JP2011224225A - Mixer of two-chamber container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mixer, mounted by simple operation to perform mixing, and simply detached after mixing to be used as a container holding the mixed agent.SOLUTION: In this two-chamber container, a first holding chamber R1 is partitioned by a first movable wall A6 and a second movable wall A7, a second holding chamber R2 is partitioned above the second movable wall A7, and a communicating recessed part 13 communicating the interior of the first holding chamber R1 with the interior of the second holding chamber R2 through the outer periphery of the second movable wall A7, when the first movable wall A6 is pushed in, is recessed in the inner periphery of the second holding chamber R2. A cylindrical base B4, where the two-chamber container A can be locked to be prevented from slipping out upward and the two-chamber container is removably fitted, is rotatably mounted on a pedestal B1, and a mechanism for lifting a pressing body B6 with small force by relative rotation of the cylindrical base B4 to the pedestal B1 is provided. The first movable wall A6 is pushed up by the tip of the rising pressing body B6 to mix two agents in the respective holding chambers.

Description

  The present invention relates to a mixing device for a two-chamber container.

  Provided with a container for injection solution components configured such that a plurality of drugs such as components of an injection solution are kept in an isolated state, and these drugs can be mixed and dissolved by an external action An injection device has been proposed. (For example, see Patent Document 1)

  The front end is sealed by a membrane that can penetrate the container, and the solid component of the injection solution is stored in a space between the penetrable membrane and the front movable wall member, and the front movable wall member and the rear movable wall member. The liquid component of the injection solution is accommodated in the space between and the liquid component flows over the front movable wall member when the rear movable wall member moves together with the liquid and the front movable wall member on the tubular wall. And a communication passage for mixing with the solid component.

  In addition, the injection device includes holder means that can fix the container therein so that the components of the injection solution are mixed together. This holder means is composed of two tubular members, a tubular member provided in a double cylinder shape on the outer periphery of the container, and a tubular member in which the outer periphery of the tip is screwed to the inner periphery of the tubular member. When the container is screwed, the rear movable wall member of the container is moved forward together with the liquid and the front movable wall member, so that the liquid flows into the solid component space through the communication passage and mixes the liquid with the solid component. And a pressing mechanism for adjusting the solution.

Japanese Patent Publication No. 06-063611

  The above device is excellent in that the components can be mixed very quietly and safely, but since the holder means and the pressing mechanism are integrated with the container, the replacement operation at the time of reuse is complicated. Become.

  In the present invention, as in the above-described conventional example, the first movable wall includes a first storage chamber defined by the first movable wall and the second movable wall, and a second storage chamber defined above the second movable wall. For a two-chamber container in which a communication recess is formed in the periphery of the second storage chamber through the outer periphery of the second movable wall when the second storage wall is pushed, A mixing apparatus is proposed that can be mounted and mixed, and can be easily detached after mixing and used as a container containing a mixed material.

  The first means is configured as follows. That is, the first movable wall A6 and the second movable wall A7 define the first storage chamber R1, and the second storage chamber R2 is partitioned above the second movable wall A7, and the second movable chamber A6 is pushed when the first movable wall A6 is pushed. A two-chamber container A having a communication recess 13 communicating with the inside of the first storage chamber R1 and the second storage chamber R2 through the outer periphery of the movable wall A7 is detachably mounted on the inner periphery of the second storage chamber R2. A mixing device for two-chamber containers to be mixed. The two-chamber container A is detachably mounted on the pedestal B1, and fitted to the upper part so that it can be locked in a state in which it is prevented from coming out upward. A cylindrical base B4 having a vertical guide groove 42 vertically provided in the lower portion thereof, and a guide base 42 mounted on the outer periphery of the guide base 42 so as to be rotatable relative to the cylindrical base B4. A spiral cylinder B5 having an inclined surface 71 rising in a predetermined direction along the upper surface, a pressing body B6 mounted in the guide cylinder 42 so as to be movable up and down, and a cylinder for the base B1 And a booster mechanism that decelerates and rotates the helical cylinder B5 relative to the cylindrical base body B4 by relative rotation of the base body B4. The booster mechanism is disposed on the base B1 and has a first gear 37 formed at the center. One gear member B2, a plurality of second gears B3 meshed with the first gear 37 and arranged to be able to rotate and revolve around the first gear 37, and a helical cylinder B5 around each second gear B3 A third gear 73 provided on the inner surface and meshing with each second gear B3 is provided, and each second gear B3 can be revolved around the first gear 37 in conjunction with the rotation of the cylindrical base B4. Thus, the helical cylinder B5 is configured to rotate at a reduced speed relative to the rotation of the cylindrical base B4, and the tip of the sliding protrusion 78 projecting from the outer periphery of the pressing body B6 is mounted on the inclined surface 71 via the vertical cut groove 41. At the same time, the pressure body B6 is raised by the rotational speed difference between the spiral cylinder B5 and the guide cylinder 42 due to the rotation of the cylindrical base B4 with respect to the base B1, and the tip of the pressure body B6 that rises From pushing up the first movable wall A6 was composed as mixing two agents each accommodating chamber.

