JP7328511B2 - Assembly equipment - Google Patents

Description

The present invention relates to an assembling apparatus, and more particularly to an assembling apparatus for assembling an assembly composed of a plurality of parts.

Conventionally, as an assembling apparatus for assembling an assembly composed of a plurality of parts, there is known one in which another part (cap) is attached to a part (container) conveyed by conveying means (Patent Document 1). ).
The assembling apparatus of Patent Document 1 has a capper for attaching the cap to the container as the assembling means, and the capper has a holding head (capping head) for holding the cap and attaching it to the container. .
On the other hand, in such an assembling apparatus, in order to assemble a plurality of types of assemblies composed of different parts, there is known one in which the holding head is replaceable. When assembling an assembly constituted by the above, a so-called model change operation is carried out, such as exchanging the parts constituting the assembly and exchanging the holding head of the assembling means.

JP-A-05-051087

However, the mold change operation is complicated. For example, when replacing the holding head of the assembling means, an operator takes the new holding head to the assembling means and replaces it with the existing holding head. I needed work to do.
In view of such problems, the present invention provides an assembling apparatus capable of more efficiently performing mold changing work.

That is, the assembling apparatus according to the invention of claim 1 assembles an assembly composed of a plurality of parts into supply means for supplying the parts, conveying means for conveying the parts, and the parts conveyed by the conveying means. An assembling device for assembling using an assembling means for mounting other parts,
The assembling means has a configuration capable of mounting either a first holding head holding the parts constituting the first assembly or a second holding head holding the parts constituting the second assembly. ,
The conveying means includes a first carrier that stores the parts that make up the first assembly, a second carrier that stores the parts that make up the second assembly, the first holding head, and a second carrier. 2 a head carrier that houses the holding head,
After the assembling means assembles the first assembly accommodated in the first carrier , when changing the mold for assembling the second assembly accommodated in the second carrier , the second The head carrier accommodating the holding head moves to the assembly means, the first holding head attached to the assembly means is disconnected from the assembly means, is accommodated in the head carrier , and is accommodated in the head carrier. A second holding head is mounted on the assembly means.

According to the above invention, there is no need to provide a connecting portion between the supply means and the assembly means in the isolator, and the structure of the assembly means in the isolator can be simplified. As a result, it is possible to reduce the probability of an abnormality occurring inside the isolator. In addition, since the head carrier is provided, the first holding head and the second holding head in the assembly means can be exchanged at the time of the mold change, so that the mold change operation can be simplified. Become . Therefore , the operator can use the glove from the outside of the isolator to perform recovery work and mold change work when an abnormality occurs or when the mold is changed.
In other words, since it is not necessary to decontaminate the isolator again after these operations, the apparatus can be restarted immediately after the completion of these operations, enabling efficient production.

Plan view of filling line according to the present embodiment Front view showing the holder of the carrier and the parts housed in the holder Side view of carrier and rails Plan view for explaining container supply means The side view explaining a container supply means Diagram for explaining the operation in the filling and capping section Top view of carrier stocker Side view of head carrier

Referring now to the illustrated embodiments, FIG. 1 shows a filling line 2 for filling eye drops into an eye drop container 1 as an assembly and for capping.
As shown in FIG. 2, the eye drop container 1 is composed of a plurality of parts, including a container part 1a as a main part for containing a drug, and a mouth part of the container part 1a, which is attached to the mouth of the container part 1a to drop the drug solution one drop at a time. It is composed of an inner plug 1b as an attachment part for dripping, and a cap 1c as an attachment part attached to the mouth.
The container portion 1a has a substantially trapezoidal shape with the upper base longer than the lower base when viewed from the front as shown in FIG. 2, and has a substantially rectangular shape with a predetermined thickness when viewed from the side as shown in FIG. . A cylindrical opening is formed in the center of the upper portion of the container portion 1a so as to face upward.
The inner plug 1b is made of resin and has a substantially columnar shape, and the inner plug 1b can be attached to the container portion 1a by pressing the inner plug 1b into the mouth portion from above. It's becoming
The cap 1c has a substantially trapezoidal shape in which the upper base is shorter than the lower base when viewed from the front, and has a substantially rectangular shape with a predetermined thickness when viewed from the side as shown in FIG.
An engaging portion that engages with the outer peripheral portion of the mouth portion of the container portion 1a is formed inside the cap 1c. In other words, the cap 1c does not need to be rotated with respect to the opening when the cap 1c is attached.
When the cap 1c is attached to the container portion 1a, the upper base portion of the container portion 1a and the lower base portion of the cap 1c are brought into close contact with each other, so that the eye drop container 1 having a substantially hexagonal shape when viewed from the side is obtained. (See Fig. 6).
The eye drop container 1 having the above structure is conventionally known, and detailed description of the structures of the inner plug 1b and the cap 1c is omitted.

