JP6762996B2 - Liquid supply device - Google Patents

Description

The present invention relates to a liquid agent supply device, and more particularly to a liquid agent supply device for supplying a liquid agent from a liquid agent bottle containing a liquid agent to a medication bottle.

Conventionally, dispensing pharmacies and the like have been dispensing liquid medicines, which are liquid medicines. According to the prescription for the patient, one or more kinds of liquid preparations are sequentially injected into the dosing bottle in predetermined amounts, necessary excipients are injected, and the liquid preparation is prepared.

When dispensing a suspendable liquid preparation, the dispensing guideline requires that the liquid preparation in the liquid medicine bottle be agitated and then supplied to the medication bottle. Regarding agitation of a liquid agent, a configuration has conventionally been proposed in which a rotating unit that rotates while holding a plurality of liquid agent bottles is provided, and the liquid agent bottle is overturned by rotating the rotating unit 180 degrees (for example, a patent). Reference 1). Further, it has been proposed that the nozzle is inserted into the liquid medicine bottle containing the liquid medicine, and the liquid medicine in the liquid medicine bottle is repeatedly sucked and discharged to periodically stir the liquid medicine in the liquid medicine bottle (for example,). See Patent Document 2).

JP-A-2009-112673 International Publication No. 2010/110303

Patent Document 1 discloses a flow of a dispensing process in which a dispensing bottle is moved to a discharge position and then the liquid medicine bottle is overturned to stir the liquid medicine. However, this dispensing process requires time to stir the liquid before supplying the liquid to the dosing bottle. Therefore, there is a problem that the supply time of the liquid medicine to the medication bottle becomes long.

The present invention has been made in view of the above problems, and a main object thereof is to provide a liquid medicine supply device capable of shortening the supply time of the liquid medicine contained in the liquid medicine bottle to the medication bottle. ..

The liquid agent supply device of one aspect according to the present invention is a liquid agent supply device that supplies the liquid agent from the liquid agent bottle containing the liquid agent to the medication bottle, and is water for stirring the liquid agent in the liquid agent bottle. The operation of the agent stirring unit, the bottle holding unit that holds a plurality of liquid agent bottles including the first bottle containing the first liquid agent and the second bottle containing the second liquid agent, and the liquid agent supply device. It includes a control unit for controlling. The control unit operates the liquid agent stirring unit to stir the second liquid agent while supplying the first liquid agent from the first bottle to the medication bottle.

In the above liquid medicine supply device, preferably, the control unit starts supplying the second liquid medicine from the second bottle to the medication bottle after the supply of the first liquid medicine to the medication bottle is completed.

In the above liquid agent supply device, preferably, the first liquid agent does not require stirring before being supplied to the dosing bottle.

The liquid agent supply device preferably includes a bottle position changing unit that changes the position of a plurality of liquid agent bottles held in the bottle holding unit, and the control unit changes the position of the liquid agent bottle by the bottle position changing unit. In the meantime, the liquid agent stirring unit is operated to stir the second liquid agent.

The liquid agent supply device of another aspect according to the present invention has a plurality of liquid agent bottles containing the liquid agent, and includes a liquid agent supply unit that supplies the liquid agent from each liquid agent bottle to the medication bottle. Liquids include liquids that require agitation that need to be agitated prior to feeding into the dosing bottle. The liquid medicine supply device further includes a liquid medicine stirring unit that stirs the liquid medicine in the liquid medicine bottle, and a supply sequence in which each of the liquid medicines contained in a plurality of liquid medicine bottles is supplied from the liquid medicine bottle to the medication bottle. The control unit is provided to stir the stir-required liquid before the supply turn to supply the stir-required water to the medication bottle.

In the above liquid agent supply device, preferably, the control unit agitates the agitating necessary liquid while supplying the agitating liquid having a supply order earlier than that of the agitation necessary liquid to the medication bottle.

In the above liquid agent supply device, preferably, the liquid agent contains a stirring-free liquid agent that does not require stirring before being supplied to the medication bottle, and the control unit supplies the stirring-required liquid agent in the order of supply of the stirring-free liquid agent. Set the supply order so that it is later than.

According to the liquid medicine supply device of the present invention, the time for supplying the liquid medicine to the dosing bottle can be shortened.

It is a perspective view which shows the structure of the liquid agent supply device 1 of one Embodiment of this invention. It is a front view of the liquid agent supply device shown in FIG. It is sectional drawing of the liquid agent supply device along the line III-III shown in FIG. It is sectional drawing of the liquid agent supply device along the IV-IV line shown in FIG. It is sectional drawing of the liquid agent supply device along the VV line shown in FIG. It is a perspective view which shows the structure of the stirring unit which stirs a liquid agent in a liquid agent bottle. It is a side view of the stirring unit shown in FIG. It is sectional drawing of the stirring unit along the line VIII-VIII shown in FIG. It is a block diagram which shows the structure of the liquid agent supply device. It is a schematic diagram which shows the position of each liquid medicine bottle. This is an example of a table showing the current position of the liquid medicine bottle. It is an example of a table showing a liquid agent that requires stirring. This is an example of a prescription table showing the type of liquid medicine supplied to the medication bottle. It is a flowchart of the liquid agent supply process from a liquid agent bottle to a medication bottle using the liquid agent supply device which concerns on this embodiment. It is a flowchart which shows the detail of the step which determines the order shown in FIG. It is a flowchart which shows the detail of the step which calculates the TOTAL pouring time. It is a table which shows the present position of the liquid agent bottle when the liquid agent B is in a pouring position. It is a table which shows the present position of the liquid agent bottle when the liquid agent C is in the pouring position. It is a timing chart which shows the TOTAL pouring time when pouring liquid B, C, G in this order. It is a table which shows the present position of the liquid agent bottle when the liquid agent G is in the pouring position. 6 is a timing chart showing the TOTAL pouring time when pouring liquids G, B, and C in this order. 6 is a timing chart showing the TOTAL pouring time when pouring liquids G, C, and B in this order. It is a flowchart which shows the detail of the step of pouring a liquid agent shown in FIG. It is a flowchart which shows the subroutine which stirs a liquid agent. It is a timing chart which shows the TOTAL pouring time of Embodiment 2. It is a timing chart which shows the TOTAL pouring time of Embodiment 3. It is a timing chart which shows the TOTAL pouring time of Embodiment 4. It is a timing chart which shows the TOTAL pouring time of Embodiment 5.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings below, the same or corresponding parts are given the same reference number, and the description is not repeated.

(Embodiment 1)
FIG. 1 is a perspective view showing the configuration of the liquid agent supply device 1 according to the embodiment of the present invention. FIG. 2 is a front view of the liquid agent supply device 1 shown in FIG. FIG. 3 is a cross-sectional view of the liquid agent supply device 1 along the line III-III shown in FIG. FIG. 4 is a cross-sectional view of the liquid agent supply device 1 along the IV-IV line shown in FIG. FIG. 5 is a cross-sectional view of the liquid agent supply device 1 along the VV line shown in FIG. The liquid medicine supply device 1 of the present embodiment is used to supply the liquid medicine 5 which is a liquid medicine from the liquid medicine bottle 23 containing the liquid medicine 5 to the medication bottle 2 and dispense it according to a prescription for a patient. Be done.

The liquid medicine supply device 1 has a plurality of liquid medicine bottles 23 containing the liquid medicine 5, and a liquid medicine supply unit 3 for supplying the liquid medicine 5 from each liquid medicine bottle 23 to the medication bottle 2 and a medication bottle 2 A weight detecting unit 4 for detecting the weight of the liquid agent 5 contained in the water agent 5 is provided. The volume of the liquid agent 5 supplied to the dosing bottle 2 is calculated from the weight of the liquid agent 5 detected by the weight detection unit 4 and the specific gravity of the liquid agent 5. The liquid medicine supply unit 3 is controlled so that a predetermined volume of the liquid medicine 5 according to the prescription is supplied to the dosing bottle 2. The liquid agent supply unit 3 and the weight detection unit 4 are provided in the housing 6. The housing 6 is formed in a rectangular parallelepiped shape and is installed on a horizontal installation surface in an upright state.