  The second means is configured as follows. That is, in the first means, the first gear member B2 is a base having a top cylindrical shape with a lower end opening disposed in a recessed portion 31a formed in a central portion of the bottom wall 31 of the base B1. 36, the first gear 37 is erected on the upper surface of the base, and the bottom wall 43 of the cylindrical base B4 is formed in such a manner that the high bottom wall 43c is extended from the peripheral low bottom wall 43a through the standing wall 43b. And the second gear B3 is pivotally supported on the three shafts 44 suspended from the lower surface of the high-bottom wall 43c so that the rotation of the cylindrical base B4 and the revolution of each second gear B3 are linked to each other. The third gear 73 located on the outer periphery of the standing wall 43b and the second gears B3 are engaged with each other through the connecting window 45 formed in a predetermined position of 43b.

  The third means was configured as follows. That is, in either the first means or the second means, the first gear member B2 is rotatably mounted on the base B1, and the ratchet is provided between the base B1 and the first gear member B2. A mechanism is provided so that the first gear member B2 cannot rotate in a predetermined direction and can rotate in the reverse direction.

  The fourth means is configured as follows. That is, in any one of the first to third means, the spiral cylinder B5 includes an inclined surface 71 and a vertical surface 75 continuous with the inclined surface 71. A pair of chevron-shaped portions formed along the peripheral surface with the vertical surface 75 are provided at opposing positions.

  The fifth means is configured as follows. That is, in any one of the first to fourth means, a confirmation window 48 is provided on the peripheral wall 40 of the cylindrical base B4 so that the sliding projection 78 of the pressing body B6 at the lowest position faces. It was.

  According to the present invention, when the two-chamber container A is used, the two-chamber container A can be mounted and the two agents can be mixed by a simple operation, and can be easily removed after mixing. In addition, since the rotation of the cylindrical base B4 relative to the pedestal B1 is equipped with a booster mechanism that decelerates and rotates the helical cylinder B5 relative to the cylindrical base B4, the pressing body B6 can be raised by a small force, and as a result In addition, it has the advantage that mixing of two agents can be done with a small force.

  The booster mechanism meshes with the first gear member B2 which is disposed on the base B1 and has the first gear 37 formed at the center, and the first gear 37, and rotates and revolves around the first gear 37. A plurality of second gears B3 arranged in a possible manner, and a third gear 73 provided on the inner surface of the spiral cylinder B5 around each second gear B3 and meshing with each second gear B3, Since each second gear B3 is configured to revolve around the first gear 37 in conjunction with the rotation, the spiral cylinder B5 is configured to rotate at a reduced speed with respect to the rotation of the cylindrical base B4. In addition, there is an advantage that the size of the entire apparatus can be formed compactly by efficiently arranging the members constituting the booster mechanism.

  The first gear member B2 includes a base 36 having a cylindrical shape with a lower end opening disposed in a recessed portion 31a provided in the center of the bottom wall 31 of the base B1, and the first gear is disposed on the upper surface of the base. 37 is formed, and the bottom wall 43 of the cylindrical base body B4 is formed in a form in which the high bottom wall 43c is extended from the peripheral low bottom wall 43a through the standing wall 43b, and is suspended from the lower surface of the high bottom wall 43c. The second gear B3 is pivotally supported by the three shafts 44, respectively, and the rotation of the cylindrical base B4 and the revolution of each second gear B3 are linked to each other via a connecting window 45 formed at a predetermined position on the standing wall 43b. When the third gear 73 positioned on the outer periphery of the standing wall 43b and each second gear B3 are meshed with each other, in addition to the above effects, the members constituting the booster mechanism can be arranged more efficiently. Become.