The filling line 2 includes a parts supply section A that supplies parts constituting the eye drop container 1, and two filling and capping sections B1 that fill the container portion 1a with medicine and attach the inner plug 1b and the cap 1c. , B2, a discharge section C for discharging the eyedropper container 1 with the cap 1c attached, the parts and the eyedropper container 1 so as to circulate through the parts supply section A, the filling and capping sections B1 and B2, and the discharge section C. are provided, and these are controlled by control means (not shown).
In this embodiment, the parts supply section A is housed in a parts supply isolator 4 whose interior is kept sterile, and the two filling and capping sections B1 and B2 are also filled and capped with their interiors kept sterile. Housed in plug isolator 5 .
The discharge section C and a part of the conveying means 3 other than the parts supply section A and the filling and plugging sections B1 and B2 are accommodated in a clean booth 6 whose interior is kept cleaner than the exterior.
In this embodiment, the component supply isolator 4 and the clean booth 6 are provided adjacent to each other, while the filling and plugging isolator 5 is provided inside the clean booth 6 .
At the connection position between the parts supply isolator 4 and the clean booth 6, there is formed a communication port 4a through which the parts and the like conveyed by the conveying means 3 can pass. Communicating port 5a through which the like can pass is formed.

The two filling and plugging isolators 5 are provided inside the clean booth 6, and one side of the filling and plugging isolator 5 is integrally formed with the side of the clean booth 6, and the side is exposed to the outside.
The exposed side surface is made of a transparent acrylic plate, and the acrylic plate is provided with a glove (not shown) that can be worn by the operator. Therefore, the worker can work inside the filling and plugging isolator 5 from the outside using gloves.

The parts supply isolator 4 and the filling and plugging isolator 5 are each provided with sterile air supply means (not shown) for supplying sterile air to the inside, and the inside is set to a required positive pressure. The inside of the clean booth 6 is also set to a required positive pressure.
The internal pressures of the parts supply isolator 4 and the filling and plugging isolator 5 are set to be more positive than the internal pressure of the clean booth 6, and the dust generated in the clean booth 6 is removed from the parts supply isolator 4 and the filling and plugging isolator 4. Intrusion into the isolator 5 is prevented.

The conveying means 3 includes a rail 11 forming an endless conveying track, and a plurality of carriers 12 linearly driven along the rail 11. The control means controls the position of each carrier 12. and movement speed can be controlled individually.
The rail 11 includes a component supply section 11A having a substantially C shape provided inside the component supply isolator 4, a transfer section 11B having a substantially U shape provided inside the clean booth 6, and the and a filling and plugging section 11</b>C provided inside the filling and plugging isolator 5 .
Of these sections, the parts supply section 11A and the conveying section 11B form a circular circulation path, while the filling and plugging section 11C is provided so as to branch off from the conveying section 11B.
In this manner, although the component supply section 11A and the filling and plugging section 11C are provided at separated positions, the carrier 12 moves in the conveying section 11B while moving between the component supply section 11A and the filling and plugging section 11C. It is adapted to cyclically move between sections 11C.
Further, both ends of the parts supply section 11A and both ends of the conveying section 11B are slightly separated from each other, and both ends of the filling and plugging section 11C are also slightly separated from the conveying section 11B. . However, for these spaced apart parts, the carrier 12 can be transferred by connecting rails 13 provided between them.

As shown in FIGS. 2 and 3, the carrier 12 includes a holder 14 that accommodates the component, a plate-like base member 15 that supports the holder 14, and a columnar member 16 provided on the lower surface of the base member 15. , a shuttle 17 provided substantially in the center of the columnar member 16 and having a permanent magnet 17a provided therein, and two sets of rollers 18 provided above and below the shuttle 17 .
Concave portions 14a are formed on the upper surface of the holder 14 in conformity with the shapes of the components, and these concave portions 14a are provided with the container portion 1a as the main component and the above-described container portion 1a as the component in order from the end on the upstream side in the conveying direction. It accommodates the inner plug 1b and the cap 1c.
Of the recessed portions 14a of the holder 14, the recessed portions 14a for accommodating the container portion 1a and the cap 1c are formed so that the direction of the accommodated container portion 1a and the cap 1c is the same.
Further, as shown in FIG. 3, two holders 14 are provided in parallel on the upper surface of the base member 15 so that one carrier 12 can carry two sets of components.
As shown in FIG. 2(b), instead of the concave portion 14a, the holder 14 is provided with a protrusion 14b and a hook 14c that are fitted with the cap 1c and the bottom portion of the container portion 1a, so as to position them. can be

As shown in FIG. 3, the rail 11 includes an electromagnetic coil 19 provided on the side of the shuttle 17 and guides 20 provided above and below the electromagnetic coil 19 and in contact with the rollers 18 of the carrier 12 . It has
When the roller 18 of the carrier 12 abuts against the guide 20 of the rail 11, a certain gap is formed between the electromagnetic coil 19 and the shuttle 17. In this state, magnetic force is generated from the electromagnetic coil 19. , the carrier 12 can be linearly driven.
The conveying means 3 for moving the carrier 12 by linear driving is conventionally known, and further detailed description of the linear driving will be omitted.