A support frame 8 is provided inside the housing 6. The support frame 8 is arranged between the bottom plate 9 of the housing 6 and the top plate 10 of the housing 6, and more specifically, is arranged near the top plate 10 of the housing 6. The internal space of the housing 6 is partitioned by the support frame 8 into an upper space 11 above the support frame 8 and a lower space 12 below the support frame 8. A touch panel 14 and printers 17a and 17b are arranged on the front surface portion 13 of the housing 6. Further, the front surface portion 13 is formed with a lower opening 15 that communicates the lower space 12 with the outside of the housing 6.

The lower opening 15 is formed between the left and right side portions 16a and 16b of the front surface portion 13 of the housing 6. A curved plate-shaped front cover portion 18 that separates the lower space 12 from the outside of the housing 6 is arranged above the lower opening 15 between the left and right side portions 16a and 16b. The front cover portion 18 is formed of a transparent material so that the lower space 12 can be visually recognized from the outside on the front side of the housing 6. The front cover portion 18 is attached to one of the left and right side portions 16a and 16b via a hinge and is rotatably provided around the axis of the hinge, whereby the front cover portion 18 can be opened and closed. There is.

The liquid agent supply unit 3 is arranged in the lower space 12, and is supported by a rotating drum 21 which is a rotating body which is rotatably provided around an axis (hereinafter, referred to as “drum axis”) L1 which is vertical to the support frame 8. It is mounted on the upper surface of the frame 8 and has a drum rotation motor 22 that rotates the rotating drum 21 around the drum axis L1 with respect to the support frame 8. The liquid agent supply unit 3 is also provided on the rotary drum 21 and drives a plurality of pumps 24 for transferring the liquid agent from the plurality of liquid agent bottles 23 containing the liquid agent 5 to the medication bottle 2, and each pump 24. It has a pump drive unit 25 and. Each pump 24 may be a tube pump.

The rotary drum 21 holds a pump holding body 31 for holding each pump 24 and a bottle holding for holding a plurality of liquid agent bottles 23 in an upright state so that the opening 23A (see FIG. 8 described later) opens upward. It has a liquid medicine bottle holder 32 as a part. The liquid medicine bottle holder 32 is provided below the pump holder 31 and is formed in a flat plate shape having an annular shape in a plan view. Each pump 24 is arranged on the pump holder 31 at intervals in the circumferential direction (hereinafter, referred to as "drum circumferential direction") about the drum axis L1. On the liquid medicine bottle holder 32, each liquid medicine bottle 23 is arranged at intervals in the drum circumferential direction.

The number of the liquid agent bottles 23 and the pumps 24 mounted on the rotary drum 21 in the present embodiment can be arbitrarily changed according to the purpose. Each of the plurality of liquid medicine bottles 23 may contain a different liquid medicine 5, and the plurality of liquid medicine bottles 23 may contain the same kind of liquid medicine 5 which is frequently prescribed, and one or more liquid medicines may be contained. Bottle 23 may contain excipients such as normal water and simple syrup.

The pump drive unit 25 for selectively driving each of the pumps 24 has a fixed portion 37 fixed to the support frame 8 and a double-headed arrow shown in FIGS. 4 and 5 with respect to the fixed portion 37. A moving part 38 that is movably provided in the A direction), a moving motor 39 that is fixed to the fixed part 37 and moves the moving part 38 in the front-rear direction with respect to the fixed part 37, and a pump that is fixed to the moving part 38. It has a pump drive motor 40 for driving 24 and a pump drive motor 40. A stepping motor may be used as the pump drive motor 40.

A connecting member 42 is fixed to the tip of the drive shaft 41 that is rotationally driven by the pump drive motor 40. A connected member 44 to be connected to the connecting member 42 is fixed to the rotating shaft 43 of the rotor of each pump 24. By connecting the connecting member 42 and the connected member 44, the rotation of the pump driving motor 40 is transmitted to the pump 24. The pump 24 is configured to be driven for each pump 24 in conjunction with the intermittent drive of the drum rotation motor 22. The supply speed of the liquid agent 5 to the medication bottle 2 becomes higher as the rotation speed of the pump driving motor 40 becomes higher.

By driving the moving motor 39, the pump driving motor 40 moves in the front-rear direction. By moving the pump drive motor 40, the connecting member 42 of the pump driving motor 40 is connected to the connected member 44 of the pump 24, and the connecting member 42 is not connected to the connected member 44. And, can be switched.

For example, the connecting member 42 and the connected member 44 can be connected by moving the moving portion 38 forward by driving the moving motor 39. Further, by moving the moving portion 38 backward by driving the moving motor 39, the connection between the connecting member 42 and the connected member 44 can be released. The rotating drum 21 can rotate with respect to the support frame 8 in the disconnected state.

By driving the drum rotation motor 22 in the disconnected state, the connected member 44 of the specific pump 24 selected based on the prescription information input to the liquid agent supply device 1 becomes the connecting member of the pump driving motor 40. The rotary drum 21 is rotated to a position facing the 42, and after the rotation, the rotary drum 21 is switched to the connected state. Thereby, the selected specific pump 24 can be driven to dispense the liquid agent 5 supplied from the desired liquid agent bottle 23 into the dosing bottle 2. The connecting member 42 and the connected member 44 are both composed of gears, but any configuration may be used as long as it can transmit power.

A ring member 27 arranged horizontally with the drum axis L1 is rotatably arranged around the drum axis L1 at the upper end portion 26 of the rotating drum 21. Three or more support members 28 that support the ring member 27 are provided on the outer peripheral side of the ring member 27. The support members 28 are arranged at equal intervals in the circumferential direction of the drum.

Each support member 28 is provided so as to be rotatable relative to the support frame 8 around an axis parallel to the drum axis L1. A recess 29 is formed on the outer peripheral surface of each of the flat cylindrical support members 28 over the entire circumference. An annular ridge 30 is formed on the outer peripheral portion of the ring member 27 over the entire circumference. The ridge 30 of the ring member 27 fits into the ridge 29 of each support member 28. The ring member 27 and the support member 28 are provided so as to be rotatable relative to each other.

The drum rotation motor 22 is fixed to the support frame 8. A driving gear (not shown) is fixed to the rotating shaft of the drum rotation motor 22. A driven gear 33 that meshes with the driving gear is fixed to the upper end portion 26 of the rotating drum 21. The driven gear 33 is formed in an annular thin plate shape and is fixed to the lower surface of the ring member 27. The rotation of the drum rotation motor 22 is transmitted to the ring member 27 via the driving gear and the driven gear 33, whereby the ring member 27 and the rotating drum 21 to which the ring member is fixed rotate as one. With such a configuration, the rotating drum 21 can be smoothly rotated with respect to the support frame 8.

The drum rotation motor 22 includes a plurality of liquid agent bottles 23 mounted on the rotary drum 21, a pump 24 and a supply nozzle 36 provided corresponding to each of the plurality of liquid agent bottles 23, and one end of the liquid agent bottle 23. The tube 34, which will be described later and has the other end attached to the supply nozzle 36, is integrally rotated in the horizontal direction. The rotary drum 21 has a function as a bottle position changing unit that changes the positions of a plurality of liquid agent bottles 23 held by the liquid agent bottle holder 32 in the housing 6 of the liquid agent supply device 1.

The supply nozzle 36 is mounted on the same circumference of the outer peripheral portion of the nozzle mounting plate 53, which is an annular flat plate provided at the lower end of the pump holding body 31. The supply nozzles 36 are arranged on the nozzle mounting plate 53 on a virtual circle centered on the drum axis L1 at equal intervals in the drum circumferential direction. The supply nozzle 36 is inclined to the drum axis L1 at a predetermined angle and is attached to the nozzle mounting plate 53. The nozzle mounting plate 53 is arranged above the liquid agent bottle holder 32. The nozzle mounting plate 53 and the liquid agent bottle holder 32 are parallel to each other, and are configured to be rotatable around the drum axis L1 on a horizontal plane together with the rotating drum 21.

