the blood donor. In order to secure the target platelet count, a series of blood processing steps including the blood collection, the centrifugation of the collected blood, the collection of platelets, and the return of blood are performed a plurality of times.

  The centrifuge bowl (centrifugal separator) has a stator having a blood inlet and a blood component outlet, and an annular blood storage space inside, and is bell-shaped (bell-shaped) supported rotatably with respect to the stator. ), And the blood in the blood storage space is centrifuged by rotating the rotor at a high speed while supplying blood into the blood storage space from the inflow port. It is comprised so that it may isolate | separate into a plasma layer, a buffy coat layer, and a red blood cell layer from the side close | similar to (for example, refer patent document 1).

  By the way, the rotor of the centrifuge bowl is fixed to the turntable of the rotation driving device and rotated at a high speed, and the blood in the blood storage space is centrifuged. As a mechanism for fixing the rotor (bowl 52) to the turntable (housing 60), the outer peripheral portion of the bottom of the rotor is fixed by a plurality of gripping fingers 112 (hereinafter simply referred to as “finger”) provided on the outer peripheral portion of the turntable. The thing of the structure grasped is disclosed (for example, refer patent document 2).

  In this fixing mechanism, the finger 112 is installed so that the center of mass thereof is lower than the rotation center (pivot point: pin 123) of the finger 112. The upper end 126 of the finger 112 (the claw portion that engages with the outer periphery of the bottom of the rotor) is urged in the direction of the rotation center by the force, and the force for pinching the rotor (the holding force of the rotor) is increased. And the holding power of a rotor increases, so that the rotational speed of a turntable increases (refer paragraph number 0007 of patent document 2).

  In this fixing mechanism, when the turntable rotates at a high speed, the holding force of the rotor by the finger is high and the rotor is securely fixed. However, when the turntable stops rotating, the centrifugal force is lost. As a result, the force sandwiching the rotor is reduced, and the rotor is held only by the weak spring force urging the finger 112.

  Therefore, this fixing mechanism has a drawback that the rotor may easily come off the turntable when the turntable is stopped or rotated at a relatively low speed (paragraph of Patent Document 2). No. 0008).

  In addition, the fixing mechanism includes a plurality of fingers 112, a rotation mechanism that rotatably supports each finger 112, and a spring 132 that urges each gripping finger toward the center of rotation. Since it is an assembled structure, it not only has a large number of parts and a complicated structure, but when assembling the device, as described above, the positional relationship between the mass center of the finger 112 and the rotation center can be determined appropriately. The biasing force of the spring 132 must be finely adjusted in relation to the centripetal force acting on the finger 112 when the turntable rotates, so that the assembly is not easy and the performance as a fixing mechanism, There is also a problem that the holding force of the rotor with respect to changes in the rotation speed of the turntable is likely to vary, resulting in a lack of reliability.

JP-A-9-108594 JP-A-9-164343

An object of the present invention, with a simple configuration, the detachment operation of the centrifugal separator can be easily carried out, also, provides a centrifugal separator fixing adapters that can be reliably fixed to the centrifuge There is.

Such an object is achieved by the present invention of the following (1) to ( 10 ).
( 1 ) A centrifuge fixing adapter for fixing a rotating body-shaped centrifuge having a blood storage space inside to a turntable for rotationally driving,
A disc-shaped adapter body that can be fixed to the turntable;
Engaging portions provided on the adapter main body and detachably engaged with a plurality of protrusions formed to protrude outwardly from the outer peripheral portion of the bottom of the centrifuge;
Engagement maintaining means for maintaining the engagement state of the protrusion with respect to the engagement portion,
The engagement maintaining means is urged so as to displace a contact member that is displaceable between a contact position that contacts the protrusion and a retracted position that does not contact the protrusion, and the contact member is moved to the retracted position. And when the adapter body is fixed to the turntable, the contact member is configured to displace to the contact position against the biasing force of the bias member.
The centrifuge fixing adapter, wherein the centrifuge is rotated relative to the adapter main body in a predetermined direction to engage and fix the protrusions and the engaging portions.

( 2 ) The centrifuge fixing adapter according to ( 1 ), wherein the protrusion includes a flange-shaped protrusion.

( 3 ) The engaging portion is formed at a position spaced apart from the upper surface of the adapter main body by a predetermined distance, substantially parallel to the upper surface, and substantially perpendicular to the upper surface. The adapter for fixing a centrifuge according to the above ( 1 ) or ( 2 ), comprising a rotation regulating member that regulates movement in the rotation direction.

(4) the guide plate, the is formed in a band shape along the outer peripheral portion of the adapter body, the rotation regulating member, centrifugation according to (3) which is erected on an end portion of the guide plate Separator fixing adapter.

( 5 ) The centrifuge fixing adapter according to ( 3 ) or ( 4 ), wherein the rotation restricting member is provided on a rear side in the rotation driving direction of the turntable in the engaging portion.

( 6 ) Any one of the above (1) to (5), wherein the abutting member is constituted by a pin, and the pin is configured such that one end thereof protrudes / immerses with respect to the upper surface of the adapter body . The adapter for fixing a centrifuge as described in 1.

( 7 ) When the one end of the pin protrudes from the upper surface of the adapter body, the other end of the pin is recessed from the fixing surface with respect to the turntable, and when the one end of the pin is recessed from the upper surface of the adapter body, the other The centrifuge fixing adapter according to the above ( 6 ), wherein the end portion is configured to protrude from the fixing surface.