The rails 11 indicated by solid lines in FIG. The connection rail 13 is indicated by a dashed line on the opposite side of the carrier 12 .
The connection rail 13 is also provided with the electromagnetic coil 19 and the guide 20 in the same manner as the rail 11 constituting the component supply section 11A and the transport section 11B. It is possible to move the carrier 12 along the connection rail 13 .
With such a configuration, when the carrier 12 is positioned between the rail 11 of the component supply section 11A and the connection rail 13, the control means demagnetizes the electromagnetic coil 19 of the rail 11 of the component supply section 11A, while the connection By activating the electromagnetic coil 19 of the rail 13, the carrier 12 can be transferred from the component supply section 11A to the connection rail 13.
On the other hand, after that, when the carrier 12 that has moved on the connection rail 13 is positioned between the rail 11 of the transfer section 11B, the control means demagnetizes the electromagnetic coil 19 of the connection rail 13, By activating the coil 19, the carrier 12 can be transferred from the connecting rail 13 to the transport section 11B.

When the carriers 12 are branched from the conveying section 11B to the filling and plugging section 11C, an arbitrary carrier 12 is branched to the filling and plugging section 11C by the connection rail 13, and the other carriers 12 remain in the conveying section. 11B can be moved to pass through the filling and plugging section 11C.
That is, when the carrier 12 is branched from the conveying section 11B to the filling and capping section 11C, the control means activates the electromagnetic coil 19 of the connecting rail 13 when the carrier 12 approaches the connecting rail 13. Then, the carrier 12 is transferred to the filling and plugging section 11C.
On the other hand, when the carrier 12 is to pass through the filling and capping section 11C, the control means does not operate the electromagnetic coil 19 of the connection rail 13, but continues to operate the electromagnetic coil 19 of the rail 11 of the conveying section 11B. Just do it.

The component supply section A is composed of cap supply means 21, inner plug supply means 22, and container supply means 23 as supply means provided along the component supply section 11A of the transport means 3. As shown in FIG. It should be noted that the order of these supply means does not have to be as described.
Hereinafter, the container supply means 23 will be described with reference to FIGS. 4 and 5, but since the cap supply means 21 and the inner plug supply means 22 have the same configuration, detailed description thereof will be omitted. shall be omitted.
The container supply means 23 includes a hopper 24 for supplying the container portion 1a, a conveyor 25 for conveying the container portion 1a, a camera 26 for photographing the container portion 1a on the conveyor 25, and the container portion 1a on the conveyor 25. It is composed of a robot 27 that holds the container 27 and transfer means 28 that receives the container 1a from the robot 27 and stores it in the carrier 12 .
Of these, the conveyor 25, the camera 26, the robot 27, and the transfer means 28, excluding the hopper 24, are arranged on the upstream and downstream sides of the transport direction of the carrier 12 by the transport means 3 with the hopper 24 as the center, as shown in FIG. It is provided symmetrically towards the Note that FIG. 4 mainly shows the configuration on the downstream side in the moving direction of the carrier 12 .

The conveying means 3 is adapted to stop 12 carriers 12 with respect to the container supply means 23. Specifically, 6 carriers 12 are stopped at each of the two transfer means 28. It has become.
The hopper 24 accommodates the pre-sterilized container portion 1a, and discharges the container portion 1a onto the conveyor 25 provided below the discharge port of the hopper 24. As shown in FIG.
Since the discharged container portions 1a on the conveyor 25 are oriented in random directions, they are photographed by the camera 26, and the control means recognizes the position and orientation of each container portion 1a from the photographed image. It has become.

The robot 27 is composed of an arm portion 27a and a suction head 27b provided at the tip of the arm portion 27a. The suction head 27b is connected to negative pressure generating means (not shown).
When the position and orientation of the eye drop container 1 on the conveyor 25 are recognized, the control means controls the robot 27 according to the position and orientation of the container portion 1a to move the suction head 27b, thereby A required portion of the portion 1a is held by suction.
In this embodiment, the suction head 27b can suck and hold, for example, two container portions 1a. The distance between the recesses 14a formed in each holder 14 is the same as that of the recesses 14a.
Then, the robot 27 moves the suction head 27b sideways while elevating the sucked container portion 1a, and moves the upright container portion 1a to the transfer position adjacent to the transfer means 28. As shown in FIG.