The weight detection unit 4 is arranged in the lower opening 15. The weight detection unit 4 is placed and fixed on the electronic balance 45, the casing 46 accommodating the electronic balance 45, and the electronic balance 45, and the medication bottle 2 is in an upright state so that the opening 2A opens upward. It has a medication bottle holder 47 to hold. The electronic balance 45 detects the weight of the liquid agent 5 supplied to the dosing bottle 2. When the weight of the liquid agent 5 reaches a predetermined value, the liquid agent supply unit 3 stops driving the pump 24 and stops the supply of the liquid agent 5 to the medication bottle 2. The electronic balance 45 may be of any type such as a tuning fork type, a load cell type or an electromagnetic type. The casing 46 is provided at the lower portion between the left and right side portions 16a and 16b on the front surface portion 13 of the housing 6. The medication bottle holder 47 has a mounting table 48 on which the medication bottle 2 is placed, and a holder 49 provided above the mounting table 48 to hold the medication bottle 2.

The weight detecting unit 4 is moved up and down by the elevating device 50 as a driving unit shown in FIG. The lifting device 50 moves the weight detecting unit 4 in the vertical direction so that it can be located at two positions, the initial position and the supply position, and accordingly, the weight detecting unit 4 is placed on the mounting table 48 of the weight detecting unit 4. Move the dosing bottle 2 that has been used. The initial position is a position for installing the medication bottle 2 on the mounting table 48 of the liquid agent supply device 1. The supply position is a position where the dosing bottle 2 and the supply nozzle 36 are closer than the initial position to supply the liquid agent 5 to the dosing bottle 2. The elevating device 50 reciprocates the medication bottle 2 from the outside to the inside of the housing 6 of the liquid agent supply device 1 so as to reciprocate between the initial position and the supply position.

FIG. 6 is a perspective view showing the configuration of a stirring unit that stirs the liquid agent 5 in the liquid agent bottle 23. FIG. 7 is a side view of the stirring unit shown in FIG. FIG. 8 is a cross-sectional view of the stirring unit along the line VIII-VIII shown in FIG. The liquid agent supply unit 3 of the present embodiment includes a liquid agent stirring unit that agitates the liquid agent 5 contained in the liquid agent bottle 23 inside the housing 6 of the liquid agent supply device 1. Hereinafter, the liquid agent stirring unit will be described in detail.

Note that FIGS. 6 to 8 show the liquid medicine bottle holder 32 on which only one liquid medicine bottle 23 is placed, giving priority to comprehensibility. Further, the liquid agent supply device 1 includes a plurality of cup fixing portions 76, 76A and cup 78 for holding the liquid agent bottle 23, and FIGS. 6 and 7 show the plurality of cup fixing portions 76, 76A and the cup 78. Only some of them are shown, and not all of them are shown.

A rotation drive unit 61 that generates a rotational force is arranged below the liquid agent bottle holder 32. As shown in FIG. 8, the rotary drive unit 61 includes a motor 62 as an example of a power source, and a box 63 for accommodating the motor 62 inside. A shaft portion 64 that rotates together with the motor 62 is connected to the rotating shaft of the motor 62. The shaft portion 64 is fixed to the motor 62 so as to be rotatable around the rotation shaft L3 integrally with the motor 62. The shaft portion 64 is arranged so as to extend inside and outside the box 63. The shaft portion 64 is arranged so as to penetrate the flat plate-shaped liquid medicine bottle holder 32 in the vertical direction, and the rotational force generated by the motor 62 is applied from the lower side of the liquid medicine bottle holder 32 to the upper side of the liquid medicine bottle holder 32. Communicate to.

The shaft portion 64 is surrounded by a cover 75 and is covered at the upper end thereof. The cup 78 is integrally fixed to the shaft portion 64 with the cover 75 interposed therebetween. The cup 78 is formed in a bottomed hollow cylindrical shape. The cup 78 functions as a holder for holding the liquid medicine bottle 23. The cup 78 holds the bottom 23B side of the liquid medicine bottle 23 shown in FIG. The liquid medicine bottle 23 is housed in the cup 78 so that the bottom portion 23B faces the inner bottom surface of the cup 78. The inner wall surface of the side wall of the cup 78 has a diameter slightly larger than the diameter of the side surface of the liquid medicine bottle 23. Therefore, the side surface of the liquid medicine bottle 23 faces the inner wall surface of the side wall of the cup 78 via a minute gap. A part of the side surface of the liquid medicine bottle 23 may come into contact with the inner wall surface of the side wall of the cup 78.

A tube 34 as a tube portion is arranged inside the liquid medicine bottle 23. The tube 34 is provided for each of the plurality of liquid agent bottles 23. The tube 34 is made of a material having flexibility and elasticity, and its cross section is deformable by pressing and elastically restored by releasing the pressing. The tube 34 may be made of a synthetic resin such as a silicon tube. The tube 34 extends from the opening 23A of the liquid medicine bottle 23 toward the bottom 23B, and is arranged inside the liquid medicine bottle 23 so that one end 34a thereof contacts the inner surface of the bottom 23B of the liquid medicine bottle 23. There is.

A base member 81 is fixed to the opening 23A of the liquid medicine bottle 23. The tube 34 is inserted into a through hole formed in the base member 81 and is arranged from the outside to the inside of the liquid agent bottle 23. As shown in FIG. 8, the base member 81 is fixed to the opening 23A of the liquid medicine bottle 23. A cylindrical spacer 82 made of an elastic material such as silicone rubber is attached to the inner peripheral surface of the base member 81. The base member 81 is an elastically deformable spacer so that the base member 81 can be reliably fixed to the opening 23A of the liquid agent bottle 23 even if the base member 81 or the liquid agent bottle 23 has dimensional variations. It is attached to the liquid medicine bottle 23 with the 82 interposed therebetween.

A cover 83 is arranged on the base member 81. The cover 83 is placed on the upper surface of the base member 81 in a non-fixed state with respect to the base member 81. The cover 83 is formed in a cap shape having a hollow cylindrical wall portion and a disk-shaped ceiling portion covering the upper end of the wall portion. The lower end of the wall portion abuts on the upper surface of the base member 81, and the cover 83 is placed on the base member 81. The cover 83 is provided so as to cover the opening 23A of the liquid medicine bottle 23 in a state where the cover 83 is placed on the base member 81 fixed to the liquid medicine bottle 23. A through hole having a diameter such that the tube 34 is just inserted is formed in the ceiling portion of the cover 83.

The ceiling portion of the cover 83 is further formed with a recessed portion 84 in which a part of the upper surface is recessed. A positioning member 85 is attached to the tube 34. The positioning member 85 is attached to the tube 34 without obstructing the flow of the liquid agent 5 flowing through the inside of the tube 34. Further, the positioning member 85 is attached to the tube 34 so that the tube 34 is difficult to move in the longitudinal direction with respect to the tube 34. The recessed portion 84 and the positioning member 85 are formed in a shape corresponding to each other so that the positioning member 85 fits in the recessed portion 84.

The positioning member 85 engages with the recessed portion 84 formed in the cover 83 to position the tube 34 to which the positioning member 85 is attached with respect to the liquid agent bottle 23. As shown in FIG. 8, when the positioning member 85 is housed in the recess 84 of the cover 83, one end 34a of the slightly curved tube 34 in the liquid bottle 23 comes into contact with the bottom 23B of the liquid bottle 23. As such, the positioning member 85 positions the tube 34 with respect to the liquid medicine bottle 23.

Further, a tube fixing portion 86 for fixing the tube 34 outside the liquid medicine bottle 23 is provided. As shown in FIG. 3, the tube fixing portion 86 is fixed to the lower surface side of the nozzle mounting plate 53. The tube 34 is fixed to the nozzle mounting plate 53 by holding the tube 34 in the tube fixing portion 86 in the state shown in FIGS. 7 and 8 in which the tube 34 is inserted into the liquid agent bottle 23. Will be done. The tube 34 is further fixed to the nozzle mounting plate 53 by being fitted into a notch 54 (see FIG. 5) formed in the nozzle mounting plate 53.