( 8 ) The centrifuge fixing adapter according to any one of ( 1 ) to ( 7 ), wherein the centrifuge fixing adapter is fixed to the turntable by setting the inside to a negative pressure.

( 9 ) The centrifuge fixing adapter according to ( 8 ), wherein an air suction port is formed in the adapter body.

( 10 ) The centrifuge includes a stator having a blood inlet and a blood component outlet, and a container body having an annular blood storage space therein and rotatably supported with respect to the stator. The adapter for fixing a centrifuge according to any one of the above ( 1 ) to ( 9 ), comprising a rotor.

According to the present invention, the centrifuge can be easily attached and detached with a simple configuration, and the centrifuge can be reliably fixed with a constant holding force regardless of the rotation speed.
Therefore, the centrifuge is prevented from being detached even when the rotation speed is reduced or the rotation is stopped.

It will be described in detail with reference to preferred embodiments shown in the accompanying drawings per centrifugal separator fixing adapter of the present invention.

Figure 1 is a cross-sectional side view showing an example of the configuration of including a fixing base centrifugal separator (centrifuge bowl) rotation driving device, FIG. 2 is a longitudinal sectional view showing a configuration example of a centrifugal separator (centrifuge bowl), Figure 3 is a perspective view showing a configuration example of a fixing base centrifugal separator. Further, FIG. 4 is a sectional view taken along line A-A in FIG. 3 is a sectional view showing a configuration example of the engaging portion and the engaging maintaining means. In FIG. 3, the centrifuge (centrifugal bowl) 4 shows only the rotor 50 constituting it, and the stator 40 is not shown.

  First, the configuration of the centrifuge (centrifuge bowl) will be described with reference to FIG. In the following description, the upper side in FIGS. 1 to 4 is referred to as “upper”, “upper” or “upper end”, and the lower side is referred to as “lower”, “lower” or “lower end”.

  The centrifuge (centrifugal bowl) 4 includes a stator 40 and a rotor 50 that can rotate with respect to the stator 40. A bowl head 41 is provided on the upper portion of the stator 40, and an inlet 43 and an outlet 44 that protrude in opposite directions are formed in the bowl head 41. Near the center of the bowl head 41 in the longitudinal direction, a skirt-like cover 42 that houses a seal mechanism 48 described later is formed.

  An upper outlet pipe 45 that expands downward is liquid-tightly fitted into the lower end of the bowl head 41. A lower inflow tube 46 is inserted into the lumen of the bowl head 41 and the upper outflow tube 45 to form a double tube structure.

  An upper end 461 of the lower inlet pipe 46 projects upward from the outlet 44 and communicates with the inlet 43. Further, a flange portion 462 having a shape facing the lower surface of the upper outflow pipe 45 is formed in the middle of the lower inflow pipe 46.

  A narrow flow path 463 is formed between the upper outflow pipe 45 and the flange portion 462, and this flow path 463 is a flow formed between the inner surface of the bowl head 41 and the outer surface of the lower inflow pipe 46. It communicates with the outflow port 44 via a path 464.

  A straight tubular inflow pipe 47 extending in the vertical direction is connected to the lower end of the lower inflow pipe 46. The lower end of the inflow pipe 47 is located near the bottom in the rotor 50.

  The sealing mechanism 48 liquid-tightly seals the upper end portion of the rotor 50. The ring 481, the seal member 482 whose inner peripheral edge is fixed to the bowl head 41, and the outer peripheral edge of the seal member 482 are connected to the ring 481. And a presser member 483 that is sandwiched and fixed therebetween.

  The ring 481 has a convex portion 484 that slides in contact with the sliding member 58 fixed to the rotor 50 side when the rotor 50 rotates. The seal member 482 is made of a film made of an elastic material such as various rubbers such as natural rubber, isoprene rubber, silicone rubber, styrene-butadiene rubber, and urethane rubber, and various thermoplastic elastomers.

  On the other hand, the rotor 50 includes a container body (bowl body) 51 having a bell shape (or a bowl shape), a bottom plate (plate-shaped shielding member) 52 that shields the lower end opening of the container body 51, and the container body 51. A bell-shaped (bell-shaped) outer core 53 and a cylindrical inner core 54 fitted inside the outer core 53 are assembled. Both the container main body 51 and the bottom plate 52 have a rotating body shape, and the bottom plate 52 is fixed to the container main body 51 in a liquid-tight manner by fusing or bonding with an adhesive. In particular, fusion is preferred. Examples of this fusion method include thermal fusion, ultrasonic fusion, fusion by laser light irradiation, etc., but more uniform fusion is possible and the fusion strength is high. Fusion by is particularly preferred.

In this case, the type of laser light to be irradiated is not particularly limited, and examples thereof include a semiconductor laser, a CO ₂ laser, a YAG laser, and an excimer laser. Among these, a semiconductor laser is particularly energy efficient and has a long life. Is preferable because it is long. The wavelength of the laser beam to be irradiated generally depends on the type of laser beam, but in the case of a semiconductor laser, the wavelength is preferably about 800 to 1000 nm.

  The inflow pipe 47 is inserted inside the inner core 54, and the rotor 50 rotates about the pipe axis (rotation center axis 500) of the inflow pipe 47.