The delivery means 28 is composed of a suction head 28a for sucking and holding the container portion 1a, and a moving means 29 for moving the suction head 28a horizontally and vertically.
The suction head 28a is capable of sucking and holding six container portions 1a. is set to the same interval as the distance of
For this reason, the suction head 28a is kept waiting at the transfer position, and during that time the robot 27 moves the suction head 27b a plurality of times to transfer the six container portions 1a to the suction head 28a. there is

As shown in FIG. 4, the moving means 29 includes two X-direction rails 29a provided perpendicular to the rails 11 of the conveying means 3 and movable in the X-direction along the X-direction rails 29a. and a Z-direction rail 29c provided vertically with respect to the Y-direction member 29b. The suction head 28a is provided so as to be vertically movable by the Z-direction rail 29c.
As described above, since the suction head 28a sucks and holds the six container portions 1a at the delivery position, the suction head 28a is then moved in a direction orthogonal to the rails 11, and the suction head 28a is moved. It is possible to accommodate the container portion 1a in the concave portions 14a of the holders 14 of the six carriers 12 simply by moving them up and down.
In other words, since the suction head 27b of the robot 27 and the suction head 28a of the transfer means 28 transfer the container portion 1a in the same direction as the concave portion 14a formed in the holder 14 of the carrier 12, the transfer means 28 can be accommodated in the recess 14a without changing the orientation of the container portion 1a.

In addition, a camera 32 as missing part recognition means for photographing the carrier 12 in which parts are accommodated in the parts supply section A is provided at a position adjacent to the upstream side of the filling and plugging sections B1 and B2 in the conveying means 3. is provided.
The image photographed by the camera 32 is image-recognized by the control means, and the presence/absence of the component accommodated in the holder 14 of the carrier 12 is determined.
As a result of the determination, if one of the two holders 14 provided in the carrier 12 is found to be missing a component, the control means controls the carrier 12 having the missing component to perform filling and plugging sections B1 and B2. , and the conveying section 11B is moved as it is.
Subsequently, the control means causes the carrier 12 with the missing part to pass through the discharge part C, and moves it to the component supply part A again, and supplies the carrier 12 with the missing part together with the other carrier 12 with the cap supply. The means 21, the inner plug supply means 22, and the container supply means 23 are sequentially stopped.
At this time, the control means controls these supply means so that only the missing part is supplied to the carrier 12 having the missing part, without supplying the already accommodated part.
In this manner, even if a component supply error occurs in the component supply unit A, the carrier 12 having the missing component is circulated and moved to the component supply unit A again, thereby preventing the component supply error. It is possible to replenish missing parts without rejecting the parts accommodated in a certain carrier 12.例文帳に追加

The filling and plugging sections B1 and B2 are housed in the filling and plugging isolator 5, respectively. , a filling means 42 , an inner plugging means 43 and a capper 44 .
The air cleaner 41, the filling means 42, the inner plugging means 43, and the capper 44 are provided at a position close to the wall surface of the filling and plugging isolator 5, and when the operator wears the gloves, these It is possible to perform a required operation on the processing means.
As a result, it is possible for the worker to perform restoration work for recovering from the abnormality that occurred in the filling and capping sections B1 and B2 without entering the filling and capping isolator 5. Since the sterilization work inside 5 is unnecessary, it is possible to improve the production efficiency of the filling line 2 as a whole.
The air cleaner 41 has an injection nozzle for injecting sterile air above the carrier 12 moved by the conveying means 3, and injects air from above the parts accommodated in the carrier 12 to remove dust adhering to the parts. etc. are removed.

6A and 6B are diagrams for explaining the operations of the filling means 42, the plugging means 43 and the capper 44. The carrier 12 moves from right to left in the drawing, and the carrier 12 moves from the right to the left. A container portion 1a, an inner plug 1b, and a cap 1c are accommodated in this order from the upstream side (right side in the drawing).
The filling means 42 includes a filling nozzle 42a connected to drug supply means (not shown) provided outside the filling and plugging isolator 5, and an elevating means (not shown) for vertically moving the filling nozzle 42a.
The inner plug capping means 43 includes an inner plug gripper 43a as a holding head for holding the inner plug 1b, and an elevating means (not shown) for vertically raising and lowering the inner plug gripper 43a.
Similarly, the capper 44 includes a capping head 44a as a holding head for holding the cap 1c, and an elevating means (not shown) for vertically elevating the capping head 44a.
In this embodiment, the carrier 12 is provided with two holders 14, and the components are conveyed in two rows. are provided two each at intervals of .