When the motor 62 of the rotation drive unit 61 is driven in the liquid agent stirring unit having the above configuration, the shaft unit 64 fixed to the motor 62 rotates together with the motor 62. The rotation direction of the motor 62 at this time is referred to as a positive direction. As the shaft portion 64 rotates in the forward direction, the cup 78 fixed to the shaft portion 64 and the liquid medicine bottle 23 held by the cup 78 rotate about the rotation shaft L3. The rotation axis L3 forming the central axis of rotation of the liquid agent bottle 23 is along the center line L2 of the liquid agent bottle 23. Here, the center line L2 of the liquid medicine bottle 23 means a straight line connecting the opening 23A and the bottom 23B of the liquid medicine bottle 23, and typically, the opening 23A of the liquid medicine bottle 23 having a circular shape in a plan view. Refers to a straight line connecting the center of the water agent bottle 23 and the center of the bottom portion 23B of the liquid medicine bottle 23 having a circular shape in a plan view.

In the embodiment illustrated in FIGS. 7 and 8, the liquid medicine bottle 23 is located in the center of the cup 78. As a result, the center line L2 of the liquid agent bottle 23 and the rotation shaft L3 of the rotation drive unit 61 exist in the same linear shape. In order to stir the liquid agent 5 more efficiently, the center line L2 of the liquid agent bottle 23 may be shifted from the rotation axis L3 of the rotation drive unit 61, and the center line L2 of the liquid agent bottle 23 may be displaced from the rotation drive unit 61. May be tilted with respect to the rotation axis L3 of.

With the rotation of the liquid agent bottle 23, the liquid agent 5 contained in the liquid agent bottle 23 moves the inside of the liquid agent bottle 23 along the rotation direction of the liquid agent bottle 23 to the cylinder of the liquid agent bottle 23. It flows in the circumferential direction of the side of the shape.

After rotating the motor 62 in the forward direction for a predetermined time, the motor 62 is subsequently rotated in the opposite direction to the forward direction. The rotation drive unit 61 is provided so as to be able to generate rotational force in both forward and reverse directions. The liquid agent supply device 1 may be configured so that the operator who operates the liquid agent supply device 1 can arbitrarily set the rotation direction and the rotation time of the motor 62. For example, the motor 62 is rotated in the forward direction for 5 seconds to rotate the liquid agent bottle 23 a plurality of times, and then the motor 62 is rotated in the reverse direction for 5 seconds to rotate the liquid agent bottle 23 in the reverse direction a plurality of times. The time between the forward rotation and the reverse rotation may be equal. Further, for example, the rotation direction of the motor 62 may be set only in the positive direction.

As the rotation direction of the motor 62 is switched, the rotation direction of the liquid agent bottle 23 is also switched. That is, the rotation drive unit 61 rotates the liquid agent bottle 23 in the forward direction and then rotates the liquid agent bottle 23 in the opposite direction to the forward direction. Inside the liquid agent bottle 23 whose rotation direction is switched and rotates in the opposite direction, the turbulence strength of the turbulent flow in the flow of the liquid agent 5 increases. In addition, a vortex is generated during the flow of the liquid agent 5. Due to the action of the turbulent flow and the vortex, the liquid agent 5 is agitated in the liquid agent bottle 23.

In this way, the liquid agent bottle 23 is rotated by the rotational driving force generated by the rotary drive unit 61, so that the liquid agent 5 contained in the liquid agent bottle 23 is agitated inside the liquid agent supply device 1. Can be done. Therefore, the liquid agent 5 that requires stirring can be efficiently dispensed in a short time by using the liquid agent supply device 1 of the present embodiment. With a simple configuration in which a rotation drive unit 61 is added as compared with the conventional device, the cup 78 holding the liquid agent bottle 23 and the liquid agent bottle 23 are integrally rotated, and the liquid agent 5 is supplied to the liquid agent supply device 1. Can be agitated within. By switching the rotation direction of the liquid agent bottle 23 from the forward direction to the reverse direction, the turbulence strength of the turbulent flow in the liquid agent bottle 23 can be increased, so that the liquid agent 5 can be agitated more efficiently. ..

Further, a tube 34 is arranged in the liquid medicine bottle 23 so as to extend from the opening 23A to the bottom 23B of the liquid medicine bottle 23, and the tube 34 is fixed outside the liquid medicine bottle 23. Therefore, the tube 34 rotates relative to the rotating liquid medicine bottle 23. Since the tube 34 is kept fixed to the liquid agent 5 flowing in the liquid agent bottle 23 together with the liquid agent bottle 23, the tube 34 functions as a stirrer for the liquid agent 5. That is, by arranging the tube 34 so as to be immersed in the liquid agent 5 in the liquid agent bottle 23, the flow of the liquid agent 5 tends to be turbulent. Therefore, the liquid agent 5 can be agitated more efficiently.

Next, the control in the case where the liquid agent 5 is supplied from the liquid agent bottle 23 to the medication bottle 2 to perform dispensing will be described. FIG. 9 is a block diagram showing the configuration of the liquid agent supply device 1. As shown in FIG. 9, the liquid agent supply device 1 includes a control unit 90 that controls the operation of the entire liquid agent supply device 1. The touch panel 14 functions as an input unit for inputting various parameters related to the operation of the liquid agent supply device 1 such as prescription data, and various information such as a patient name and a pharmacist name. The touch panel 14 also functions as a display unit for displaying the operating state of the liquid agent supply device 1. In addition to the touch panel 14, the liquid agent supply device 1 may include, for example, a lamp that lights up when a malfunction of the liquid agent supply device 1 occurs.

The electronic balance 45 detects the weight of the liquid agent 5 supplied to the dosing bottle 2, and inputs the value of the detected weight to the control unit 90. The control unit 90 supplies a predetermined amount of the liquid agent 5 to the medication bottle 2 while receiving the weight data of the liquid agent 5 in the medication bottle 2 from the electronic balance 45.

The liquid agent supply device 1 includes a bottle position detecting means 91 that detects the position of each liquid agent bottle 23 in the lower space 12 inside the housing 6. The bottle position detecting means 91 may be, for example, various sensors, and the sensor may detect the rotation angle of the liquid agent bottle holder 32 around the drum axis L1. Since the liquid medicine bottle 23 rotates around the drum axis L1 as the rotating drum 21 rotates, the current position of the liquid medicine bottle 23 changes frequently. The current position of the liquid medicine bottle 23 is accurately detected by using the bottle position detecting means 91, and the data related to the detected current position of the liquid medicine bottle 23 is input to the control unit 90.

The liquid agent supply device 1 also includes a communication unit 92 for communicating with an external device and receiving data from the external device. Various parameters related to the operation of the liquid agent supply device 1 may be input to the control unit 90 by the operation of the touch panel 14 described above, or instead, the control unit 90 may be input from an external computer via the communication unit 92. May be entered in.

The liquid agent supply device 1 also includes a memory 93 for the control unit 90 to perform calculations. The memory 93 may store data relating to the current position of the liquid agent bottle 23 and data of the liquid agent 5 housed in the liquid agent bottle 23 mounted on the liquid agent supply device 1. The liquid agent supply device 1 also includes a recording medium access unit 94 for mounting a removable recording medium. The data of the liquid agent 5 described above may be stored in various recording media mounted on the recording medium access unit 94, and may be appropriately read from the recording medium by the control unit 90.

The control unit 90 controls the liquid agent supply device 1 based on the information input from the various devices described above. Specifically, a control signal is transmitted from the control unit 90 to the drum rotation motor 22, the moving motor 39, the pump drive motor 40, the motor 62 for stirring the liquid agent 5, and the elevating device 50, and each motor. Is appropriately operated and stopped to supply the liquid agent 5 from the liquid agent bottle 23 to the dosing bottle 2. After the supply of the liquid medicine 5 is completed, a piece of paper on which the injection result is printed and a medication bottle 2 on which the patient name, pharmacy name, medication time, dosage amount, etc. are printed are attached from the printers 17a and 17b constituting the output unit 17. Label is output.

FIG. 10 is a schematic view showing the positions of the respective liquid agent bottles 23 detected by the bottle position detecting means 91. FIG. 11 is an example of a table showing the current position of the liquid medicine bottle 23. As shown in FIG. 10, it is assumed that eight liquid medicine bottles 23 can be mounted on the liquid medicine bottle holder 32 of the present embodiment. The positions where these eight liquid medicine bottles 23 are mounted on the liquid medicine bottle holder 32 are indicated by numbers 1 to 8 in FIG. The position indicated by the number 1 is the position on the frontmost side of the liquid agent supply device 1 where the liquid agent 5 contained in the liquid agent bottle 23 is discharged to the medication bottle, and this position is referred to as a pouring position.

