JP4619708B2 - Organic synthesizer - Google Patents

Description

  The present invention relates to an organic synthesizer that synthesizes a reagent contained in a reaction container by stirring and heating the reagent in the reaction container.

  Conventionally, an organic synthesizer has been used as one that synthesizes many types of reagents at the same time or under different conditions at once, and tests the synthesized reagents all at once. This organic synthesizer synthesizes the reagents contained in the reaction vessel by stirring and heating the reagents in the reaction vessel, and generally comprises a plurality of reaction vessels 60 as shown in FIGS. A reaction container gripping part 62 that can be gripped, a stirring part 64 that stirs the reagent in the reaction container 60 gripped by the reaction container gripping part 62, and an opening of the reaction container 60, and the reagent is added to the reaction container 60 And a possible reagent addition unit 66 (see Patent Document 1).

  The reaction container gripping part 62 and the stirring part 64 are configured to be separable, and the reagent addition part 64 is configured to be attached to the opening at the upper end of the reaction container 60 gripped by the reaction container gripping part 62. Yes. The stirring unit 64 is provided with a rotating magnet for rotating a magnet put together with the reagent in the reaction vessel 60 for each reaction vessel 60 held by the reaction vessel holding unit 62, and the magnet in the reaction vessel 60 is rotated by this rotating magnet. By doing so, the reagent in the reaction container 60 is agitated. In addition, the stirring unit 64 includes a heating unit having a heater 68 that heats the lower portion of the reaction vessel 60. The heater 68 is provided for each reaction vessel 60 held by the reaction vessel holding portion 62 so as to protrude upward from the main body of the stirring portion 64. Further, a plurality of protruding temperature sensors 70 are provided at positions adjacent to the heater 68 of the stirring unit 64.

  The reaction vessel gripping part 62 is provided for each of the top plate 72 formed with a hole that can protrude above the gripped reaction vessel 60 and the reaction vessel 60 held below the top plate 72. A holding part 74 having an insertion hole into which the bottom part can be inserted, and a reflux block 76 provided for each reaction vessel 60 held between the top plate 72 and the holding part 74 and having a through-hole through which the reaction vessel 60 can penetrate; The recirculation block 76 and the support column 78 that supports the holding portion 74 with respect to the top plate 72 are provided. The heater 68 and the temperature sensor 70 of the stirring unit 64 are provided at positions that are aligned with the holding units 74 of the reaction vessel gripping unit 72, and the protruding heater 68 and temperature sensor 70 are inserted into the bottom surface of the holding unit 74. Possible insertion holes are provided. Therefore, heat is transmitted from the heater 68 of the heating unit to the lower side of the reaction vessel 60 through the holding unit 74. When the lower portion of the reaction vessel 60 is heated by the heater 68 of this heating unit, the reagent filled in the reaction vessel 60 evaporates, but is cooled and condensed at the position of the reflux block 76 of the reaction vessel 60, and again the liquid It is configured to be returned to.

JP 11-137990 A

  However, since the reaction container gripping part 62 is configured such that the plurality of holding parts 74 are integrated with the main body of the reaction container gripping part 62, only one type of reaction container 60 can be gripped. Therefore, when using reaction containers 60 having different shapes, organic synthesis cannot be performed at a time, and there is a problem that the reaction container holding part 62 must be replaced and performed multiple times.

  Further, as described above, in the conventional organic synthesizer, since the reagent heated by the heater 68 of the heating unit needs to be cooled by the reflux block 76, the heat of the heater 68 of the heating unit is transmitted to the reflux block 76. There is a problem that a certain distance must be provided between the holding unit 74 and the reflux block 76 so that the relatively short reaction vessel 60 cannot be used.

  Furthermore, as described above, the conventional organic synthesizer rotates the magnets contained in the reaction vessel 60 by rotating the rotating magnets of the stirring unit. Since each container 60 is provided in parallel, the magnetic force between adjacent rotating magnets may affect each other, and as a driving source for rotating the rotating magnet when the rotating speed is slow, such as when the rotating magnet starts rotating. It may give a load.