  The first gear member B2 is rotatably mounted on the base B1, and a ratchet mechanism is provided between the base B1 and the first gear member B2, so that the first gear member B2 cannot be rotated in a predetermined direction. In the case where the rotation in the reverse direction is possible, the booster mechanism acts only in a predetermined direction for raising the pressing body B6, and in the opposite direction, the first gear member B2 idles and a wasteful load is applied. As a result, it plays a role in preventing damage to the apparatus.

  The spiral cylinder B5 includes an inclined surface 71 and a vertical surface 75 that is continuous with the inclined surface 71, and a pair of chevron-shaped portions formed along the peripheral surface of the inclined surface 71 and the vertical surface 75 at the opposing positions. When the two-chamber container A is mixed, if the cylindrical base B4 is further rotated relative to the pedestal B1, the pressing body B6 falls by its own weight after reaching the highest rising position of the inclined surface 71. Thus, the pressing body B6 can be returned to the base end position of the original inclined wall 71.

  When a confirmation window 48 is provided on the peripheral wall 40 of the cylindrical base B4 so that the sliding projection 78 of the pressing body B6 at the lowest position faces, the mixing device B is used once and then becomes the original usable state again. There is an advantage that can be surely recognized.

It is a partially notched front view of the mixing apparatus equipped with the two-chamber container. It is a half sectional view showing a two-chamber container. The base is shown, (a) is a plan view and (b) is a half sectional view. The 1st gear member is shown, (a) is a top view, (b) is a half sectional view, (c) is a bottom view. The 2nd gearwheel is shown, (a) is a top view, (b) is a sectional view, (c) is a bottom view. The 1st lower cylindrical base | substrate is shown, (a) is a top view, (b) is a half sectional view, (c) is a bottom view. The 2nd lower cylindrical base | substrate is shown, (a) is a top view, (b) is a half sectional view, (c) is a bottom view. It is principal part explanatory drawing of a 2nd lower cylindrical base | substrate. An upper cylindrical base | substrate is shown, (a) is a top view, (b) is a half sectional view, (c) is a bottom view. A spiral cylinder is shown, (a) is a plan view and (b) is a half sectional view. It is explanatory drawing which shows a boost mechanism. The pressing member is shown, (a) is a plan view and (b) is a half sectional view. It is a partially notched front view of the mixing apparatus equipped with the two-chamber container after mixing the two-chamber container.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  In FIG. 1, A indicates a two-chamber container, and B indicates a mixing device for the two-chamber container A.

  As shown in FIG. 2, the two-chamber container A includes a main body A1, an inner plug A2, a fixed frame A3, a needle mounting member A4, a cap A5, a first movable wall A6, and a second movable wall A7. It has.

  The main body A1 is integrally formed by fitting and connecting a cylindrical inner peripheral wall 10 and a cylindrical outer peripheral wall 11 by a connecting cylinder member 12 fitted to the lower end. In addition, a communication recess 13 is formed at a predetermined position in the middle portion of the inner peripheral wall 10 in the vertical direction so that the predetermined vertical width is recessed outward (inflated), and the upper end of the inner peripheral wall 10 is reduced in diameter. It is formed in the reduced diameter portion 10a. In addition, a pair of engaging protrusions 14 project from the opposing position of the outer surface lower portion of the outer peripheral wall 11.

  The inner plug A2 is formed of a flexible and elastic material, and includes a lid plate portion 16 having a peripheral portion placed on the upper surface of the reduced diameter portion 10a and closing the upper end opening of the reduced diameter portion 10a. A seal cylinder 17 suspended from the back surface is configured to be liquid-tightly fitted to the inner periphery of the reduced diameter portion 10a.

  The fixing frame A3 plays a role of fixing the inner plug A2 to the reduced diameter portion. The fixed frame A3 extends from the upper end of the peripheral wall portion 19 tightly fitted to the outer periphery of the reduced diameter portion 10a by extending a flange portion 20 that presses the upper peripheral edge portion of the cover plate portion 16, and a screw thread is provided on the outer periphery of the peripheral wall portion 19. There are around.