As shown in FIG. 11, the eight liquid agent bottles 23 currently mounted on the liquid agent supply device 1 contain eight types of liquid agents A to H, respectively. At present, it is assumed that the liquid medicine bottle 23 containing the liquid medicine A is in the pouring position. It is assumed that the rotating drum 21 can rotate on both sides in the circumferential direction of the drum. The liquid medicine bottle holder 32 can rotate in both clockwise and counterclockwise directions. Therefore, the time for moving the liquid agent B and the liquid agent H arranged next to the liquid agent A currently in the pouring position to the pouring position is the same.

In the following example, the time required to rotate the liquid medicine bottle holder 32 by 45 °, that is, the time required to move the adjacent liquid medicine B to the pouring position when the liquid medicine A is currently in the pouring position is tentatively set. Set to 3 seconds. In this case, the moving time is proportional to the moving distance of the liquid medicine bottle 23, and as shown in FIG. 11, the moving time to the pouring position of the liquid agent C and the liquid agent G two adjacent to the liquid agent A is taken. Is 6 seconds, and similarly, the movement time from the liquid agent A to the injection position of the liquid agent E farthest in the rotation direction is 12 seconds.

FIG. 12 is an example of a table showing the liquid agent 5 that requires stirring. Of the eight types of liquid agents A to H mounted on the liquid agent supply device 1, the liquid agent B and the liquid agent E are stirring necessary liquid agents that need to be agitated before being supplied to the medication bottle 2. In the present embodiment, the liquid agent that requires stirring is a liquid agent that becomes inhomogeneous due to sedimentation or the like when left to stand for a long time. Examples of the liquid agent requiring stirring include suspensions and emulsions. On the other hand, the liquid agents A, C, D and F to H are stirring-free liquid agents that do not require stirring before being supplied to the dosing bottle 2. A liquid agent that does not require stirring is a liquid agent that can maintain a homogeneous state even when left to stand for a long time.

As shown in FIG. 12, the required stirring time of the liquid agent B and the liquid agent E is set to 10 seconds, and based on this required stirring time, the rotation time of the stirring motor 62 in the forward direction (5 seconds). And the rotation time (5 seconds) in the opposite direction are determined. In FIG. 12, the required stirring times of the liquid agents B and E requiring stirring are the same, and the required stirring time is fixed, but the required stirring time may be different for each type of the liquid agent 5.

FIG. 13 is an example of a prescription table showing the types of the liquid preparation 5 supplied to the medication bottle 2. In this example, according to a doctor's prescription, three kinds of liquid preparations 5 for the patient to take are mixed and supplied to the medication bottle 2. The prescription table stores data on the type of liquid medicine and the amount of liquid medicine dispensed. In the case of this example, 20 ml of liquid agent B, 30 ml of liquid agent C, and 40 ml of liquid agent G are supplied. As described above, each data related to the prescription table may be input to the control unit 90 using the touch panel 14, or may be input to the control unit 90 from an external computer via the communication unit 92. ..

FIG. 14 is a flowchart of a liquid agent supply process from the liquid agent bottle 23 to the medication bottle 2 using the liquid agent supply device 1 according to the present embodiment. As shown in FIG. 14, in the liquid agent supply process of the present implementation, the order of pouring the liquid agent 5 is first determined in step S100, and then the actual pouring is performed in step S200. In the present specification, a continuous order in which each of the liquid agents 5 contained in the plurality of liquid agent bottles 23 is continuously and sequentially supplied from the liquid agent bottle 23 to the medication bottle 2 is referred to as a supply order. In this supply order, the order in which each liquid agent 5 is supplied is referred to as a supply order.

FIG. 15 is a flowchart showing the details of step S100 for determining the order shown in FIG. The supply order of the plurality of liquid agents 5 and the supply order of each liquid agent 5 are determined according to the steps described below. First, in step S110, the number of chemicals to be poured into the medication bottle 2 is acquired. At this time, the control unit 90 recognizes that three types of liquid agents, liquid agent B, liquid agent C, and liquid agent G, are poured out with reference to the prescription table shown in FIG.

Subsequently, in step S120, the current position of the liquid medicine bottle 23 at the stage when the number of injected chemicals is acquired is acquired. At this time, the control unit 90 refers to the table shown in FIG. 11 in which the current position of the liquid agent bottle 23 is recorded based on the detection result of the bottle position detecting means 91, and the liquid agent currently in the pouring position is the liquid agent A. And recognizes the current position of the liquid medicine bottle 23 containing the three kinds of liquid medicines B, C, and G to be dispensed. Subsequently, in step S130, the control unit 90 calculates the movement time to the pouring position of each liquid agent bottle 23 based on the current position of the liquid agent bottle 23 acquired in step S120. In the case of this example, since the liquid agent A is in the pouring position, as shown in FIG. 11, the movement time to the pouring position of the liquid agent B is 3 seconds, and the movement to the pouring position of the liquid agent C is The time is 6 seconds, and the travel time to the pouring position of the liquid agent G is 6 seconds.

Subsequently, in step S140, the stirring time of the liquid agent 5 is calculated. The control unit 90 compares the prescription table shown in FIG. 13 with the table of the liquid agent requiring stirring shown in FIG. 12, and the water agent B dispensed in the present dispensing treatment is the water requiring stirring. It is calculated that it is an agent and that the required stirring time is 10 seconds.

Subsequently, in step S150, the pouring time of each liquid agent is calculated. The control unit 90 recognizes the injection amount of each of the three types of liquid agents B, C, and G with reference to the prescription table of FIG. 13, and injects the liquid agent 5 per unit time by the pump drive motor 40. The injection time of each of the liquid agents B, C, and G is calculated based on the output amount. In the case of this example, the pump drive motor 40 has a specification that can transfer 10 ml of the liquid agent 5 per second, and the injection time is proportional to the injection amount of the liquid agent 5. In this case, the pouring time of the liquid agent B is 2 seconds, the pouring time of the liquid agent C is 3 seconds, and the pouring time of the liquid agent G is 4 seconds.

Subsequently, in step S160, the total supply time (hereinafter referred to as TOTAL pouring time) required for supplying the three types of liquid agents B, C, and G to all the medication bottles 2 is calculated.

FIG. 16 is a flowchart showing the details of step S160 for calculating the TOTAL pouring time. A method of calculating the TOTAL injection time will be described in detail with reference to FIG. First, in step S161, the variable i is set to 1, and the variable total is set to 0.

Here, the variable i indicates a number assigned to the liquid medicine to be poured, and can take an integer value of 1 or more. For example, according to the prescription table shown in FIG. 13, provisional numbering is performed so that the liquid agent B is No. 1, the liquid agent C is No. 2, and the liquid agent G is No. 3. The variable total indicates time.

Note that the variable i does not indicate the supply order when the actual pouring is done in step S200. As will be described later, in order to determine the supply order when the actual injection is performed, the TOTAL injection time for all possible supply orders is calculated, and then the optimum supply order (that is, the optimum supply order) is calculated. , The supply order with the shortest TOTAL pouring time) is selected. In FIG. 13, liquid agent B is numbered 1, liquid agent C is numbered 2, and liquid agent G is numbered 3, for example, these are numbered according to the order in which the doctor wrote the prescription. For example, it is just the order in which the data was entered. When determining the TOTAL pouring time, liquid agents B, C and G are numbered arbitrarily from 1 to 3 and a total of 6 combinations of pouring orders are tried. Similarly, for example, if two types of liquids are listed on the prescription table, a total of two combinations of dispensing orders will be attempted, and if, for example, four types of liquids are listed on the prescription table. A total of 24 combinations of pouring orders will be attempted.

Returning to FIG. 16, in step S162, the stirring time and the moving time of the liquid agent B, which is the first chemical, are compared. Since the variable total is 0 at this point, only the stirring time and the moving time of the liquid agent B need to be compared. In the case of this example, as shown in FIG. 12, the required stirring time of the liquid agent B is 10 seconds, and as shown in FIG. 11, the moving time for moving the liquid agent B to the pouring position is 3 seconds. The time is longer. That is, the stirring of the liquid agent B is not completed while the liquid agent B is moved from the current position to the pouring position, the stirring time of the liquid agent B becomes rate-determining, and the variable total is controlled by the stirring time of the liquid agent B. .. Therefore, the process proceeds to step S163, and the sum (10 seconds + 2 seconds = 12 seconds) of the stirring time and the pouring time of the liquid agent B is set as the variable total.