  A plurality of protrusions 505 are formed on the outer periphery of the bottom of the rotor 50 so as to protrude outward. The projecting portion 505 is configured as a flange-shaped projecting piece. Further, the protrusions 505 may be formed at regular intervals along the circumferential direction or may not be regular intervals, but are preferably formed at regular intervals. In the example shown in FIG. 3, four protrusions 505 are formed at intervals of 90 °. The thickness of each protrusion 505 is substantially equal. Further, the outer peripheral end of each protrusion 505 has an arc shape centering on the rotation center axis 500.

  The protrusion 505 is formed by extending the outer peripheral edge of the bottom plate 52 outward, formed by extending the lower end of the container body 51 outward, and both of them are fused. Alternatively, any material may be used, such as a material obtained by bonding or a material obtained by fusing or bonding another member.

  A recess 506 into which an upper end 242 of a contact member 241 described later can be inserted is formed on the lower surface of the protrusion 505. The concave portion 506 can have a shape corresponding to the shape (rounded shape) of the upper end portion 242 of the contact member 241. For example, as shown in the drawing, the concave portion 506 has an arcuate shape.

  An annular blood storage space (suspension storage space) 55 is formed between the inner peripheral surface of the side wall 511 of the container body 51 and the outer peripheral surface of the outer core 53. Further, a narrow flow path 56 that communicates with the upper part of the blood storage space 55 between the shoulder inner surface of the container main body 51 and the upper outer surface of the outer core 53, from there toward the rotation center axis 500 of the rotor 50. Is formed.

  The bottom plate 52 is a substantially disk-shaped member, and a concave portion 521 for receiving the blood flowing down the inflow tube 47 is formed at the center thereof. A substantially disc-shaped channel 57 is formed between the lower surface of the inner core 54 and the upper surface (inner surface) of the bottom plate 52. The inner peripheral side of the flow path 57 communicates with the recess 521 and the inflow pipe 47, and the outer peripheral side communicates with the lower part of the blood storage space 55.

  Thereby, the lower part of the blood storage space 55 communicates with the inflow port 43 through the flow path 57, the lumen of the inflow pipe 47 and the lumen of the lower inflow pipe 46, and the upper part of the blood storage space 55 is connected to the flow path 56, It communicates with the outflow port 44 via the flow path 463 and the flow path 464.

  A reduced diameter portion 515 is formed on the upper portion of the container body 51, and the upper outlet pipe 45 and the flange portion 462 are accommodated in the reduced diameter portion 515. A ring-shaped sliding member 58 made of, for example, ceramics is fixed to the upper end portion of the reduced diameter portion 515.

  The blood storage space 55 has a shape (tapered shape) whose inner and outer diameters gradually decrease upward in FIG. In particular, the upper part of the blood storage space 55 is curved toward the rotation center axis 500 of the rotor 50 and reaches a narrow flow path 56. This curved portion is referred to as a shoulder portion 59, and the innermost peripheral portion of the flow path 56 is referred to as a dam portion 60. The dam portion 60 flows along the inner surface of the reduced diameter portion 515 when the blood component exceeds this (when moving to the rotation center axis 500 side) during the centrifugation operation, and further flows from the outlet 44 through the flow paths 463 and 464. This is a boundary portion where the blood component can flow back into the blood storage space 55 by, for example, lowering the rotational speed of the rotor 50 if it does not exceed this.

  In the rotor 50, the volume V of the blood storage space 55 is not particularly limited, but is usually preferably about 50 to 1000 [ml], and more preferably about 100 to 300 [ml].

  The container main body 51, the bottom plate 52, the outer core 53, and the inner core 54 are each made of a hard resin material. Examples of the hard resin material include polycarbonate, polyethylene, and polystyrene.

  Further, at least the container body 51 among the container body 51, the bottom plate 52, the outer core 53, and the inner core 54 is preferably made of a substantially transparent material in order to ensure the visibility of the blood storage space 55. . In particular, the container main body 51 and the bottom plate 52 are preferably the same or the same type of material or a material excellent in compatibility in order to increase the fusion strength of the fusion part.

Rotor 50 as described above, for example, by rotating the driving unit (centrifugal separator drive unit) 1 shown in FIG. 1, it is rotated at a preset predetermined centrifugal conditions (rotational speed and rotation time). Under this centrifugal condition, the blood separation pattern (for example, the number of blood components to be separated) in the rotor 50 can be set. For example, in the blood storage space 55, the centrifugal conditions can be set so that the blood is separated from the inner layer into the plasma layer, the buffy coat layer, and the red blood cell layer. The buffy coat layer contains platelets and white blood cells. Although this buffy coat layer is a small amount compared to the plasma layer and the red blood cell layer, platelets and white blood cells can be more clearly separated by passing the plasma and utilizing the difference in sedimentation rate.

As shown in FIG. 1, the rotary drive device 1 includes a housing 11 that houses the centrifugal separator 4, a leg portion 12, a motor 13 as a drive source, holding the centrifugal separator 4 (fixed) to that centrifugal A separator fixing base (hereinafter simply referred to as “fixing base”) 2 is provided. The housing 11 is placed and fixed on the upper portion of the leg portion 12.

  A motor 13 is fixed to the lower surface of the housing 11 with a bolt 16 via a spacer 17. The rotation shaft 14 of the motor 13 protrudes upward, and the fixed base 2 is fitted on the tip of the motor 13 so as to rotate coaxially and integrally with the rotation shaft 14. That is, the fixed base 2 and the rotating shaft 14 are preferably detachably connected by a coupler having an uneven fitting structure capable of transmitting a rotational force. The rotor 50 of the centrifuge 4 is coaxially fixed to the upper part of the fixing base 2 by an operation described later.