  The needle mounting member A4 has a top plate 23 extending from the upper end of the screw tube 22 screwed to the outer periphery of the peripheral wall portion 19, and a metallic needle 24 is fitted and fixed to the center of the top plate 23, and is mounted on the fixed frame A3. In doing so, the lower part of the needle 24 is passed through the lid plate part 16 of the inner plug A2, so that the mixture can be poured out.

  The cap A5 is detachably attached to the needle attachment member A4.

  As shown in FIG. 1 or FIG. 2, the first movable wall A6 and the second movable wall A7 are fitted to the inner peripheral wall 10 inner surface so as to be slidable in a liquid-tight manner at predetermined intervals. A first storage chamber R1 is defined between the first movable wall A6 and the second movable wall A7, and a second storage chamber R2 is defined above the second movable wall A7 (on the side of the needle mounting member A4). ing. The second movable wall A7 is fitted at a predetermined position below the communication concave portion 13, in other words, the communication concave portion 13 is recessed at a predetermined position above the second movable wall A7. In addition, the vertical width of the outer peripheral edge of the second movable wall A7 (contact portion with the inner surface of the inner peripheral wall 10) is smaller than the vertical width of the communication recess 13 and the second movable wall A7 reaches the upper and lower intermediate portions of the communication recess 13. The top and bottom communicate with each other.

  The mixing device B includes a base B1, a first gear member B2, a plurality of second gears B3, a cylindrical base B4, a spiral cylinder B5, and a pressing body B6.

  As shown in FIG. 3, the pedestal B1 includes a peripheral wall 30 having a taper extending downward, and a recessed portion 31a in which a central portion of a bottom wall 31 extending from an intermediate portion in the vertical direction of the peripheral wall 30 is recessed downward. Is formed. In addition, a plurality of ratchet projections 32 project from the upper surface of the recessed portion 31a at equal intervals in the circumferential direction. Each ratchet projection 32 constitutes a ratchet mechanism for locking (resting) rotation of a first gear member, which will be described later, in a predetermined direction, and allowing rotation in the reverse direction, and tilts one surface in the circumferential direction. The other surface is formed on the vertical surface 32b. Further, a protrusion 33 is intermittently provided on the inner surface of the peripheral wall 30 above the bottom wall 31, and a knurl 34 is provided on the outer surface of the peripheral wall 30.

  The first gear member B2 has an externally toothed first gear 37 erected at the center of the upper surface of the base 36 having a cylindrical shape with a bottom opening that is rotatably mounted in the recessed portion 31a of the base B1. As shown in FIG. 4, a plurality of ratchet claws 38 protrude from the back surface of the base 36. Each ratchet pawl 38 engages with a ratchet protrusion 32 projecting from the recessed portion 31a of the base B1 when rotating in a predetermined direction to prevent rotation in that direction, and when rotating in the opposite direction, the ratchet It is configured to be able to rotate over the projection 32. In the illustrated example, when the first gear member B2 is clockwise, the ratchet pawl 38 comes into contact with the vertical surface 32b so that no further rotation is possible. The first gear member may not be provided with such a ratchet mechanism but may be simply fixed on the base B1 so as not to rotate, or formed integrally with the base.

  The second gear B3 meshes with the first gear 37 and is arranged so as to be able to rotate and revolve around the first gear 37. As shown in FIG. Three pieces are arranged around the first gear 37.

  The cylindrical base body B4 has a cylindrical shape which is erected on the base B1 so as to be rotatable, and the upper part of the cylindrical base body B4 is detachable and can be locked in a state where it is prevented from coming out upward. Can be fitted. In addition, a guide cylinder 42 having a double cylindrical shape with the peripheral wall 40 is suspended in the lower part, and a longitudinal groove 41 is vertically provided in the guide cylinder 42.

  In the illustrated example, the cylindrical base B4 is configured by fitting an upper cylindrical base B4b on a lower cylindrical base B4a. Further, the lower cylindrical base B4a includes the first lower cylindrical base B4a1 and the first cylindrical base B4a1. It consists of two lower cylindrical bases B4a2, and is composed of three members as a whole.