Since the time required for pouring out the first liquid agent B was calculated in step S163, the process proceeds to step S165, and 1 is added to the variable i. That is, the pouring time for the second liquid agent C will be examined next. In the next step S166, in order to determine whether the pouring time for all the prescription drugs has been calculated, it is determined whether the variable i exceeds the number of prescription drugs. In this example, the variable i at this point is 2, the number of prescription drugs is 3, and the variable i is equal to or less than the number of prescription drugs, so the process returns to step S162.

In the second step S162, the stirring time of the liquid agent C, which is the second chemical, and the sum of the current variable total and the moving time of the liquid agent C are compared. In the case of this example, since the liquid agent C is a liquid agent that does not require stirring, the stirring time is 0. That is, the sum of the current variable total and the moving time of the liquid agent C is longer than the stirring time of the liquid agent C. Therefore, the sum of the current variable total and the travel time of the liquid agent C becomes the rate-determining factor, and the sum of the current variable total and the travel time of the liquid agent C dominates the new variable total. Therefore, the process proceeds to step S164, and the sum of the current variable total, the moving time of the liquid agent C, and the pouring time of the liquid agent C is set as a new variable total.

FIG. 17 is a table showing the current position of the liquid agent bottle 23 when the liquid agent B is in the pouring position. As a result of the rotary drum 21 rotating and moving from the position of the table shown in FIG. 11 and the position of the liquid agent bottle 23 changing, the liquid agent B is currently in the pouring position. Therefore, the movement time required to move the second liquid agent C to the pouring position is 3 seconds as shown in FIG. Therefore, the movement time and the pouring time (3 seconds + 3 seconds = 6 seconds) of the liquid agent C are added to the current variable total (12 seconds), and the new variable total becomes 18 seconds. As a result, the time required to dispense the second liquid agent C has been calculated.

Subsequently, in step S165, 1 is added to the variable i to set the variable i to 3. Subsequently, in step S166, the value of the variable i and the number of prescription drugs are compared, and since both the variable i and the number of prescription drugs are 3 and the variable i is equal to or less than the number of prescription drugs, the process returns to step S162 again.

In the third step S162, the stirring time of the liquid agent G, which is the third chemical, and the sum of the current variable total and the moving time of the liquid agent G are compared. In the case of this example, since the liquid agent G is a liquid agent that does not require stirring, the stirring time is 0. Therefore, the process proceeds to step S164, and the sum of the current variable total, the moving time of the liquid agent G, and the pouring time of the liquid agent G is set as a new variable total.

FIG. 18 is a table showing the current position of the liquid agent bottle 23 when the liquid agent C is in the pouring position. As a result of the rotary drum 21 rotating and moving from the position of the table shown in FIG. 17 and the position of the liquid agent bottle 23 changing, the liquid agent C is currently in the pouring position. Therefore, the moving time required to move the third liquid agent G to the pouring position is 12 seconds as shown in FIG. Therefore, the moving time and the pouring time (12 seconds + 4 seconds = 16 seconds) of the liquid agent C are added to the current variable total (18 seconds), and the new variable total becomes 34 seconds. As a result, the time required for pouring out the third liquid agent G has been calculated.

Subsequently, in step S165, 1 is added to the variable i, and the variable i is set to 4. Subsequently, in step S166, the value of the variable i is compared with the number of prescription drugs. At this point, the variable i is 4, the number of prescription drugs is 3, and the variable i exceeds the number of prescription drugs, so that the calculation of the TOTAL injection time is completed.

FIG. 19 is a timing chart showing the TOTAL injection time when the liquid agents B, C, and G are injected in this order. As described above, since the stirring time of the liquid agent B is longer than the moving time of the liquid agent B, the stirring and pouring of the liquid agent B, the movement and pouring of the liquid agent C, and the movement of the liquid agent G And by adding the time required for pouring, it is calculated that the TOTAL pouring time is 34 seconds when pouring the liquid agents B, C, and G in this order.

In the case of this example, since the number of medicines to be dispensed is 3, there are a total of 6 possible combinations of the order of pouring the liquid medicine 5 into the medication bottle 2 by changing the order of the liquid medicines B, C and G. Be done. The TOTAL pouring time is calculated in the same manner as above for all of these six pouring orders.

For example, the TOTAL injection time may be calculated when the liquid agents G, B, and C are then dispensed in this order. In this case, referring to FIG. 16 again, since the liquid agent G, which is the first chemical, does not need to be agitated before being supplied to the medication bottle 2, the time required for pouring out the liquid agent G is water. It is the sum of the moving time of the agent G and the pouring time (6 seconds + 4 seconds = 10 seconds).

The second chemical, liquid B, requires stirring for 10 seconds. Here, the stirring of the liquid agent B is performed between the moving time for moving the liquid agent G which does not require stirring to the pouring position and the pouring time for pouring out the liquid agent G. The liquid agent bottle 23 containing the liquid agent B rotates around the drum axis L1 while the liquid agent B is agitated.

The control unit 90 shown in FIG. 9 stirs the liquid agent while supplying the liquid agent G to the medication bottle 2 and while rotating the rotating drum 21 as the bottle position changing unit to change the position of the liquid agent bottle 23. The part is operated to stir the liquid agent B. The control unit 90 supplies each of the liquid agents 5 contained in the plurality of liquid agent bottles 23 from the liquid agent bottle 23 to the medication bottle 2 in the supply order in which the liquid agent B is supplied to the medication bottle 2. The liquid agent B is stirred until the liquid agent B is started, that is, until the rotary movement of the rotary drum 21 for moving the liquid agent bottle 23 containing the liquid agent B to the pouring position is started. The control unit 90 starts supplying the liquid agent B to the medication bottle 2 after the supply of the liquid agent G to the medication bottle 2 is completed, and the supply order of the liquid agent G is earlier than that of the liquid agent B. The liquid preparation B is agitated while supplying the medicine bottle 2.

In the second step S162, the stirring time of the liquid agent B and the sum of the current variable total and the moving time of the liquid agent B are compared. FIG. 20 is a table showing the current position of the liquid agent bottle 23 when the liquid agent G is in the pouring position. With reference to FIG. 20, the movement time required to move the second liquid agent B to the pouring position is 9 seconds as shown in FIG. The current variable total is the sum of the travel time and the pouring time of the first drug, the liquid agent G. That is, in the second step S162, the control unit 90 compares the first liquid agent supply time required for supplying the liquid agent G with the second liquid agent stirring time required for stirring the liquid agent B.

Here, the first liquid agent supply time is the supply of the liquid agent G from the liquid agent bottle 23 as the first bottle containing the liquid agent G which is the first liquid agent to be poured out to the medication bottle 2. It's the time it takes. The second liquid agent stirring time is the time required for stirring the liquid agent B, which is the second liquid agent to be poured out second. Further, the control unit 90 compares the subtotal time obtained by adding the first liquid agent supply time and the position change time required for changing the position of the liquid agent bottle 23 with the second liquid agent stirring time.

Comparing the stirring time of the liquid agent B (10 seconds) and the sum of the current variable total and the moving time of the liquid agent B (10 seconds + 9 seconds = 19 seconds), the latter is larger. Therefore, the process proceeds to step S164, and the moving time and the pouring time (9 seconds + 2 seconds = 11 seconds) of the liquid agent B are added to the current variable total (10 seconds), and the new variable total becomes 21 seconds. As a result, the time required to dispense the second liquid agent B has been calculated.

Since the third chemical, liquid agent C, does not require stirring, in step S164, the sum of the current variable total, the moving time of liquid agent C, and the pouring time of liquid agent C is newly added. Variable total. With reference to FIG. 17, the movement time required to move the third liquid agent C to the pouring position is 3 seconds. Therefore, the movement time and the pouring time (3 seconds + 3 seconds = 6 seconds) of the liquid agent C are added to the current variable total (21 seconds), and the new variable total becomes 27 seconds. As a result, the time required for pouring out the third liquid agent G has been calculated.