  The present invention solves the above-described problems, and provides an organic synthesizer that does not have to perform organic synthesis multiple times by replacing the reaction vessel gripping portion even if the reaction vessel has a different shape. This is the first purpose. The second object of the present invention is to provide an organic synthesis apparatus that can be used regardless of the length of the reaction vessel. Furthermore, a third object of the present invention is to provide an organic synthesizer that can rotate the stirring magnet without applying a load to the drive source of the stirring magnet.

  In order to achieve the first object, the present invention comprises a reaction container gripping part capable of gripping a plurality of reaction containers, a stirring part for stirring the reagent in the reaction container gripped by the reaction container gripping part, The reaction vessel gripping portion has an insertion hole into which at least the lower part of the reaction vessel can be inserted, and is separately provided for each reaction vessel to be gripped with respect to the main body of the reaction vessel gripping portion. And a reaction container holder configured to be detachable.

  Thus, according to the organic synthesis apparatus according to the present invention, the reaction vessel holder is configured to be detachable from the main body of the reaction vessel gripping unit as a separate body for each reaction vessel to be gripped. Even when reaction vessels with different shapes are used at the same time, by preparing reaction vessel holders with different shapes for each reaction vessel, organic synthesis can be performed in a single process without changing the reaction vessel gripping part. It can be carried out. In the organic synthesizer according to the present invention, the insertion hole of the reaction vessel holder is formed in accordance with the shape of the lower portion of the reaction vessel to be inserted, and is configured so that the lower portion of the reaction vessel can be inserted in a close state. It is preferable.

  The organic synthesizer according to the present invention further includes a reagent addition unit that is mounted above the reaction vessel and can add a reagent to the reaction vessel, and the reagent addition unit is a connection adapter that can be detached from the reagent addition unit. The upper end of the connection adapter is configured to be tightly joined to the lower end of the reagent addition unit, and the lower end is tightly joined to the opening of the reaction vessel. It is preferable that it is comprised. In this way, by configuring the reaction container to be connected to the reagent addition part via the connection adapter, for example, even if the reaction container has a different diameter size or shape at the upper end of the reaction container, By preparing a connection adapter that can be joined to the opening, a plurality of types of reagent addition portions need not be prepared. Further, by configuring the reagent adding part and the reaction vessel to be connected via the connection adapter in this way, it is possible to use, for example, a Bayer bin in which a thread is formed on the edge of the opening. When Bayer bin is used, it is possible to store the container without changing the container simply by capping the Bayer bin after synthesis, and there is an advantage that it is not necessary to prepare a reaction container and a storage container separately. Also, unlike the Bayer Bin, the lip-equipped test tube is not threaded at the upper end, so when attaching the lip-equipped test tube to the lower end of the connection adapter, a fixing ring with a thread formed on the outer peripheral surface It is desirable to tightly join the upper end of the test tube with a lip to the lower end of the connection adapter via

  Further, in the organic synthesis apparatus according to the present invention, the stirring unit includes a heating unit that heats a lower portion of the reaction vessel held by the reaction vessel holding unit, and heat of the heating unit is above the heating unit. It is preferable that a heat insulating plate is provided to prevent transmission to the upper side of the reaction vessel held by the reaction vessel holding portion. By providing the heat insulating plate in this manner, it is possible to prevent the heat of the heating unit from being transmitted to the upper side of the reaction vessel, so that even when a relatively short reaction vessel is used, the reflux is performed above the reaction vessel. It can be performed. In addition, when a relatively long reaction container is used, a certain distance is required between the syringe needle inserted from the reagent addition unit and the bottom surface of the reaction container. By using such a relatively short reaction container, Since the distance between the syringe needle inserted from the reagent addition section and the bottom surface of the reaction container can be shortened, the reagent can be charged from the syringe needle in a stable state.