6, the eye drop container 1 is assembled by filling the container portion 1a with the drug and attaching the inner plug 1b and the cap 1c by means of the filling means 42, the inner stopper capping means 43, and the capper 44. Explain the procedure.
FIG. 6(a) shows the operation of filling the container portion 1a with the drug by the filling means 42. As shown in FIG. The control means positions the carrier 12 below the filling means 42 and stops it so that the mouth of the container portion 1a is positioned below the filling nozzle 42a.
Then, the filling nozzle 42a is lowered by the elevating means, and a predetermined amount of the drug is discharged from the lowered filling nozzle 42a to fill the container portion 1a with the drug.

FIG. 6(b) shows the operation of taking out the inner plug 1b from the carrier 12 by the inner plug plugging means 43. As shown in FIG. The control means positions the carrier 12 below the inner plug capping means 43 and stops it so that the inner plug 1b is positioned below the inner plug gripper 43a.
Then, the inner plug gripper 43a is lowered by the elevating means, and the lowered inner plug gripper 43a holds the inner plug 1b.

FIG. 6(c) shows the operation of plugging the container portion 1a with the inner plug 1b by the inner plug capping means 43. As shown in FIG. The inner plug capping means 43 once raises the inner plug gripper 43a by the elevating means, and in this state, the carrier 12 moves downstream from the state shown in FIG. Stop below the inner plug gripper 43a.
Then, the inner plug gripper 43a is lowered by the elevating means, the sucked and held inner plug 1b is fitted into the opening of the container portion 1a, and the inner plug 1b is completely capped by a predetermined pressing force. , the container portion 1a.

FIG. 6(d) shows the operation of removing the cap 1c from the carrier 12 by the capper 44. FIG. The control means stops the carrier 12 below the capper 44 and the cap 1c below the capping head 44a.
Then, the capping head 44a is lowered by the elevating means, and the lowered capping head 44a grips the cap 1c.

FIG. 6(e) shows the operation of attaching the cap 1c to the container portion 1a by the capper 44. As shown in FIG. The control means moves the carrier 12 downstream from the state of FIG. 6(d), and stops the opening of the container portion 1a so as to be positioned below the capping head 44a.
Then, the capping head 44a is lowered by the elevating means, and the held cap 1c is fitted to the opening of the container portion 1a, and the cap 1c is attached to the container portion 1a, whereby the eye drop container 1 is assembled. becomes.

In this manner, the filling means 42, the inner plugging means 43, and the capper 44 of the filling line 2 of this embodiment vertically move the filling nozzle 42a, the inner plug gripper 43a, and the capping head 44a, respectively, by the elevating means. It is composed of mechanisms.
With such a configuration, the carrier 12 simply positions the corresponding parts and the container portion 1a below the filling nozzle 42a, the inner plug gripper 43a, and the capping head 44a to fill the medicine, take out the parts, and remove the container portion 1a. It is possible to attach to
In other words, there is no need for a mechanism for moving these holding heads in the horizontal direction, and there is no need to accommodate a complicated mechanism such as a robot in the filling and plugging isolator 5 .
By simplifying the configuration of the filling and plugging sections B1 and B2 in this way, it is possible to reduce the probability of an abnormality occurring in the filling and plugging sections B1 and B2, and even if an abnormality occurs, , which can be easily restored.
At this time, since the above-mentioned abnormality can be recovered from the outside by a glove provided on the filling and capping isolator 5, the recovery work can be performed while maintaining the sterile environment, and the inside of the filling and capping isolator 5 can be removed after recovery. You can save the trouble of dyeing.

Further, in this embodiment, the holder 14 of the carrier 12 accommodates the container portion 1a as the main component on the upstream side in the conveying direction, and the attached parts such as the inner plug 1b and the cap 1c on the downstream side. It has become.
By doing so, it is possible to attach the inner plug 1b and the cap 1c to the container portion 1a simply by moving the carrier 12 downstream.
Conversely, if the inner plug 1b and the cap 1c are accommodated upstream of the container portion 1a, for example, in the inner plug capping means 43, after the inner plug gripper 43a holds the inner plug 1b, the carrier 12 is conveyed. Unless it is reversed in the direction upstream, the container portion 1a cannot be moved below the inner plug gripper 43a, and the movement of the carrier 12 becomes complicated and inefficient.

The discharge section C includes a belt conveyor 45 having one end provided inside the clean booth 6 and the other end provided outside the clean booth 6, and the eye drop container 1 housed in the carrier 12 through the belt conveyor 45. and a transfer means 46 for moving upward.
As the transfer means 46, a conventionally known robot or, for example, a device composed of a holding head capable of holding the eye drop container 1 and a moving means for moving the holding head can be used.
At this time also, the carrier 12 can be stopped at a desired position with respect to the transfer means 46 by the control means, so that the eye drop container 1 can be transferred by the transfer means 46 having a simple structure. .