  The stator 40 of the centrifugal separator 4 is fixed to the housing 11 by a fixing member (not shown) at the upper position (bowl head 41). In the rotation drive device 1, when the motor 13 is driven, the fixed base 2 and the rotor 50 fixed thereto rotate under a predetermined centrifugal condition (for example, a rotational speed of 1000 to 6000 rpm). Under this centrifugal condition, the blood separation pattern (for example, the number of blood components to be separated) in the rotor 50 can be set.

  The fixed base 2 is provided on the turntable 20 that is rotationally driven by a motor 13 in a predetermined direction (the arrow direction in FIG. 3), and is freely detachable with respect to each protrusion 505 of the centrifuge 4. And a plurality of engaging portions 22 that engage with each other, and an engagement maintaining means 24 that maintains the engagement state of the protrusion 505 with respect to each engaging portion 22.

  The turntable 20 is composed of a disk-like member that forms the main body of the fixed base 2, and a plurality of engaging portions 22 are formed on the outer peripheral portion of the upper surface 201 so as to correspond to the protrusions 505. Yes. In the illustrated embodiment, the four engaging portions 22 are formed at equal intervals along the circumferential direction, that is, at 90 ° intervals.

  In addition, a recess 205 is formed substantially at the center of the turntable 20. A convex portion for defining a concave portion 521 formed in the central portion of the bottom plate 52 of the centrifuge 4 is inserted and disposed in the concave portion 205.

  Hereinafter, although each engagement part 22 and each engagement maintenance means 24 are demonstrated, since each structure is the same, one engagement part 22 and each engagement maintenance means 24 are demonstrated.

  The engaging portion 22 is formed at a position spaced apart from the upper surface 201 of the turntable 20 by a predetermined distance and is substantially perpendicular to the upper surface 201, and a guide plate 221 disposed substantially parallel to the upper surface 201. A rotation restricting member 222 that restricts movement in the direction.

  Between the upper surface 201 of the turntable 20 and the guide plate 221, a space 21 in which a protrusion (projection piece) 505 is inserted and stored is formed. Therefore, the separation distance from the upper surface 201 of the guide plate 221 is a distance necessary and sufficient for the protrusion 505 to be inserted.

  The guide plate 221 is formed in a band shape along the outer peripheral portion of the turntable 20, and the rotation restricting member 222 is configured by a small piece standing upright at one end of the guide plate 221 so as to close the space 21. . The outer edge of the guide plate 221 and the outer edge of the turntable 20 are connected (or integrated) by an arc-shaped outer peripheral wall 223, and the outer peripheral side of the space 21 is closed. With such a configuration, the space 21 is a space that is open only to the rotation center side of the turntable 20 and the other end side of the guide plate 221 (the side without the rotation restricting member 222).

  Here, the rotation restricting member 222 may be formed at either end of the guide plate 221, but the rotation drive is related to the rotation drive direction of the turntable 20 (see the arrow in FIG. 3). It is preferably provided on the rear side in the direction. Thus, when the turntable 20 is rotationally driven (rotational acceleration), the protrusion 505 comes into contact with and is urged by the inertial force of the centrifuge 4, so that the turntable 20 can be urged. Secure fixing is maintained without causing the centrifuge 4 to slip.

  Each engagement portion 22 is provided with an engagement maintaining means 24 that maintains the engagement state of the protrusion 505 that engages with the engagement portion 22. As shown in FIG. 4, the engagement maintaining unit 24 includes a contact member 241 that contacts the lower surface of the protrusion 505 and a biasing member 245 that biases the contact member 241 to contact the protrusion 505. And the engagement state is maintained by the urging force of the urging member 245.

  A hole 247 is formed in the lower portion of the space 21 of the engaging portion 22 of the turntable 20, and the contact member 241 and the urging member 245 are accommodated in the hole 247.

  The contact member 241 is configured by a pin, and the upper end portion 242 has a rounded shape. A hook-shaped spring seat 243 is formed in the middle of the contact member 241. The urging member 245 is configured by a coiled spring accommodated in the hole 247 in a compressed state. The lower end and the upper end of the urging member (spring) 245 are the bottom surface of the hole 247 and the contact member 241, respectively. Is in contact with the spring seat 243. Thereby, the urging member 245 urges the contact member 241 upward toward the space 21.

  The upper portion of the hole 247 is formed with a reduced diameter portion 248 that has a diameter reduced to such an extent that the spring seat 243 cannot pass through, and the spring seat 243 comes into contact with the lower surface of the reduced diameter portion 248, whereby the contact member 241. The upper end 242 is prevented from excessively protruding into the space 21.

Next, a fixing method (mounting method) of the centrifuge 4 to the fixing base 2 will be described.
As shown in FIG. 3, the rotor 50 of the centrifuge 4 is positioned above the turntable 20, and the protrusions 505 are lowered while the centrifuge 4 is lowered while the rotation centers thereof are substantially aligned with each other. Alignment is performed so that they are inserted between the adjacent engaging portions 22 (four gaps).

  Next, with the turntable 20 fixed (rotation stopped), the rotor 50 is rotated clockwise in FIG. As a result, each protrusion 505 is inserted into the space 21 of the corresponding engaging portion 22 (in the direction of the arrow in FIG. 4), and stops when the protrusion 505 contacts the rotation restricting member 222.

  This operation may be performed by rotating the turntable 20 counterclockwise in FIG. 3 with the rotor 50 fixed (rotation stopped).