  As shown in FIG. 6, the first lower cylindrical base B4a1 has a bottom wall 43 extending inward from the lower end of the lower peripheral wall 40a constituting the lower portion of the peripheral wall 40. The bottom wall 43 is configured such that the peripheral edge portion is an annular low bottom wall 43a and the center portion is a high bottom wall 43c via a standing wall 43b. Further, three shafts 44 are suspended at predetermined positions on the center circle of the bottom surface of the high bottom wall 43c at equal intervals in the circumferential direction. Further, three connecting windows 45 are drilled in portions extending from the standing wall 43b to the inner edge of the low bottom wall 43a corresponding to the position where each shaft 44 is suspended. A protrusion 46 is provided around the lower end of the outer periphery of the lower peripheral wall 40a, a flange 47 is provided above the protrusion 46, and a confirmation window 48 is provided at a predetermined position directly above the flange 47. Further, a concave portion 49 is provided at a position opposite to the inner peripheral upper portion of the lower peripheral wall 40a, a protrusion 50 is provided between the concave portions 49, and a knurl 51 is provided on the outer surface.

  As shown in FIGS. 7 and 8, the second lower cylindrical base B4a2 includes a guide cylinder 42 having a vertical groove 41 drilled from the lower end to the upper part, and the first lower cylindrical base body is provided at the upper end of the guide cylinder 42. A fitting portion 53 for fitting with B4a1 and the upper cylindrical base B4b is provided. The fitting portion 53 erects the first fitting tube 54 via a flange that extends outward from the upper end of the guide tube 42, and an annular locking protrusion that protrudes outward from the upper end of the first fitting tube 54. 55 is protruding. A pair of protrusions 56 project from the position facing the outer surface of the first fitting cylinder 54, and a protrusion 57 is laterally provided between the protrusions 56. Further, a step-like second fitting cylinder 58 is erected through a flange extending inward from the upper end of the guide cylinder 42, and a recess 59 is recessed at a position facing the lower outer surface of the second fitting cylinder 58. Has been established. Further, a protrusion 60 is provided around the upper end of the outer periphery of the second fitting cylinder 58. In addition, a cover wall 61 is provided which extends downward from the lower surface of the stepped portion of the second fitting cylinder 58 and then extends obliquely upward in the center direction.

  As shown in FIG. 9, the upper cylindrical base B4b is provided with a pair of protrusions 62 at a position opposed to the inner surface of the lower end of the upper peripheral wall 40b constituting the upper portion of the peripheral wall 40, and is located above the large diameter portion. A protrusion 63 is provided on the lower part of the inner surface of the upper peripheral wall 40b. The upper part of the upper peripheral wall 40b is formed in the small diameter part 64, and a pair of bulging parts 65 (outward bulging) are formed in the opposing part of the small diameter part. Further, a recess 70 in which one side end portion in the circumferential direction on the inner peripheral surface of each bulging portion 65 is recessed outward is vertically provided, and this portion is inserted through the engagement protrusion 14 of the two-chamber container A. Is forming. A guide protrusion 68 is provided on the lower surface of the bulging portion 65 so as to guide the engaging protrusion 14 descending the insertion path to the downward step portion 66 on the lower surface of the small diameter portion 64. The inner diameter portion of the small-diameter portion 64 is configured to be approximately the same or slightly larger than the lower outer diameter of the two-chamber container A so that the lower portion of the two-chamber container A can be inserted and fitted therein. When the engaging projections 14 of the container A are lowered through the insertion passages and the two-chamber container A is rotated relative to the upper peripheral wall 40b at the lowest position, the engaging projections 14 are formed on the downward step portion 66. The two-chamber container A is configured to be engaged to prevent the container A from coming out upward. Further, since the connecting cylindrical member 12 of the two-chamber container A comes into contact with the cover wall 61 at the lowest position, the two-chamber container A is stably held.

  Further, a climbing projection 69 and a locking projection 67 are provided at the lower end of the small-diameter portion 64, and the engagement projection 14 of the two-chamber container A guided by the insertion passage and the guide projection 68 gets over. It is configured such that it gets over the protrusion 69 and is locked between the overhang protrusion 69 and the locking protrusion 67.