FIG. 21 is a timing chart showing the TOTAL injection time when the liquid agents G, B, and C are injected in this order. As described above, the sum of the moving time and pouring time of the first liquid agent G and the moving time of the second liquid agent B is longer than the stirring time of the liquid agent B. Therefore, by adding the time required for the movement and injection of the liquid agent G, the movement and injection of the liquid agent B, and the movement and injection of the liquid agent C, the liquid agents G, B, and C are injected in this order. The TOTAL pouring time for the case is calculated to be 27 seconds.

FIG. 22 is a timing chart showing the TOTAL injection time when the liquid agents G, C, and B are injected in this order. Liquid B, which requires agitation, is poured out third. Since the stirring of the liquid agent B is started at the same time as the movement of the first liquid agent G is started, the stirring of the liquid agent B has already been completed by the time the pouring of the second liquid agent C is completed. The control unit 90 starts supplying the liquid agent B to the dosing bottle 2 after a while after the stirring of the liquid agent B is completed. Therefore, by adding the time required for the movement and injection of the liquid agent G, the movement and injection of the liquid agent C, and the movement and injection of the liquid agent B, the liquid agents G, C, and B are injected in this order. The TOTAL pouring time for the case is calculated to be 30 seconds.

Similarly, the TOTAL pouring time when pouring in the order of liquid agents B, G, C, the order of liquid agents C, B, G, and the order of liquid agents C, G, B is calculated. That is, six TOTAL injection times, which are all combinations of sequentially injecting the three types of liquid agents B, C, and G, are calculated.

Returning to FIG. 15, next, in step S170, the order of dispensing when actually pouring the liquid preparation 5 into the dosing bottle 2 based on the calculation results of the above six TOTAL pouring times decide. Specifically, among the six TOTAL pouring times, the order in which the TOTAL pouring time is the shortest is selected, and the order is set so that each of the liquid agents 5 contained in the plurality of liquid agent bottles 23 is liquid. The order of supply from the bottle 23 to the medication bottle 2 is determined. In this way, the supply order for supplying each of the liquid agents 5 (that is, the liquid agents B, C, and G) to the medication bottle 2 is determined, and step S100 shown in FIG. 14 is completed.

By minimizing the amount of rotation of the rotating drum 21, the time required to move the liquid agent bottle 23 to the pouring position can be minimized. The control unit 90 supplies the plurality of types of liquids 5 contained in the plurality of liquids 23 to the dosing bottle 2 so that the supply order of the liquids requiring stirring is later than the supply order of the liquids not requiring stirring. Set the supply order. As a result, it is possible to shorten the time required for stirring the liquid agent required for stirring, which affects the TOTAL pouring time. Therefore, it is possible to shorten the time required to inject all of the plurality of types of liquid preparations.

Subsequently, the liquid agent 5 is supplied to the dosing bottle 2 from each of the plurality of liquid agent bottles 23 containing the liquid agent 5. FIG. 23 is a flowchart showing the details of step S200 for pouring out the liquid agent 5 shown in FIG. With reference to FIG. 23, first, in step S210, it is determined whether or not the plurality of liquid agents 5 supplied to the dosing bottle 2 contain chemicals that require stirring. If there is a liquid agent required for stirring, the process proceeds to step S220, the stirring operation flag is set, and then the process proceeds to step S230. If there is no chemical that requires stirring, step S220 is skipped and the process directly proceeds to step S230.

FIG. 24 is a flowchart showing a subroutine for stirring the liquid agent 5. The subroutine shown in FIG. 24 is started at the same time as the activation of the liquid agent supply device 1 and is always executed. As shown in step S221, whether or not the stirring operation flag is set is constantly monitored, and while the stirring operation flag is not set, the standby state is waiting for an instruction.

When the stirring operation flag is set in step S220 shown in FIG. 23, it is determined that the stirring operation flag is set in step S221, and the process proceeds to step S222. In step S222, the control unit 90 rotates the liquid agent bottle 23 by driving the motor 62 for stirring the liquid agent 5. By rotating the liquid agent bottle 23 in both forward and reverse directions, turbulence is generated in the liquid agent bottle 23, whereby the liquid agent 5 in the liquid agent bottle 23 is agitated. Stirring is continued until it is determined in step S223 that the stirring is complete. The determination of the completion of stirring is performed, for example, by detecting with a timer whether or not the driving time of the motor 62 exceeds a predetermined time.

When the stirring operation flag is set in step S220, the determination in step S221 becomes YES, and the process proceeds to step S222 to start stirring. When one prescription contains a plurality of liquid agents 5 that require stirring, the stirring operation flags of the plurality of liquid agents 5 are set at the same time, and the stirring of the plurality of liquid agents 5 is started all at once.

When it is determined that the stirring is completed, the motor 62 is stopped, and then the process proceeds to step S224, and the stirring operation flag is cleared. The subroutine of FIG. 24 is then returned and returns to the standby state again.

The subroutine shown in FIG. 24 may be always executed at the same time as the device is started as described above, but the subroutine start flag may be set after the supply order of the liquid agent 5 is determined. In this case, a plurality of necessary types are required. The subroutine may be terminated after all of the liquid agent 5 of No. 5 has been supplied to the medication bottle 2.

Returning to FIG. 23, in step S230, it is determined whether or not it is the order of dispensing the chemicals that require stirring. If it is the order of supplying the liquids required for stirring, then in step S240, it is determined whether the stirring operation flag is cleared. That is, when it is the order of supplying the liquid agents required for stirring, the liquid agent 5 has already been stirred according to the subroutine shown in FIG. 24, and as a result, it is determined whether or not the stirring operation flag is cleared in step S224. .. If the stirring operation flag is not cleared, the stirring has not been completed yet, so the process waits until the stirring is completed and the stirring operation flag is cleared. If it is determined that the stirring operation flag is cleared, the process proceeds to step S250.

If the order of supplying the stirring-free liquids that does not require stirring is that the liquids 5 can be poured out regardless of the stirring operation flag, the process directly proceeds from step S230 to step S250. Subsequently, in step S250, the liquid agent bottle 23 containing the liquid agent 5 to be injected is moved to the injection position, and then the liquid agent 5 is dispensed from the liquid agent bottle 23 to the dosing bottle 2.

Here, as soon as the stirring operation flag is set in step S220, stirring is started in step S222. Further, if the liquid agent 5 first supplied to the medication bottle 2 after the stirring operation flag is set in step S220 is a stirring-free liquid agent that does not require stirring before being supplied to the medication bottle 2, it is immediately step S250. The movement of the liquid medicine bottle 23 is started at. While the rotary drum 21 changes the position of the liquid agent bottle 23, the control unit 90 operates the rotary drive unit 61 constituting the liquid agent stirring unit to agitate the liquid agent 5 in the liquid agent bottle 23.

Subsequently, the process proceeds to step S260, and it is determined whether or not all the target liquid agents 5 described in the prescription have been supplied to the medication bottle 2, and if not, the process returns to step S230. If all the liquid agents 5 have been poured out, the supply of the liquid agent 5 to the dosing bottle 2 is completed, and step S200 shown in FIG. 14 is completed.

As described above, in the liquid agent supply device 1 of the present embodiment, the liquid agent 5 that needs to be agitated before being supplied to the medication bottle 2 is used while supplying the other liquid agent 5 to the medication bottle 2. / Alternatively, it is agitated while changing the position of the liquid medicine bottle 23. By superimposing the stirring time of the liquid agent required for stirring on the pouring time and / or moving time of the other liquid agent 5, the time for only stirring can be shortened, and typically the time for only stirring can be eliminated. it can. Therefore, the pouring time of the liquid agent 5 can be shortened.

The supply order of supplying the plurality of types of liquid agents 5 contained in the plurality of liquid agent bottles 23 to the medication bottle 2 is such that the supply order of the liquid agent B which is the water agent which requires stirring is the liquid agent which does not require stirring. It may be set so as to be later than the supply order of G. Alternatively, the supply order is set in advance, such as being set according to the order in which the doctor wrote the prescription, and the control unit 90 does not have to change the supply order. Even if the supply order is preset and the liquid agent B that requires stirring is set in the first supply order, as shown in FIG. 19, the stirring time and the moving time of the liquid agent B are overlapped. Therefore, the time for only stirring the liquid agent B can be shortened. Therefore, the pouring time of the liquid agent 5 can be shortened.