  When the protrusion 505 is inserted into the space 21 of the engaging part 22 by about half, the edge of the protrusion 505 contacts the upper end 242 of the contact member 241 and contacts the urging force of the urging member 245. The member 241 is pressed downward. As a result, the upper end 242 is retracted into the hole 247. Thereafter, the upper end 242 slides while contacting the lower surface of the protrusion 505. When the protrusion 505 comes into contact with the rotation restricting member 222, the recess 506 formed on the lower surface of the protrusion 505 coincides with the substantially central position of the hole 247. 241 moves upward, and the upper end 242 is inserted into the recess 506. Since the upper end portion 242 of the contact member 241 is pressed against the curved concave surface of the concave portion 506 by the biasing force of the biasing member 245, the protrusion 505 can move in the direction of returning (the direction away from the rotation restricting member 222). Is prevented.

  Thus, the engagement of each protrusion 505 with the engaging portion 22 is completed, and the engaged state is maintained. Thereby, the fixed (mounted) state of the rotor 50 with respect to the turntable 20 is reliably maintained. The force with which the fixing base 2 fixes the rotor 50 is substantially constant regardless of the rotation speed of the turntable 20 (even when the rotation is stopped).

  When the rotor 50 is removed from the turntable 20 after the centrifugal separation operation is completed, the rotor 50 is rotated relative to the turntable 20 counterclockwise in FIG. As a result, the upper end 242 of the contact member 241 is disengaged from the recess 506 formed on the lower surface of the protrusion 505, and the protrusion 505 comes out of the space 21 and is disengaged from the engagement portion 22. 50 can be easily removed from the turntable 20.

  FIG. 5 is a cross-sectional view showing another configuration example of the engaging portion and the engagement maintaining means. The engagement maintaining means shown in FIG. 5 is a simplified version of the configuration of the engagement maintaining means 24 shown in FIG.

  A recess 506 similar to the above is formed in the protrusion 505 formed on the outer peripheral portion of the rotor 50.

  On the other hand, the engagement maintaining means 25 includes an urging member 255 configured by a leaf spring, and a projecting contact member 251 formed at one end thereof and protruding upward. In the present embodiment, the contact member 251 and the biasing member 255 are integrally formed of the same material (for example, hard resin, metal material).

  The other end of the urging member 255 is fixed to the turntable 20, whereby the urging member 255 and the contact member 251 are cantilevered with respect to the turntable 20. The contact member 251 can be displaced in the vertical direction by the bending of the biasing member 255. The contact member 251 is configured by a rounded protrusion, and when the protrusion 505 is inserted into the space 21, the contact member 251 is inserted into the recess 506 formed on the lower surface thereof.

  Also in the case of the fixing base 2 having the engaging portion and the engagement maintaining means shown in FIG. 5, the fixing method (mounting method) of the centrifuge 4 to the fixing base 2 is substantially the same as described above. Description is omitted.

  FIG. 6 is a perspective view showing an embodiment of the centrifuge fixing adapter of the present invention. A centrifuge fixing adapter (hereinafter simply referred to as “adapter”) 3 is an adapter for fixing the centrifuge 4 to the turntable 28 of the rotary drive device 1, and is a disc-like shape that can be fixed to the turntable 28. Adapter body 30, a plurality of engaging portions 32 provided on the adapter main body 30 and detachably engaged with the protrusions 505 of the centrifuge 4, and protrusions 505 with respect to the engaging portions 32. It is comprised with the engagement maintenance means 34 which maintains this engagement state.

  The turntable 28 is configured by a substantially disk-shaped member, and an air suction port 281 is formed at the center thereof. An air suction device (not shown) is installed below the turntable 28, and an intake pipe of the air suction device is connected to a lower end portion of the air suction port 281.

  A ring-shaped outer peripheral wall 282 is formed on the outer periphery of the turntable 28 so as to stand substantially vertically.

  Further, a ring-shaped packing (adhesion sheet) 283 is installed over the entire circumference on the top surface of the bottom of the turntable 28 and inside the outer peripheral wall 282. The packing 283 can be made of, for example, various rubber materials, various thermoplastic elastomers, various soft resins, and the like as described above. In the present invention, such packing may be installed on the lower end surface 303 side of the leg portion 302, or the packing itself may not exist.

  The adapter body 30 has a cylindrical (ring-shaped) leg portion (spacer) 302 formed on the outer periphery of the lower portion thereof over the entire periphery. When the adapter 3 is fixed (attached) to the turntable 28, the lower end portion of the leg portion 302 is fitted inside the outer peripheral wall 282 of the turntable 28, and the lower end surface (fixed surface) 303 of the leg portion 302 is Adheres closely to the packing 283.

  In addition, a recess 305 is formed substantially at the center of the adapter body 30. A convex portion for defining a concave portion 521 formed in the central portion of the bottom plate 52 of the centrifuge 4 is inserted and disposed in the concave portion 305.

  Hereinafter, although each engagement part 32 and each engagement maintenance means 34 are demonstrated, since each structure is the same, one engagement part 32 and each engagement maintenance means 34 are demonstrated.

  The engaging portion 32 is formed at a position spaced apart from the upper surface 301 of the adapter main body 30 by a predetermined distance, and is formed substantially perpendicular to the upper surface 301 and is rotated by the projection 505 contacting the guide plate 321. A rotation restricting member 322 that restricts movement in the direction.