  Furthermore, in the organic synthesis apparatus according to the present invention, the stirring unit includes a heating unit that heats a lower portion of the reaction vessel held by the reaction vessel holding unit, and the heating unit includes a lower portion of the reaction vessel holder. It is preferable that an insertion hole that can be inserted is formed. As described above, when the conventional organic synthesizer is attached to the stirring part of the reaction container, the heater or temperature sensor of the stirring part must be inserted into the insertion hole of the holding part of the reaction container holding part. In addition, since the number of reaction containers to be grasped is provided, it is necessary to insert twice the number of reaction containers into the insertion hole of the holding part together with the heater and the temperature sensor, and the work is complicated. However, since it is not necessary to provide an insertion hole for each heater or temperature sensor by forming an insertion hole into which the lower part of the reaction container holder can be inserted in the heating part, the work of attaching the reaction container gripping part to the stirring part is It can be done easily. In the organic synthesis apparatus according to the present invention, the insertion hole of the heating unit of the stirring unit is formed in accordance with the shape of the reaction vessel holder of the reaction vessel holding unit, and can be inserted with the outer peripheral surface of the reaction vessel holder in close contact with each other It is preferable that it is comprised.

  Furthermore, in the organic synthesizer according to the present invention, the stirring unit includes a rotating magnet that rotates a magnet accommodated in the reaction vessel together with the reagent, and the rotating magnet is held by the reaction vessel holding unit. Each reaction vessel is provided at a position aligned with the reaction vessel, and is configured to rotate in one direction in conjunction with it, and is attracted to the adjacent rotating magnet by the influence of magnetic force, and the other adjacent side It is preferable to arrange so as to repel the rotating magnet. By arranging the magnets to be attracted to the adjacent one side and repelled to the other side in this way, the number of magnets to be attracted and the number of repelled magnets are the same. Can be reduced. It is preferable that the adsorbing state with respect to the adjacent one rotating magnet and the repulsive state with respect to the other rotating magnet are arranged so as to be maintained even when these rotating magnets are rotating.

  Further, in the organic synthesis apparatus according to the present invention, the stirring unit further includes a support plate that supports the heating unit, and the heating unit includes a cooling member that cools the reaction vessel held by the reaction vessel holding unit. It is preferable to provide a cooling member support portion that can be supported, and a heater is preferably provided on the back surface of the support plate. Thus, by providing a heater on the back surface of the support plate that supports the heating portion, It is possible to prevent condensation on the back surface of the support plate during the cooling process.

  In order to achieve the second aspect of the invention, the present invention includes a reaction container gripping part capable of gripping a plurality of reaction containers, and a stirring part for stirring the reagent in the reaction container gripped by the reaction container gripping part. In the organic synthesizer provided, the stirring unit includes a heating unit that heats a lower portion of the reaction vessel held by the reaction vessel holding unit, and the heating unit heats the reaction vessel holding the heating unit above the heating unit. The heat insulation board which prevents that it propagates above the reaction container hold | gripped by the part is provided, It is characterized by the above-mentioned.

  In order to achieve the third aspect of the invention, the present invention includes a reaction container gripping part capable of gripping a plurality of reaction containers, and a stirring part for stirring the reagent in the reaction container gripped by the reaction container gripping part. In the organic synthesizer provided, the stirring unit includes a rotating magnet that rotates a magnet accommodated in the reaction vessel together with the reagent, and the rotating magnet is aligned with the reaction vessel held by the reaction vessel holding unit. The reaction vessel is provided at a position to be rotated in one direction in conjunction with it, and is attracted to the adjacent one side rotating magnet by the influence of magnetic force, and is adjacent to the other side rotating magnet. It is arranged so as to repel.

  As described above, according to the organic synthesizer according to the present invention, an organic synthesizer that does not have to perform organic synthesis over a plurality of times by replacing the reaction vessel gripping portion even if the reaction vessel has a different shape. It is possible to provide an organic synthesizer that can be used regardless of the length of the reaction vessel, and to rotate the stirring magnet without applying a load to the drive source of the stirring magnet. It is possible to provide an organic synthesis apparatus that can