The operation of the filling line 2 having the above configuration will be described below.
The insides of the parts supply isolator 4 and the filling and plugging isolator 5 are sterilized in advance, and a predetermined number of carriers 12 are prepared in the conveying means 3 in advance.
First, the control means moves 12 carriers 12 at a time to the parts supply section A, and moves them to the inner cap supply means 22 and the container supply means 23 in order from the cap supply means 21 located on the upstream side.
During this time, the cap supply means 21, the inner plug supply means 22, and the container supply means 23 accommodate the cap 1c, the inner plug 1b, and the container portion 1a in the holder 14 of the carrier 12 by the robot 27 and transfer means 28, respectively. Thus, the container portion 1a, the inner plug 1b, and the cap 1c are accommodated in the holder 14 in this order from the upstream side in the conveying direction.

When the components are supplied to the carrier 12 in this way, the control means moves the carrier 12 from the component supply isolator 4 to the adjacent clean booth 6. photograph the parts of
The control means recognizes the missing part of the parts housed in the carrier 12 from the photographed image, and when the missing part is recognized, the carrier 12 with the missing part moves the filling and plugging sections B1 and B2. Make a decision to let it pass.
The carrier 12 with the missing part passes through the filling and plugging sections B1 and B2 and the discharging section C, and the carrier 12 moves to the parts supply section A again, and the missing part is replenished. It is designed to be

The carrier 12 recognized as containing all the parts by the missing component recognition means alternately moves to either one of the two filling and plugging sections B1 and B2.
In addition, for example, it is possible to move the carrier 12 only to one filling and plugging section B1 and not to move the carrier 12 to the other filling and plugging section B2.
In this case, it is possible to change the type of the eyedropper container 1 to be processed and work efficiency in the other filling and capping section B2 while the medicine is being filled in the filling and capping section B1. It is possible to perform arbitrarily according to.

When the carrier 12 containing the components enters the filling and plugging isolator 5 and moves to the filling and plugging sections B1 and B2, the air cleaner 41 first injects air to the components contained in the carrier 12. , remove dust, etc.
6, the filling nozzle 42a of the filling means 42, the inner stopper gripper 43a of the inner stopper capping means 43, and the capping head 44a of the capper 44 move up and down to move the container portion 1a. Then, the filling of the drug, the plugging of the inner plug 1b, and the mounting of the cap 1c are performed.
At this time, the carrier 12 is stopped below the filling nozzle 42a, the inner plug gripper 43a, and the capping head 44a by linear transportation, so that only by moving these holding heads up and down, the medicine can be filled into the container portion 1a and the capping head 44a. , the inner plug 1b and the cap 1c can be held and attached to the container portion 1a.

When the filling of the drug and the attachment of the inner plug 1b and the cap 1c are completed in this manner, the carrier 12 moves from the filling and plugging isolator 5 into the clean booth 6 and then to the discharge section C. As shown in FIG.
In the discharge section C, the transfer means 46 takes out the eye dropper container 1 from the carrier 12 and places it on the belt conveyor 45, after which the eye dropper container 1 is conveyed by the belt conveyor 45 to the downstream process. It's like
Then, the carrier 12 from which the eyedropper container 1 has been taken out is moved again to the component supply isolator 4 along the circulation path of the transport means 3, and the above-described operations are repeated.

As described above, according to the filling line 2 of this embodiment, even if the eye drop container 1 has a shape that makes it difficult to convey in an upright state, the parts constituting the eye drop container 1 can be placed in the holder 14 for exclusive use. Since it is transported in a state where it is housed in a container, it is possible to perform drug filling and component mounting (assembly) in a stable state.
Further, since the inner plug supply means 22 and the cap supply means 21 as supply means for supplying parts are provided separately from the inner plug capping means 43 and the capper 44 as assembly means, respectively, these supply means There is no need for a mechanism for feeding the parts from the assembly to the assembly means.
As such a mechanism, for example, a shooter for supplying the cap to the holding head is conceivable, but this shooter requires replacement and adjustment according to the shape of the parts, and has a complicated structure.
By eliminating the need for such a mechanism, it is possible to simplify the configuration of the assembly means provided inside the filling and plugging isolator 5 .
Therefore, it is possible to quickly recover from an abnormality that has occurred in the assembling means, and it is possible to simplify the work at the time of mold change, so that work efficiency is improved.
Furthermore, the assembling means is provided in the filling and capping isolator 5 whose inside is maintained in a sterile state. Restoration work and mold change work can be performed from the outside, eliminating the need for decontamination work after these work.