  Between the upper surface 301 of the adapter main body 30 and the guide plate 321, a space 31 in which a protrusion (projection piece) 505 is inserted and stored is formed. Therefore, the separation distance from the upper surface 301 of the guide plate 321 is a distance necessary and sufficient for the protrusion 505 to be inserted.

  The guide plate 321 is formed in a band shape along the outer peripheral portion of the adapter main body 30, and the rotation restricting member 322 is configured by a small piece that is erected so as to close the space 31 at one end portion of the guide plate 321. . The outer edge of the guide plate 321 and the outer edge of the adapter body 30 are connected (or integrated) by an arc-shaped outer peripheral wall 323, and the outer peripheral side of the space 31 is closed. With such a configuration, the space 31 becomes a space that opens only to the rotation center side of the adapter main body 30 and the other end portion side of the guide plate 321 (the side without the rotation restricting member 322).

  Here, the rotation restricting member 322 may be formed at either end of the guide plate 321, but the rotation drive is related to the rotation drive direction of the adapter body 30 (see the arrow in FIG. 6). It is preferably provided on the rear side in the direction. Thereby, when the adapter main body 30 is driven to rotate (at the time of rotation acceleration), the protrusion 505 comes into contact with and is urged by the inertial force of the centrifuge 4, so that the adapter main body 30 can be biased. Secure fixing is maintained without causing the centrifuge 4 to slip.

  Each engagement portion 32 is provided with an engagement maintaining means 34 for maintaining the engagement state of the protrusion 505 that engages with the engagement portion 32. The engagement maintaining means 34 can be the same as the above-described engagement maintaining means 24 (shown in FIG. 4), and the configuration and operation thereof are substantially the same, so that the description thereof is omitted. Also in the adapter 3, instead of the engagement maintaining means 34, the same engagement maintaining means 35 as the above-described engagement maintaining means 25 (shown in FIG. 5) can be used, and the same action and effect are produced. .

Such an adapter 3 is used as follows.
As shown in FIG. 6, the rotor 50 of the centrifuge 4 is positioned above the adapter main body 30 and the protrusions 505 are lowered while the centrifuge 4 is lowered with their rotation centers substantially aligned with each other. Alignment is performed so that they are inserted between the adjacent engaging portions 32 (four gaps).

  Next, the rotor 50 is rotated relative to the adapter body 30 in the clockwise direction in FIG. As a result, each protrusion 505 is inserted into the space 31 of the corresponding engaging portion 32 and stops when the protrusion 505 contacts the rotation restricting member 322. At this time, the action of the engagement maintaining means 34 described above prevents the protrusion 505 from moving in the returning direction (the direction away from the rotation restricting member 322).

  Thus, the engagement of each protrusion 505 with the engaging portion 32 is completed, and the engaged state is maintained. As a result, the rotor 50 is fixed (attached) to the adapter 3.

  Next, the adapter 3 to which the rotor 50 is fixed is attached to the turntable 28. First, the lower end portion of the leg portion 302 of the adapter 3 is fitted inside the outer peripheral wall 282 of the turntable 28. At this time, the lower end surface 303 of the leg portion 302 is in contact with the packing 283.

  Next, the air suction device described above is operated, and intake is performed through the intake pipe and the air suction port 281 of the device. As a result, the internal space of the adapter 3 (the space surrounded by the adapter 3 and the turntable 28) becomes negative pressure, and the adapter 3 is attracted and fixed to the turntable 28.

  At this time, the lower end surface 303 of the leg portion 302 is pressure-bonded to the packing 283 by the adsorption force acting on the adapter 3. Since the packing 283 is made of a material such as rubber or soft resin that has adhesiveness (air tightness) and is difficult to slide, the adapter 3 slides against the turntable 28 even when the turntable 28 rotates at high speed. There will be no misalignment. Therefore, the rotor 50 fixed to the adapter 3 is also securely fixed to the turntable 28.

  The force with which the adapter 3 fixes the rotor 50 is substantially constant regardless of the rotational speed of the turntable 28. Therefore, the rotor 50 is securely fixed to the turntable 28 regardless of the rotational speed.

7 and 8 are cross-sectional views illustrating the usage scenario of the engagement maintaining means of the present invention. As shown in these drawings, the engagement maintaining means 36 has a contact position (position shown in FIG. 8) that contacts the protrusion 505 of the rotor 50 and a retracted position (position shown in FIG. 7) that does not contact the protrusion 505. ) And a biasing member 366 that biases the contact member 361 so as to be displaced to the retracted position. Note that the concave portion 506 as described above may not be formed on the lower surface of the protrusion 505.

  A hole 367 is formed in the lower portion of the adapter main body 30 near the entrance of the space 31 (in the leg portion 302), and the contact member 361 and the biasing member 366 are accommodated in the hole 367.

  The contact member 361 is constituted by a pin, and the upper end 362 and the lower end 363 thereof are rounded. The length of the contact member 361 is longer than the height of the leg portion 302, whereby at least one of the upper end portion 362 and the lower end portion 363 of the contact member 361 protrudes from the upper surface 301 or the lower end surface 303 of the adapter main body 30.

  A hook-shaped spring seat 364 is formed in the middle of the contact member 361, and an O-ring 365 is installed on the outer periphery of the spring seat 364. The O-ring 365 moves as the contact member 361 moves in the vertical direction in the figure, and comes into sliding contact with the inner peripheral surface of the hole 367.