  Next, examples of the organic synthesis apparatus according to the present invention will be described with reference to the drawings. FIG. 1 is a front conceptual view showing a use state of the organic synthesis apparatus according to the present embodiment, and FIG. 2 shows a state where the reaction vessel gripping portion 10 and the stirring section 12 of the organic synthesis apparatus according to the present embodiment are separated. FIG. The organic synthesizer according to the present embodiment includes a reaction container gripping part 10 that can grip a plurality of reaction containers 11, a stirring part 12 that stirs a reagent in the reaction container 11 gripped by the reaction container gripping part 10, and a reaction. A reagent addition unit 14 that is attached to the opening of the container 11 and that can add a reagent into the reaction container 11 is provided. As shown in FIG. 2, the reaction container holding unit 10 and the stirring unit 12 are configured to be separable. Has been. In the organic synthesizer according to the present embodiment, as the reaction vessel 11, a relatively long lip-equipped test tube 11A (first and second from the left in FIG. 1), a relatively short Bayer bin 11B (the middle in FIG. 1). ) And a relatively short test tube 11C with a lip (first and second from the right in FIG. 1).

  In the organic synthesizer according to the present embodiment, the reagent addition unit 14 is configured to be closely joined to the opening of the reaction vessel 11 (11A, 11B, 11C) via the connection adapter 16 as shown in FIGS. There are two types of connection adapters 16, one used for the test tubes 11 </ b> A and 11 </ b> C with lips and the other used for the Bayer bin 11 </ b> B. A screw thread is formed at the lower end of the reagent adding portion 14, and a thread groove into which the thread can be screwed as shown in FIG. 4 is formed on the inner peripheral surfaces of the upper ends 16A1 and 16B1 of the connection adapters 16A and 16B. Is formed.

  The inner peripheral surface of the base end portion 16B2 of the connection adapter 16B used for the Bayer bin 11B is formed with a thread groove that can be screwed with a thread formed on the edge of the opening of the reaction vessel 11B. As shown in FIG. 5, it is preferable to prepare a plurality of types of adapters 16B according to the diameter of the Bayer bin. Further, unlike the Bayer bin, the test tubes 11A and 11C are not formed with a thread at the upper end portion, so that the test tubes 11A and 11C are connected to the base end of the connection adapter 16A via the fixing ring 13 as shown in FIG. It is configured to be closely joined to the portion 16A2. That is, the inner peripheral surface of the fixing ring 13 formed in a cylindrical shape is provided with a flange that protrudes inward in the radial direction, and the upper end of this flange contacts the lower end of the lip portion of the test tubes 11A and 11C. The test tube 11A and 11B are tightly joined to the connection adapter 16A by screwing the thread formed on the outer peripheral surface of the fixing ring 13 into the thread groove formed on the inner peripheral surface of the lower end of the connection adapter 16A. can do. When a plurality of types of connection adapters 16A and 16B are prepared in this way, the upper end portions 16A1 and 16B1 joined to the reagent adding portion 14 have the same diameter and joined to the lower end portion 16A2 and Bayer bin joined to the test tubes 11A and 11C. It is preferable that only the lower end portion 16B2 is formed in accordance with the size and shape of the diameter of the test tube or Bayer bin. Thus, by making the upper end portions 16A1 and 16B1 have the same diameter, the size of the test tube or Bayer bin is set. It is not necessary to prepare a plurality of types of reagent addition sections 14 according to the above.

  As shown in FIG. 4, the upper portions of the communication holes 16A3 and 16B3 communicating from the upper ends 16A1 and 16B1 to the lower ends 16A2 and 16B2 of the joining adapters 16A and 16B are formed in a tapered shape that tapers downward. By forming the upper portion in a tapered shape, the syringe needle of the reagent injection syringe inserted from above the reagent adding portion 14 is stuck in the inner walls of the communication holes 16A3 and 16B3 of the connection adapters 16A and 16B at the time of insertion. Can be prevented.

  In the organic synthesizer according to the present embodiment, the reagent addition unit 14 using the connection adapter 16 is used, but is not limited to this, and there is no sliding with the opening of the test tube as shown in FIG. A joint that can be tightly joined, for example, an SPC transparent joint manufactured by Shibata Kagaku Co., Ltd. may be used to join the test tube. Thus, since there is no sliding part in a junction part, it is possible to maintain the transparency of a junction part, and it is possible to recognize the state of organic synthesis easily.