Next, the filling line 2 of this embodiment has a structure for efficiently changing the type of the eye drop container 1 to a different type.
In FIG. 1, a carrier stocker 51 containing a plurality of carriers 12 is provided at a position adjacent to the clean booth 6 so as to be able to move toward and away from the carrier stocker 51 itself. is possible.
The carrier 12 stored in the carrier stocker 51 has substantially the same configuration as the carrier 12 shown in FIGS. It is formed in a shape capable of accommodating a part having a shape different from that of the eye drop container 1 shown.
The conveying means 3 has a carrier stocker section 11D that branches toward the carrier stocker 51. Although the end of the carrier stocker section 11D is separated from the rail 11 of the conveying section 11B, the connecting rail It is possible to branch a required carrier 12 on the same principle as 13.

The inside of the carrier stocker 51 is maintained in a sealed state from the outside, and the inside thereof can be decontaminated by decontamination means (not shown). can be decontaminated.
Further, a connection passage 52 is provided between the carrier stocker 51 and the clean booth 6 to allow communication between the inner space of the carrier stocker 51 and the clean booth 6 without contaminating the cleanliness of the clean booth 6. .
For example, the cleanliness is maintained by connecting the carrier stocker 51 to the connection passage 52 with the opening of the connection passage 52 on the clean booth 6 side closed, and decontaminating the inside of the connection passage 52 in that state. It is possible to communicate with these as they are.

FIG. 7 is a plan view showing the inside of the carrier stocker 51. Inside the carrier stocker 51, an entrance rail 53 connected to the carrier stocker section 11D of the conveying means 3 and a plurality of carriers 12 are held. and a plurality of moving rails 54 provided movably in the horizontal direction.
When the carrier stocker 51 is connected to the connection passage 52 , the entrance rail 53 is connected at its end to the rail 11 of the carrier stocker section 11</b>D provided in the connection passage 52 .
The entrance rail 53 does not need to move the carrier 12 by linear driving, and has a structure for moving the carrier 12 positioned at the entrance of the carrier stocker 51 toward the inside or outside of the carrier stocker 51 by means of a pusher or the like. there is
The moving rail 54 is horizontally moved by a driving means (not shown) to come into contact with and separate from the entrance rail 53. When the moving rail 54 and the entrance rail 53 are close to each other, the moving rail 54 and the entrance It is possible to move the carrier 12 between the rails 53 .
By moving the moving rails 54 horizontally, a plurality of moving rails 54 can be accommodated inside the carrier stocker 51, thereby allowing a predetermined number of carriers 12 to be accommodated. .

Further, the carrier stocker 51 of this embodiment also accommodates a head carrier 55 capable of accommodating a capping head 44a for holding the cap 1c that constitutes the eye drop container 1 after the model change.
FIG. 8 shows the head carrier 55, which has the same structure as the carrier 12 except for the holder 14 for accommodating the capping head 44a.
Like the carrier 12, the head carrier 55 is linearly driven along the rails 11, and its position is controlled by control means.
In this embodiment, since the same inner plug 1b can be used for the eye drop container 1 before changing the shape and the eye drop container 1 after changing the shape, a head carrier for the inner plug capping head 44a of the inner plug capping means 44 can be used. 55 is not provided, but if the inner plug 1b also needs to be changed, a head carrier 55 for the inner plug capping head 44a can be prepared.

The holder 14 includes an existing capping head 44aA as a first holding head currently attached to the capper 44, and a new capping head 44aA as a second holding head for holding the cap 1c of the eye drop container 1 after the model change. A plurality of recesses 14a are formed to accommodate the capping heads 44aB.
The capping heads 44aA and 44aB have a mechanism that can be connected to the elevating means of the capper 44. For example, when the elevating means raises and lowers the mounting member of the capper 44, conventionally known connecting means is used. It is possible to connect or disconnect the mounting member and the capping heads 44aA and 44aB.
Even if such a connection means is not provided, if the carrier stocker 51 moves the capping head 44aA to the capper 44, an operator wearing gloves can replace the capping heads 44aA and 44aB. It is possible to change the mold efficiently.

First, in the component supply unit A, new eye drop containers are placed in the hopper 24 by the container supply means 23, the inner plug supply means 22, and the capper 44 supply means. 1 is supplied with new parts.
At this time, the container supply means 23, the inner plug supply means 22, and the cap supply means 21 do not normally need to be changed because the robot 27 has versatility. However, when replacement is required, the operator enters the component supply isolator 4 to replace the suction head 27b and sterilize the inside of the component supply isolator 4 in advance.