  Then, the recess 49 and the protrusion 56 are fitted, and the protrusion 50 and the protrusion 57 are moved over and engaged, and the upper end of the lower peripheral wall 40a is fitted and fixed to the outer periphery of the first fitting tube 54. The first lower cylindrical base B4a1 and the second lower cylindrical base B4a2 can be integrated. Further, the protrusion 62 of the upper cylindrical base B4b is fitted into the recess 59 of the second fitting cylinder 58, and the protrusion 63 of the upper cylindrical base B4b and the protrusion 60 of the second fitting cylinder 58 are overcome. The upper cylindrical base B4b is fitted on the lower cylindrical base B4a so that the cylindrical base B4 can be formed. The cylindrical base B4 constructed in this manner is rotatable by preventing the upper end of the lower peripheral wall 40a from engaging with the inner surface of the pedestal peripheral wall 30 over the ridge 46 and the ridge 33 to prevent the upper part from coming out upward. The flange 47 is brought into contact with the pedestal peripheral wall 30. Further, each shaft 44 is rotatably fitted in the shaft hole 39 of each second gear B3, and each second gear revolves around the first gear 37 by rotating the cylindrical base B4. It is composed.

  The spiral cylinder B5 is mounted on the outer periphery of the guide cylinder 42 so as to be rotatable relative to the cylindrical base B4, and has an inclined surface 71 that gradually rises in a predetermined direction on the upper surface. In this example, as shown in FIG. 10, an inclined surface 71 that gradually rises in a predetermined direction along the circumference of the cylindrical wall 72 and an upper end of the inclined surface 71 are provided at opposing positions on the cylindrical cylindrical wall 72. A pair of chevron-shaped portions having a vertical surface 75 descending vertically is raised. Further, a bottom wall 74 is extended from the upper and lower intermediate portions of the inner surface of the cylindrical wall 72, and an inner tooth-shaped third gear 73 is provided around the lower end of the inner surface of the cylindrical wall 72 below the bottom wall 74. The bottom wall 74 is composed of an annular low bottom wall 74a having an outer peripheral edge and a high bottom wall 74c extending inwardly via a standing wall 74b.

  The spiral cylinder B5 described above has the lower end of the cylinder wall 72 positioned on the low bottom wall 43a between the lower peripheral wall 40a and the upright wall 43b of the lower cylindrical base B4a, and the upper part thereof is a guide cylinder 42 and the lower peripheral wall 40a. Also, the lower bottom wall 74a is positioned on the upper surface of the high bottom wall 43c of the lower cylindrical base B4a, and the second gears B3 protruding from the connecting windows 45 of the lower cylindrical base B4a are further provided. And the third gear 73 are engaged with each other, the lower end portion of the guide cylinder 42 is rotatably fitted between the standing wall 74b and the cylinder wall 72, and is rotatably attached to the cylindrical base B4. Yes.

  As shown in FIG. 12, the pressing body B6 has a lower end opened, and a cylindrical portion 77 is erected from the upper end of the top cylindrical base portion 76, and a pair of sliding protrusions 78 project from a position facing the outer surface of the base portion 76. Configured. Then, the base portion 76 is placed on the bottom wall 74 (high bottom wall 74c) of the spiral cylinder B5, and each sliding projection 78 is placed on the inclined surface 71 of the spiral cylinder B5 via each vertical groove 41. And wearing.

  In the present invention, there is provided a boosting mechanism for rotating the helical cylinder B5 at a reduced speed with respect to the cylindrical base B4 by relative rotation of the cylindrical base B4 with respect to the base B1. In this example, as shown in FIG. 11, a mechanism called a planetary gear mechanism is employed, and a first gear member B2 arranged on the base B1 and restricted in rotation in a predetermined direction, and the first gear member A plurality of second gears B3 meshed with the first gear 37 formed in the center and arranged to be able to rotate and revolve around the first gear 37, and the inner surface of the spiral cylinder B5 around each second gear B3 And a third gear 73 that meshes with each second gear B3, and each second gear B3 is configured to revolve around the first gear 37 in conjunction with the rotation of the cylindrical base B4. The spiral cylinder B5 is configured to rotate at a reduced speed with respect to the rotation of the cylindrical substrate B4.

  A case where the mixing apparatus configured as described above is used will be described. FIG. 1 shows a state in which the two-chamber container A is mounted on the mixing device B. From this state, when the cylindrical base B4 is rotated relative to the pedestal B1, the second gears B3 are rotated clockwise. Revolve. At that time, the first gear member B2 is rotated clockwise by the first gear 37 meshed with the second gear B3. The first gear member B2 rotates until its ratchet pawl 38 comes into contact with the vertical surface 32b of the ratchet projection 32. When these contact, the rotation stops, and the second gear B3 starts rotating while revolving. If the ratchet pawl 38 and the vertical surface 32b of the ratchet projection 32 are in contact with each other from the beginning, the first gear member B2 does not rotate from the beginning, and only the second gear B3 rotates clockwise. Revolve around.