(Embodiment 2)
FIG. 25 is a timing chart showing the TOTAL pouring time of the second embodiment. In the second embodiment, an example in which the liquid preparation 5 is supplied to the dosing bottle 2 according to a prescription for supplying 50 ml each of the five kinds of liquid preparations P, Q, R, S and T will be described. The pouring times of the liquid agents P, Q, R, S and T are all equal to 5 seconds. At this time, the liquid medicine bottles 23 containing the five kinds of liquid medicines P, Q, R, S and T are arranged side by side on the liquid medicine bottle holder 32, and therefore, each liquid medicine bottle is arranged. It is assumed that the moving time to the pouring position of 23 is 3 seconds.

Of the five types of liquid agents P, Q, R, S and T, only the liquid agent T is a water agent that requires stirring before being supplied to the medication bottle 2, and the other liquid agents P, Q , R and S are all agitation-free aqueous agents that do not require agitation before being supplied to the medication bottle 2.

As described with reference to FIG. 23, since the stirring operation flag is set when the supply of the liquid agent 5 to the dosing bottle 2 is started, as shown in FIG. 25, the stirring of the liquid agent T is performed at the same time as the movement of the liquid agent P is started. Has been started. The liquid agent T is stirred for 10 seconds and then the stirring is stopped. Further, the liquid agent T is stopped for a predetermined time (10 seconds in this example), and then stirred again for 10 seconds.

In this way, if the liquid agent T, which is the liquid agent required to be agitated, is repeatedly stirred before being supplied to the medication bottle 2, the liquid agent T is in the supply order, that is, the liquid agent bottle 23 containing the liquid agent T. The liquid agent T can be agitated at a time zone closer to the time when the movement to the pouring position is started. Therefore, since the sedimentation of the suspended component contained in the liquid agent T to the bottom of the liquid agent bottle 23 can be more reliably suppressed, the liquid agent T in a more uniform state can be supplied to the dosing bottle 2.

(Embodiment 3)
FIG. 26 is a timing chart showing the TOTAL pouring time of the third embodiment. The third embodiment is an example in which the five kinds of liquid preparations P, Q, R, S and T similar to the above-mentioned second embodiment are supplied to the medication bottle 2. In the third embodiment, as shown in FIG. 26, the stirring of the liquid agent T is continuously performed from the start of movement of the liquid agent P to the end of the pouring of the liquid agent S, that is, until the supply order of the liquid agent T is reached. Can be continued.

According to the dispensing treatment shown in the third embodiment, as in the second embodiment, the liquid agent T can be agitated at a time zone closer to the time when the supply to the medication bottle 2 is started, and the suspended component water contained in the aqueous agent T can be agitated. Since the sedimentation to the bottom of the agent bottle 23 can be more reliably suppressed, the liquid agent T in a more uniform state can be supplied to the medication bottle 2.

(Embodiment 4)
FIG. 27 is a timing chart showing the TOTAL pouring time of the fourth embodiment. In the fourth embodiment, two types of liquid agents B and H arranged according to the table shown in FIG. 11 are supplied, and the injection amount of the liquid agent B is 20 ml and the injection amount of the liquid agent H is 50 ml. An example of supplying the liquid preparation 5 to the dosing bottle 2 will be described accordingly. The pouring time of the liquid agent B is 2 seconds, and the pouring time of the liquid agent H is 5 seconds. As shown in FIG. 12, it is assumed that the liquid agent B is a water agent requiring stirring and the liquid agent H is a water agent requiring stirring. Further, as shown in FIG. 27, it is assumed that the prescription for supplying the liquid preparations B and H is performed three times in succession.

In this case, the liquid agent B, which needs to be agitated before being supplied to the dosing bottle 2, may be agitated only in the first of three consecutive formulations. Shortly after the liquid agent B is agitated in the first prescription, the liquid agent B is dispensed according to the second and third prescriptions. In the second and third prescriptions, it is considered that time has not passed since the liquid agent B was agitated in the first prescription, and the liquid agent B has already been agitated. In the first formulation, the liquid agent B is a liquid agent that does not require stirring, but in the second and third formulations, the liquid agent B can be treated as a liquid agent that does not require stirring. Therefore, in the second and third prescriptions, it is not necessary to re-stir the liquid agent B, and the required time can be shortened by the stirring time of the liquid agent B.

In this way, the TOTAL injection time of the liquid preparations B and H in the second and third prescriptions can be shortened. In the second and third prescriptions, the control unit 90 starts supplying the liquid agent B to the dosing bottle 2 after a while after the stirring of the liquid agent B is completed. Such a dispensing treatment is particularly effective for shortening the TOTAL pouring time when all the liquid preparations contained in the prescription are liquid preparations that require stirring.

(Embodiment 5)
FIG. 28 is a timing chart showing the TOTAL pouring time of the fifth embodiment. The fifth embodiment is an example in which the three types of liquid agents B, C and G similar to the first embodiment described above are supplied to the dosing bottle 2. Depending on the type of liquid agent required for stirring, the liquid agent 5 can be kept uniform for a long time (for example, 10 hours or more) after stirring. In the case of such a liquid agent, if it is stirred only once a day, for example, only when the liquid agent supply device 1 is started during the day, stirring is not necessary at the time of actual subsequent pouring. In the fifth embodiment, it is assumed that the liquid agent B is a kind of liquid agent that can maintain sufficient uniformity by stirring once a day.

Therefore, as shown in FIG. 28, by stirring the liquid agent B in advance, the liquid agent B is treated as a stirring-free liquid agent that does not require stirring before being supplied to the dosing bottle 2 at the time of actual pouring. Therefore, the time required for TOTAL can be shortened by the amount of the stirring time of the liquid agent B. The control unit 90 starts supplying the liquid agent B to the dosing bottle 2 after a while after the stirring of the liquid agent B is completed. In this way, the TOTAL pouring time can be significantly shortened when the liquid agents B, C and G are dispensed in the order as compared with FIG.

In the previous embodiments, in a configuration in which the liquid agent bottle 23 can be moved in the liquid agent supply device 1, TOTAL injection is performed in consideration of the movement time for moving the liquid agent bottle 23 to the injection position. The time was calculated. In the configuration in which the liquid agent bottle 23 does not move in the liquid agent supply device 1, the TOTAL pouring time may be calculated without considering the movement time of the liquid agent bottle 23. That is, the TOTAL pouring time may be calculated by appropriately adding the pouring time and the stirring time of the plurality of liquid agents 5.

Although the embodiments of the present invention have been described above, the configurations of the embodiments may be combined as appropriate. In addition, the embodiments disclosed this time should be considered to be exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include the meaning equivalent to the scope of claims and all modifications within the scope.

1 liquid medicine supply device, 2 medication bottle, 3 liquid medicine supply unit, 5 liquid medicine, 14 touch panel, 17 output unit, 17a, 17b printer, 21 rotary drum, 22 drum rotation motor, 23 liquid medicine bottle, 32 liquid medicine Bottle holder, 39 mobile motor, 40 pump drive motor, 45 electronic balance, 50 elevating device, 61 rotary drive unit, 62 motor, 90 control unit, 91 bottle position detection means, 92 communication unit, 93 memory, 94 records Media access section.

Claims (1)

A liquid agent supply unit that supplies the liquid agent from the liquid agent bottle containing the liquid agent to the medication bottle, and
A bottle position changing unit that moves the liquid medicine bottle to a pouring position where the liquid medicine contained in the liquid medicine bottle is supplied to the medication bottle,
It is provided with a liquid agent stirring unit that agitates the liquid agent in the liquid agent bottle so as to be in a homogeneous state.
The liquid agent stirring unit stirs the liquid agent while the bottle position changing unit moves the liquid agent bottle, and the bottle position changing unit moves the liquid agent bottle to the pouring position. With the liquid agent bottle in the pouring position, the liquid agent is continuously stirred until the stirring of the liquid agent is completed .
The liquid agent supply unit is a liquid agent supply device that supplies the liquid agent from the liquid agent bottle to the medication bottle after stirring the liquid agent by the liquid agent stirring unit.

Images