Subsequently, the carrier stocker 51 is moved and connected to the connection passage 52 of the clean booth 6, so that the clean booth 6 and the carrier stocker 51 are communicated with each other.
The carrier stocker 51 moves the carrier 12 and the head carrier 55 accommodated therein to the carrier stocker section 11D of the transport means 3 while moving the moving rail 54 .
Then, the control means moves the new carrier 12 to the downstream side of the carrier stocker section 11D, and moves the existing carrier 12 used up to that point to the upstream side or the upstream side of the filling and plugging sections B1 and B2. , to the conveying section 11B provided in parallel with the filling and plugging sections B1 and B2.
In this state, the control means moves the head carrier 55 housing the new capping head 44aB for the eye drop container 1 after the model change in a direction opposite to the normal conveying direction, and moves them to the filling and capping section. It is moved to the filling and plugging section 11C provided with B1 and B2.

Subsequently, the control means moves the head carrier 55 below the capper 44 to position the empty recess 14a in the holder 14 below the existing capping head 44aA.
Then, the capper 44 lowers the existing capping head 44aA by the elevating means, and then cancels the connection state, so that the existing capping head 44aA is housed in the concave portion 14a of the holder 14. FIG.
Next, the control means moves the head carrier 55 to move the new capping head 44aB accommodated in the holder 14 below the connected member of the elevating means.
Then, the capper 44 moves the member to be connected close to the new capping head 44aB by the elevating means, and then the capping head 44aB and the member to be connected are connected to complete the model change of the capper 44. FIG.

When the replacement of the capping heads 44aA and 44aB in the capper 44 is completed in this manner, the control means moves the head carrier 55 containing the existing capping head 44aA to the carrier stocker 51. FIG.
At the same time, the control means moves the waiting existing carrier 12 to the carrier stocker 51, whereby the existing carrier 12 and the capping head 44aA are accommodated in the carrier stocker 51, and the mold change is performed. complete.
After that, the operator removes the carrier stocker 51 from the clean booth 6 and injects decontamination gas into the carrier stocker 51, thereby decontaminating the carrier 12 and the capping head 44a inside.

By storing the carrier 12 for changing the type in the carrier stocker 51 in this way, it is possible to efficiently exchange the carrier 12 necessary for changing the type to the eye drop container 1 composed of parts having different shapes. becomes.
In addition, since the carrier stocker 51 accommodates the head carrier 55 capable of accommodating the capping heads 44aA and 44aB for assembling a new eye drop container 1, the head carrier 55 can be moved to the filling and capping sections B1 and B2. It is also possible to efficiently replace the capping heads 44aA and 44aB.
Note that the carrier stocker 51 can be branched from any location on the conveying means 3. For example, the carrier stocker section 11D may be connected to the component supply section 11A. The carrier stocker 51 is connected to .

In this embodiment, as an assembling apparatus, the filling line 1 for assembling the eye drop container 1 by attaching the inner plug 1b and the cap 1c to the container portion 1a has been described as an example, but the filling line 1 can also be used as an assembling apparatus for assembling other articles. be able to.

1 eye drop container (article) 1a container part (main component)
1b Inner plug (mounting part) 1c Cap (mounting part)
2 Filling Line (Assembly Device) 3 Conveying Means 4 Part Supplying Isolator 5 Filling and Plugging Isolator 6 Clean Booth 11 Rail 12 Carrier 21 Cap Supplying Means 22 Inside Plug Supplying Means 23 Container Supplying Means 42 Filling Means 42a Filling Nozzle 43 Inside Plugging Means (assembly means) 43a Inner plug gripper (holding head)
44 capper (assembly means)
44a capping head (holding head)
51 carrier stocker 55 head carrier

Claims (3)

An assembly composed of a plurality of parts is produced by using supply means for supplying the parts, conveying means for conveying the parts, and assembling means for mounting other parts on the parts conveyed by the conveying means. An assembling device for assembling,
The assembling means has a configuration capable of mounting either a first holding head holding the parts constituting the first assembly or a second holding head holding the parts constituting the second assembly. ,
The conveying means includes a first carrier that stores the parts that make up the first assembly, a second carrier that stores the parts that make up the second assembly, the first holding head, and a second carrier. 2 a head carrier that houses the holding head,
After the assembling means assembles the first assembly accommodated in the first carrier , when changing the mold for assembling the second assembly accommodated in the second carrier , the second The head carrier accommodating the holding head moves to the assembly means, the first holding head attached to the assembly means is disconnected from the assembly means, is accommodated in the head carrier , and is accommodated in the head carrier. and a second holding head mounted on the assembly means. connecting a carrier stocker capable of accommodating the head carrier to the transporting means;
2. The assembly apparatus according to claim 1, wherein said head carrier is accommodated in said carrier stocker while said assembly is being assembled by said assembly means. While assembling the first assembly by the assembling means, the second carrier is housed in the carrier stocker, and when the mold is changed, the second carrier is moved to the outside of the carrier stocker, 3. The assembling apparatus according to claim 2, wherein said first carrier is accommodated in said carrier stocker.

Images