  The reaction vessel gripping part 10 is provided for each reaction vessel 11 and includes a reaction vessel holder 8 that holds each of the reaction vessels 11 and a frame body 9 that supports the plurality of reaction vessel holders 8. The reaction vessel holder 8 is provided with a top plate 18 in which a hole 18A that can be protruded above the reaction vessel to be grasped is formed, and an insertion hole 20A that is provided below the top plate 18 and into which the bottom of the reaction vessel can be inserted. A cylindrical holding unit 20, a reflux block 22 provided between the top plate 18 and the holding unit 20 and having a through-hole 22 </ b> A through which the reaction vessel can pass, and the reflux block 22 to the top plate 18. A first support member 24 for supporting and a second support member 25 for supporting the holding portion 20 with respect to the reflux block 22 are provided. The hole 18A of the top plate 18, the insertion hole 20A of the holding portion 20 and the reflux are provided. The through holes 22A of the block 22 are provided in alignment so that the reaction vessel 11 can be inserted. Fixing screws 19 for fixing the top plate 18 to the frame body 9 are provided at the front and rear edges 18C and 18D of the top plate 18, respectively.

  The insertion hole 20A of the holding unit 20 is configured to be insertable in a state where the lower outer peripheral surface of the grasped reaction container is in close contact, and is formed in accordance with the outer diameter of each reaction container to be inserted. Further, as shown in FIG. 8, a flange 20 </ b> B protruding outward in the radial direction is formed at the upper end of the holding portion 20 over the entire circumference, and the holding portion 20 has a front portion extending from the upper end to the lower end. A groove 20C penetrating from the insertion hole 20A to the insertion hole 20A is formed. Furthermore, the holding part 20 has a uniform outer diameter irrespective of the size of the insertion hole 20A. In the organic synthesizer according to this example, the outer diameter is the same as that of the thickest reaction vessel (for example, the Bayer bin on the right in FIG. 5). When using the thickest reaction vessel, the outer diameter is held in the reaction vessel holder 8. Without providing the part 20, the reaction vessel is directly inserted into the insertion hole 46 of the heating part 30, which will be described later. Thus, since the outer diameter of the holding part 20 is made uniform, the diameter of the insertion hole 46 of the heating part 30 described later can be made uniform regardless of the size of the reaction vessel. Furthermore, the holding unit 20 is made of a material having excellent thermal conductivity, for example, aluminum, so that heat from the heating unit 30 of the stirring unit 12 described later is transmitted to the reaction vessel inserted into the insertion hole 20A. It is configured. A heat insulating plate 26 made of polycarbonate is provided between the reflux block 22 and the holding unit 20, and an insertion hole 26A into which a reaction vessel to be grasped can be inserted is formed in the heat insulating plate 26. Yes.

  A total of three first support members 24 are arranged at the vertices of two isosceles triangles, one on the front side and two on the back side, centering on the hole 18A of the top plate 18 and the through hole 22A of the return block 22. As shown in FIG. 8, each of the first support members 24 includes a first support nut 24A provided over the reflux block 22 and the top plate 18, and a first screw for screwing the top plate 18 to the first support nut 24A. 24B and a second screw 24C for screwing the reflux block 22 to the first support nut 24A. When the first screw 24B and the second screw 24C are screwed into the first support nut 24A and are completely screwed to each other, a space 24D is formed between the respective tips. . By forming the space 24D in this manner, heat conduction between the top plate 18 and the reflux block 22 can be prevented. As shown in FIG. 9, a collar 24E is provided in the hole 18B through which the first screw 24B of the top plate 18 passes. The outer diameter of the collar 24E is slightly smaller than the inner diameter of the hole 18B, and the length of the collar 24E is slightly longer than the thickness of the top plate 18. For this reason, the reflux block 22 and the holding unit 20 are fixed to the top plate 18 with play, and this causes a slight shift in manufacturing and assembling the reaction vessel gripping unit 10 and the stirring unit 12. Even if it occurs, the holding part 20 can be easily inserted into the insertion hole 46 of the heating part 30 and the reaction gripping part 10 can be attached to the stirring part 12. A total of three second support members 25 are arranged at the positions of the vertices of two isosceles triangles, one on the front side and one on the back side, with the insertion hole 20A of the holding portion 20 and the through-hole 22A of the return block 22 as the centers. As shown in FIG. 8, each of the second support members 25 is provided across the second support nut 25 </ b> A provided across the heat insulating plate 26 and the flange of the holding portion 20, and across the heat insulating plate 26 and the reflux block 22. A collar member 25B, a third screw 25C for screwing the reflux block 22 to the second support nut 25A, and a fourth screw 25D for fixing the holding portion 20 to the second support nut 25A are provided. When the third screw 25C and the fourth screw 25D are screwed into the support nut 25A and are completely screwed to each other, a space 25E is formed between the respective tips. By forming the space 25 </ b> E in this way, it is possible to prevent the heat of the holding unit 20 from being transmitted to the reflux block 22. The heat insulating plate 26 is configured to be supported by being sandwiched between the second support nut 25A and the collar member 25B.