  The biasing member 366 is configured by a coiled spring housed in a compressed state in the upper portion of the hole 367, and the lower end and the upper end of the biasing member (spring) 366 are respectively spring seats of the contact member 361. 364 and the reduced diameter portion 368. Accordingly, the biasing member 366 biases the contact member 361 downward so that the upper end portion 362 is retracted from the space 31 (so as to be sunk below the upper surface 301).

  Near the upper end of the hole 367, there is formed a reduced diameter portion 368 having a diameter reduced to such an extent that the upper end portion 362 of the contact member 361 passes but not the biasing member 366. The upper end of the urging member 366 contacts. Further, a ring-shaped bush 369 for preventing the contact member 361 from coming off is fitted (or screwed) into the lower portion of the hole 367. The bush 369 is formed with a hole through which the lower end portion 363 of the contact member 361 passes. The spring seat 364 of the contact member 361 contacts the upper surface of the bush 369, and the contact member 361 cannot move further downward. It regulates so that.

  When the adapter 3 is in a normal state (single state where the turntable 28 is not fixed), the contact member 361 is urged downward by the urging member 366 as shown in FIG. Is still in contact with the bush 369. As a result, the upper end portion 362 of the contact member 361 is inserted into the hole 367 from the upper surface 301 of the adapter body 30, and the lower end portion 363 of the contact member 361 protrudes downward from the lower end surface (fixed surface) 303 of the leg portion 302. ing.

  On the other hand, when the adapter 3 is fixed to the turntable 28, the lower end surface (fixed surface) 303 of the leg portion 302 is pressure-bonded to the packing 283 on the turntable 28 side. As a result, as shown in FIG. 8, the lower end portion 363 of the contact member 361 contacts the packing 283 and is pushed upward, and the contact member 361 moves upward against the urging force of the urging member 366. To do. By this movement, the upper end portion 362 of the contact member 361 protrudes from the upper surface 301 of the adapter main body 30 by a predetermined length, and the lower end portion 363 of the contact member 361 enters the hole 367 from the lower end surface (fixed surface) 303 of the leg portion 302. Immerse yourself.

The adapter 3 provided with such engagement maintaining means 36 is used as follows.
As shown in FIG. 6, the rotor 50 of the centrifuge 4 is positioned above the adapter main body 30 and the protrusions 505 are lowered while the centrifuge 4 is lowered with their rotation centers substantially aligned with each other. Alignment is performed so that they are inserted between the adjacent engaging portions 32 (four gaps).

  Next, the rotor 50 is rotated relative to the adapter body 30 in the clockwise direction in FIG. As described above, the contact member 361 is in the retracted position where it does not contact the protrusion 505, that is, the upper end 362 of the contact member 361 is immersed in the hole 367 from the upper surface 301 of the adapter main body 30. For this reason (see FIG. 7), each protrusion 505 is inserted into the space 31 of the corresponding engaging portion 32 without being blocked by the contact member 361, and the protrusion 505 contacts the rotation restricting member 322. Stop where you left off.

  Next, the adapter 3 is mounted on the turntable 28 while maintaining this state. First, the lower end portion of the leg portion 302 of the adapter 3 is fitted inside the outer peripheral wall 282 of the turntable 28. At this time, the lower end surface 303 of the leg portion 302 abuts on the packing 283 and is pushed upward. Accordingly, as described above, the contact member 361 moves to the contact position where the contact member 361 contacts the protrusion 505. That is, the upper end portion 362 of the abutting member 361 protrudes from the upper surface 301 of the adapter main body 30, and abuts and engages with the edge portion of the protrusion 505. Therefore, the protrusion 505 is prevented from returning in the direction opposite to the arrow in FIG. 8 (moving in the direction away from the rotation restricting member 322), and the engaged state with respect to the engaging portion 32 is maintained.

  As described above, the engagement of each protrusion 505 with the engaging portion 32 is completed and the engaged state is maintained, whereby the rotor 50 is fixed (attached) to the adapter 3.

  Next, the air suction device described above is operated, and intake is performed through the intake pipe and the air suction port 281 of the device. As a result, the internal space of the adapter 3 (the space surrounded by the adapter 3 and the turntable 28) becomes negative pressure, and the adapter 3 is attracted and fixed to the turntable 28.

  At this time, the lower end surface 303 of the leg portion 302 is pressure-bonded to the packing 283 by the adsorption force acting on the adapter 3. Since the packing 283 is made of a material such as rubber or soft resin that has adhesiveness (air tightness) and is difficult to slide, the adapter 3 slides against the turntable 28 even when the turntable 28 rotates at high speed. There will be no misalignment. Therefore, the rotor 50 fixed to the adapter 3 is also securely fixed to the turntable 28.

  The force with which the adapter 3 fixes the rotor 50 is substantially constant regardless of the rotational speed of the turntable 28. Therefore, the rotor 50 is securely fixed to the turntable 28 regardless of the rotational speed.

  In addition, as long as the adapter 3 is securely crimped and fixed to the turntable 28, the abutting member 361 maintains the abutting position where it abuts against the protrusion 505. Engagement is also reliably maintained.

  When the adapter 3 is removed from the turntable 28 after the centrifugal separation operation is finished, the pressing of the lower end 363 of the contact member 361 by the packing 283 is released, and therefore the contact member 361 is caused by the biasing force of the biasing member 366. Then, it moves downward relative to the adapter body 30 and automatically returns to the retracted position. Accordingly, the rotor 50 can be easily detached from the adapter 3 by rotating the rotor 50 relative to the adapter body 30 counterclockwise in FIG.