  As the second gears B3 rotate (rotate), the third cylinder 73 meshed with them rotates the helical cylinder B5 in the clockwise direction. The clockwise rotation of the helical cylinder B5 is slower than the clockwise rotation of the cylindrical base B4, and as a result, the sliding protrusions 78 on the inclined surface 71 are guided by the vertical grooves 41 and are lifted. The pressing body B6 rises.

  The raised pressing body B6 pushes up the first movable wall A6, and accordingly, the content in the first storage chamber R1 pushes up and pushes up the second movable wall A7. When the second movable wall A7 reaches the communication recess 13, the contents in the first storage chamber R1 pass through the outer periphery of the second movable wall A7 and are introduced into the second storage chamber R2. Further, when the pressing body B6 is raised, as shown in FIG. 13, the first movable wall A6 rises until it comes into contact with the lower surface of the second movable wall A7, and the contents in the first accommodation chamber R1 become the second accommodation chamber R2. And mix thoroughly with the contents in the second storage chamber R2.

  Thereafter, when the cylindrical base B4 is further rotated clockwise with respect to the pedestal B1, the sliding protrusions 78 are all lifted up the inclined surface 71, and then are guided by the vertical surface 75 so that the pressing body B6 is caused by its own weight. Move down and return to the original state. Next, the two-chamber container A is rotated by a predetermined angle with respect to the cylindrical base B4 so that each engaging projection 14 is pivoted to a lower position of each insertion passage and then lifted upward. Can be easily removed from the mixing device B.

  When installing a new two-chamber container A, each engaging projection 14 is inserted through the insertion passage, the two-chamber container A is pushed in, and the two-chamber container A is rotated with respect to the mixing device B at the lowest position. Thus, the engaging protrusion 14 may be engaged with the downward stepped portion 66 between the locking protrusion 67 and the overpass protrusion 69.

  In addition, although the material which forms each said member is not specifically limited, a synthetic resin can be employ | adopted preferably.

A ... Two-chamber container
A1 ... Main unit
10 ... Inner peripheral wall, 10a ... Reduced diameter part, 11 ... Outer peripheral wall, 12 ... Connecting cylinder member, 13 ... Communication recess,
14 ... engagement protrusion
A2 ... inner plug
16… Cover plate part, 17… Seal tube
A3 ... Fixed frame
19 ... peripheral wall, 20 ... flange
A4 ... Needle mounting member
22 ... Screw, 23 ... Top plate, 24 ... Needle
A5… Cap
A6 ... 1st movable wall
A7 ... Second movable wall
R1 ... 1st containment chamber
R2 ... Second storage chamber B ... Mixing device
B1 ... pedestal
30 ... peripheral wall, 31 ... bottom wall, 31a ... recessed portion, 32 ... ratchet projection, 32a ... inclined surface,
32b… Vertical surface, 33… Projections, 34… Knurling
B2 ... 1st gear member
36 ... Base, 37 ... First gear, 38 ... Ratchet claw
B3 ... Second gear
39 ... Shaft hole
B4 ... Cylindrical substrate
40 ... peripheral wall, 41 ... longitudinal groove, 42 ... guide tube
B4a ... Lower cylindrical base
B4a1 ... 1st lower cylindrical base
40a: Lower peripheral wall, 43 ... Bottom wall, 43a ... Low bottom wall, 43b ... Standing wall, 43c ... High bottom wall, 44 ... Shaft, 45 ... Connection window, 46 ... Projection, 47 ... Flange, 48 ... Confirmation window, 49 ... recess,
50 ... Projections, 51 ... Knurling
B4a2 ... Second lower cylindrical base
53 ... fitting part, 54 ... first fitting cylinder, 55 ... locking protrusion, 56 ... protrusion, 57 ... protrusion,
58 ... second fitting cylinder, 59 ... concave, 60 ... projection, 61 ... cover wall
B4b ... Upper cylindrical base
40b ... Upper peripheral wall, 62 ... Projection, 63 ... Projection, 64 ... Small diameter part, 65 ... Swelling part,
66 ... downward step, 67 ... locking protrusion, 68 ... guide protrusion, 69 ... ride over protrusion,
70 ... recess
B5 ... spiral tube
71 ... Inclined surface, 72 ... Cylinder wall, 73 ... Third gear, 74 ... Bottom wall, 74a ... Low bottom wall, 74b ... Standing wall, 74c ... High bottom wall, 75 ... Vertical surface
B6 ... Pressing body
76… Base, 77… Cylinder, 78… Sliding protrusion