  As shown in FIG. 10, the frame 9 is formed in a rectangular frame shape composed of a pair of front and rear long sides 9B and a pair of left and right short sides 9C, and the front and rear short sides 9C are opposed to the front and rear long sides 9B. The upper portion has a thickness, and a grip portion 9D is provided on the upper surface thereof. The opening 9A of the frame body 9 is configured such that the holding portion 20 of each container holder 8 can be inserted, and the front and rear edges 18C and 18D of the top plate 18 of each container holder 8 are arranged side by side in the horizontal direction. It is configured to be placed on the front and rear long sides 9B. A screw hole 9B1 into which the fixing screw 19 can be screwed is formed at the position of the long side 9B aligned with the fixing screw 19 provided on the front and rear of the top plate 18, and the fixing screw 19 is formed in the screw hole 9B. By screwing, the container holder 8 can be detachably attached to the frame body 9. Therefore, the container holder 8 can be removed from the frame body 9 by loosening the fixing screws 19 of these top plates 18, so that the container holder 8 corresponding to various reaction containers 11 can be attached to the frame body 9.

  The stirring section 12 is provided with five rotating magnets 28A, 28B, 28C, 28D, and 28E for rotating a magnet that is put together with a reagent in the reaction container for each reaction container gripped by the reaction container gripping section 10, that is, five (see FIG. 11), and the rotating magnets 28A, 28B, 28C, 28D, and 28E rotate the magnets in the reaction vessel to stir the reagents in the reaction vessel. Each rotary magnet 28A, 28B, 28C, 28D, 28E is provided at a position aligned with the reaction container gripped by the reaction container gripping part 10. These rotary magnets 28A, 28B, 28C, 28D, and 28E have a single drive belt 29 attached thereto together with a drive pulley 27 connected to a drive source as shown in FIG. Are configured to rotate. Each rotary magnet 28A, 28B, 28C, 28D, 28E is formed in a disk shape, and a disk-shaped magnet is provided on one end side and the other end side in the planar direction. The direction of the magnetic force of these magnets is arranged to be different from each other, and each rotating magnet 28A, 28B, 28C, 28D, 28E is attracted to the adjacent one rotating magnet by the influence of the magnetic force. , It is arranged so as to repel the adjacent rotating magnet on the other side. The attracting state with respect to the adjacent one rotating magnet and the repulsive state with respect to the other rotating magnet are arranged so that they can be maintained even when these rotating magnets are rotating.