  As mentioned above, although this invention was demonstrated based on each embodiment of illustration, it cannot be overemphasized that this invention is not limited to the thing of illustration. The structure of each part of the fixed base, the adapter, and the rotation driving device described above can be replaced with an arbitrary structure that can exhibit the same function, and an arbitrary structure can be added. In particular, the shape, number, and arrangement of the protrusions formed on the centrifuge, the structure and arrangement of the engaging portion that engages with the protrusion, and the structure and arrangement of the engagement maintaining means are shown in the figure. The present invention is not limited to this, and may be anything.

  The fixing of the adapter 3 to the turntable 28 is not limited to the configuration using the negative pressure as described above, and for example, a known clamping mechanism (gripping mechanism) or the like may be used. .

  In the above description, the centrifugal bowl having a rotor and a stator is described as an example of the centrifugal separator. However, the type and structure of the centrifugal separator are not limited thereto.

It is a sectional side view showing a configuration example of a rotary drive device provided with a fixing base of centrifugal separators. It is a longitudinal cross-sectional view which shows the structural example of a centrifuge (centrifugal bowl). Is a perspective view showing the fixing base embodiment of centrifugal separator. Diagrams 3 A-A line cross-sectional view of (cross-sectional view showing a configuration example of the engaging portion and the engaging maintaining means). Engaging portion and a cross-sectional view showing another configuration example of the engagement maintaining means. It is a perspective view which shows embodiment of the adapter for centrifuge fixing of this invention. Usage scenario of the engagement maintaining means in the present invention is a cross-sectional view showing a (contact member state in the retracted position). Usage scenario of the engagement maintaining means in the present invention is a cross-sectional view showing a (contact member state in the contact position).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Rotation drive apparatus 11 Housing 12 Leg part 13 Motor 14 Rotation shaft 16 Bolt 17 Spacer 2 Fixing base 20 Turntable 201 Upper surface 205 Recess 21 Space 22 Engagement part 221 Guide plate 222 Rotation restriction member 223 Outer peripheral wall 24 Engagement maintaining means 241 Contact member (pin)
242 Upper end 243 Spring seat 245 Biasing member (spring)
247 hole 248 reduced diameter portion 25 engagement maintaining means 251 contact member (protrusion)
255 Biasing member (leaf spring)
28 Turntable 281 Air inlet 282 Outer wall 283 Packing 3 Adapter 30 Adapter body 301 Upper surface 302 Leg 303 Lower end surface (fixed surface)
305 Recessed part 31 Space 32 Engaging part 321 Guide plate 322 Rotation restricting member 323 Outer peripheral wall 34, 35 Engagement maintaining means 36 Engagement maintaining means 361 Abutting member (pin)
362 Upper end 363 Lower end 364 Spring seat 365 O-ring 366 Energizing member (spring)
367 Hole 368 Reduced diameter portion 369 Bush 4 Centrifuge (centrifugal bowl)
40 Stator 41 Bowl Head 42 Cover 43 Inlet 44 Outlet 45 Upper Outlet Pipe 46 Lower Inlet Pipe 461 Upper End 462 Flange 463, 464 Channel 47 Inlet Pipe 48 Seal Mechanism 481 Ring 482 Seal Member 483 Holding Member 484 Convex Part 50 Rotor 500 Rotation center axis 501 Concave / concave fitting part 502 Concave part 503 Convex part 505 Protruding part (protruding piece)
506 Concave part 51 Container body 511 Side wall 513 Lower end surface 515 Reduced diameter part 52 Bottom plate 521 Concave part 522 Inner surface (upper surface)
523 outer surface (lower surface)
53 Outer core 54 Inner core 55 Blood storage space 56, 57 Flow path 58 Sliding member 59 Shoulder portion 60 Dam portion

Claims (5)

A centrifuge fixing adapter for fixing a rotating body-shaped centrifuge having a blood storage space therein to a turntable for rotational driving,
A disc-shaped adapter body that can be fixed to the turntable;
Engaging portions provided on the adapter main body and detachably engaged with a plurality of protrusions formed to protrude outwardly from the outer peripheral portion of the bottom of the centrifuge;
Engagement maintaining means for maintaining the engagement state of the protrusion with respect to the engagement portion,
The engagement maintaining means is urged so as to displace a contact member that is displaceable between a contact position that contacts the protrusion and a retracted position that does not contact the protrusion, and the contact member is moved to the retracted position. And when the adapter body is fixed to the turntable, the contact member is configured to displace to the contact position against the biasing force of the bias member.
The centrifuge fixing adapter, wherein the centrifuge is rotated relative to the adapter main body in a predetermined direction to engage and fix the protrusions and the engaging portions. The centrifuge fixing adapter according to claim 1 , wherein the protrusion is configured by a flange-shaped protrusion. The engaging portion is formed at a position spaced apart from the upper surface of the adapter main body by a predetermined distance and substantially parallel to the upper surface, and substantially perpendicular to the upper surface. The centrifuge fixing adapter according to claim 1 , further comprising a rotation restricting member that restricts movement. The centrifuge fixing adapter according to any one of claims 1 to 3 , wherein the centrifuge fixing adapter is fixed to the turntable by setting the inside to a negative pressure. The centrifuge includes a stator having a blood inlet and a blood component outlet, and a rotor having an annular blood storage space and a container main body rotatably supported by the stator. The centrifuge fixing adapter according to any one of claims 1 to 4 , which is configured.

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