Claims (5)

  The first movable wall (A6) and the second movable wall (A7) define a first storage chamber (R1), and a second storage chamber (R2) is partitioned above the second movable wall (A7). When the movable wall (A6) is pushed in, the second concave chamber (13) has a communication recess (13) in which the inside of the first chamber (R1) and the second chamber (R2) communicate via the outer periphery of the second movable wall (A7). (R2) A two-chamber container mixing device that detachably attaches and mixes a two-chamber container (A) that is recessed in the inner periphery, and stands up rotatably on a pedestal (B1) (A) is detachable and fitted to the upper part so that it can be locked in a state where it is prevented from coming out upward, and a guide cylinder (42) with a longitudinal groove (41) is vertically installed in the lower part. The cylindrical base body (B4) and the cylindrical base body (B4) are mounted on the outer periphery of the guide cylinder (42) so as to be capable of mutual rotation, and an inclined surface (71) rising in a predetermined direction along the peripheral surface is provided. A pressing body mounted on the upper surface of the spiral cylinder (B5) and the guide cylinder (42) so as to be movable up and down. (B6) and a booster mechanism that decelerates and rotates the helical cylinder (B5) with respect to the cylindrical base body (B4) by relative rotation of the cylindrical base body (B4) with respect to the pedestal (B1). The first gear member (B2) disposed on the pedestal (B1) and having the first gear (37) formed at the center thereof is engaged with the first gear (37), and is arranged around the first gear (37). A plurality of second gears (B3) arranged so as to be capable of rotating and revolving, and provided on the inner surface of the spiral cylinder (B5) around each second gear (B3) and meshing with each second gear (B3). And a third gear (73), and each second gear (B3) is configured to revolve around the first gear (37) in conjunction with the rotation of the cylindrical substrate (B4). ), The tip of the sliding projection (78) projecting from the outer periphery of the pressing body (B6) is inclined through the longitudinal groove (41). (71) The spiral cylinder (B5) and the guide cylinder (42) are placed on the pedestal (B1) and rotated by the cylindrical base (B4). The pressure body (B6) is raised by the rotational speed difference between the two, and the first movable wall (A6) is pushed up by the tip of the pressure body (B6) that rises to mix the two agents in each storage chamber. A two-chamber container mixing device.   A base (36) in which the first gear member (B2) has a cylindrical shape with a lower end opening disposed in a recessed portion (31a) recessed in the center of the bottom wall (31) of the base (B1). The first gear (37) is erected on the upper surface of the base, and the high bottom wall (43c) is extended from the peripheral low bottom wall (43a) through the standing wall (43b). The cylindrical base body (B4) is formed on the bottom wall (43), and the second gear (B3) is pivotally supported on the three shafts (44) suspended from the lower surface of the high bottom wall (43c). The third position located on the outer periphery of the standing wall (43b) through the connecting window (45) drilled at a predetermined position of the standing wall (43b) by interlocking the rotation of (B4) and the revolution of each second gear (B3). The mixing device of the two-chamber container of Claim 1 which meshed | engaged the gear (73) and each 2nd gear (B3).   The first gear member (B2) is rotatably mounted on the pedestal (B1), and a ratchet mechanism is provided between the pedestal (B1) and the first gear member (B2), so that the first gear member (B2 The two-chamber container mixing device according to claim 1, wherein rotation in a predetermined direction is impossible and rotation in the reverse direction is possible.   The spiral cylinder (B5) includes an inclined surface (71) and a vertical surface (75) continuous with the inclined surface (71), and the inclined surface (71) and the vertical surface (75) are arranged along the circumferential surface. The mixing device of the two-chamber container of any one of Claim 1 thru | or 3 provided with a pair of the mountain-shaped part formed in an opposing position.   The confirmation wall (48) in which the sliding protrusion (78) of the pressing body (B6) at the lowest position is provided on the peripheral wall (40) of the cylindrical base body (B4). The mixing device of the two-chamber container as described in the paragraph.