  Further, the stirring unit 12 includes a heating unit 30 that heats the lower part of the reaction vessel, and the heating unit 30 is in a state where the holding unit 20 of the reaction vessel holding unit 10 is in close contact as shown in FIGS. A heating unit main body 34 having an insertion hole 32 that can be inserted, a heater 36 that heats the heating unit main body 34, and a temperature sensor 38 that detects the temperature of the heating unit main body 34 are provided. The heater 36 and the temperature sensor 38 are provided in holes 40 </ b> A and 40 </ b> B formed upward from the bottom surface of the heating unit main body 34. An insertion hole 46 is formed in the heating part main body 34 so that the holding part 20 of the reaction vessel gripping part 10 can be inserted in close contact. The heating part main body 34 is thermally conductive like the holding part 20. It is composed of excellent materials such as aluminum. Therefore, heat is transmitted from the heater 36 of the heating unit 30 to the lower side of the reaction vessel through the holding unit 20. When the lower part of the reaction vessel is heated by the heater 36 of the heating unit 30, the reagent filled in the reaction vessel evaporates, but is cooled and condensed at the position of the reflux block 22 of the reaction vessel, and returned to the liquid again. It is configured to be. In addition, the heating unit main body 34 is formed with a groove 48 penetrating from the front to the insertion hole 46 from the upper end to the lower end thereof, and is configured to match the groove 20C of the inserted holding unit 20. As described above, the groove 48 of the heating unit main body 34 is aligned with the groove 20C of the holding unit 20, and thus penetrates from the front surface of the heating unit main body 34 to the insertion hole 20A of the holding unit 20, and the insertion hole 20A of the holding unit 20 is inserted. The reaction vessel inserted into the can be viewed from the front side of the heating unit main body 34.

  An opening 44A is formed at a position facing the heating unit 30 on the upper surface of the main body 44 of the stirring unit 12, and the upper surface of the main body 44 of the stirring unit 12 covers the opening 44A and supports the heating unit 30. A support plate 54 made of PTFE is provided. The heating unit 30 is attached to a support plate 54 on the upper surface of the main body 44 of the stirring unit 12 via a PTFE spacer 42. For this reason, it is possible to prevent the heat of the heating unit 30 from being transmitted to the main body 44 of the stirring unit 12. A cooling block support 52 for supporting the cooling block 50 is mounted on the rear surface of the heating unit 30 so as to protrude rearward. The cooling block support 52 has a front opening. The cooling block 50 is inserted between the opening and the rear surface of the heating unit 30 so as to be mounted. By attaching the cooling block 50 to the rear surface of the heating unit 30 in this way, the holding unit 20 can be cooled via the heating unit 30, and the reaction vessel 11 can be cooled. Thus, when the holding | maintenance part 20 is cooled via the heating part 30, the support plate 54 will be cooled and the back surface of the support plate 54 may condense. For this reason, in the organic synthesis apparatus according to the present embodiment, a film heater 56 is attached to the back surface of the support plate 54, and a thermostat 57 for controlling the film heater 56 is provided in the film heater 56. And by adjusting the temperature of the film heater 56 to, for example, 20 to 30 ° C. by the thermostat 57, it is possible to prevent the back surface of the support plate 54 from condensing. Further, a heat insulating material 58 such as a silicon sponge is interposed between the film heater 56 and the support plate 54. In this way, by interposing the heat insulating material 58 between the film heater 56 and the support plate 54, even when the heating unit 30 is heated, even if the temperature reaches 170 ° C., high temperature is prevented from being transmitted to the film heater 56. can do. In the organic synthesizer according to the present embodiment, a silicon sponge is used as the heat insulating material 58, but the present invention is not limited to this, and it may be made of a material that has heat insulating properties and does not affect the magnetic force.

  As described above, the organic synthesizer according to the present embodiment is configured such that the reaction vessel holder 8 provided separately for each reaction vessel 11 is detachable from the frame body 9, and the holding unit 20. Since various types of reaction containers can be gripped by forming in accordance with the size and shape of the bottom of the reaction container that grips the insertion hole 20A, even in a different reaction container, Organic synthesis can be performed. In addition, since the organic synthesis apparatus according to the present embodiment is provided with the heat insulating plate 26 between the holding unit 20 and the reflux block 22, even if the reaction vessel is relatively short, the reflux block 22 is heated. It is possible to prevent transmission. Furthermore, the organic synthesizer according to the present embodiment is arranged so that the rotating magnet is attracted to the adjacent one side and repels the other side, so that the number of magnets to be attracted and the number of repelling magnets are the same. As a result, it is possible to reduce the burden on the driving source that links these components. Furthermore, the organic synthesizer according to the present embodiment can be easily assembled only by combining the position of the holding unit 20 with the insertion hole 46 of the heating unit main body 34 when the reaction vessel gripping unit 10 is attached to the stirring unit 12. it can. Moreover, the organic synthesizer according to the present embodiment can use not only test tubes but also various reaction vessels such as Bayer bins by using the connection adapter 16.

It is a front conceptual diagram which shows the use condition of the Example of the organic synthesis apparatus which concerns on this invention. It is a front conceptual diagram which shows the state which isolate | separated the reaction container holding | grip part and stirring part of the organic synthesizer which concerns on a present Example. It is a front view of the state which connected the reagent addition part to the Bayer bin which is a reaction container via the connection adapter. It is front sectional drawing of a connection adapter. It is a figure corresponding to Drawing 4 in the state where it connected to various Bayer bins from which a diameter differs. It is a front view which shows the operation | movement which connects a reagent addition part to the test tube with a lip which is a reaction container via a connection adapter. It is a front view which shows the state which mounted | wore the test addition tube with the reagent addition part, without using a connection adapter. It is side surface sectional drawing of a reaction container holding part and a stirring part. It is a partial expanded sectional view of a reaction container holding part. It is a top view of a frame. It is a conceptual diagram which shows arrangement | positioning of the rotating magnet of a stirring part. It is a plane sectional view in the state where a holding part was attached to a heating part. It is a front conceptual diagram showing the conventional organic synthesizer. It is a front conceptual diagram which shows the state which isolate | separated the reaction container holding part and the stirring part of the conventional organic synthesizer.

Explanation of symbols

8 Reaction container holder 10 Reaction container holding part 11 Reaction container 12 Stirring part 20 Holding part 20A Insertion hole

Claims (5)

A reaction container gripper capable of gripping a plurality of reaction containers;
An agitation unit for agitating the reagent in the reaction vessel held by the reaction vessel holding unit;
In an organic synthesizer equipped with a reagent addition section that is mounted above each reaction container and can add a reagent to the reaction container.
The reagent addition unit is configured to be connectable to a reaction container via a connection adapter that is detachable from the reagent addition unit, and the upper end of the connection adapter is configured to be closely joined to the lower end of the reagent addition unit. The lower end is configured to be tightly joined to the opening of one reaction vessel ,
The reaction vessel gripping portion has an insertion hole that can be inserted with at least the lower outer peripheral surface of the reaction vessel being in close contact with each other, and is separately provided for each reaction vessel to be gripped with respect to the main body of the reaction vessel gripping portion. An organic synthesizer comprising a reaction vessel holder configured to be detachable . The stirring unit includes a heating unit that heats a lower portion of the reaction container gripped by the reaction container gripping part,
Above the the heating unit, No placement claim 1 Symbol wherein the heat insulating plate which heat of the heating unit is prevented from being transmitted to the above the reaction container held by the reaction vessel gripping portions are provided Organic synthesizer. The stirring unit includes a heating unit that heats a lower portion of the reaction container gripped by the reaction container gripping part,
The organic synthesis apparatus according to claim 1 or 2 , wherein an insertion hole into which the lower part of the reaction vessel holder can be inserted is formed in the heating unit. The stirring unit includes a rotating magnet that rotates a magnet housed in the reaction container together with the reagent,
The rotating magnet is provided for each reaction container at a position aligned with the reaction container gripped by the reaction container gripping part, and is configured to rotate in one direction in conjunction with one another. 2. The magnets according to claim 1, wherein the magnets are arranged so as to be attracted to the rotating magnets and repel the adjacent rotating magnets of the adjacent rotating magnets with different directions of magnetic force. 3. The organic synthesis apparatus according to any one of 3 . The stirring unit further includes a support plate that supports the heating unit,
The heating unit includes a cooling member support that can support a cooling member that cools the reaction vessel held by the reaction vessel holding unit,
The organic synthesis apparatus according to any one of claims 1 to 4, wherein a heater is provided on a back surface of the support plate.

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