Very many products are assembled of injection-moulded plastic components of different kinds. Each kind of component is injection-moulded by means of a special mould mounted in an injection-moulding machine. The finished components are normally collected in a casing. The same machine is also often used to injection-mould the other components or some of them.

The casings with the components are then transported to a station for separating the components from their sprues and thereafter to an assembling station where the components are manually and/or by means of robots assembled to the finished product.

The handling and assembling of the components in this way is however, very labour-intensive and costly and moreover the production capacity is relatively low.

When a larger capacity is desired, one or more injection- moulding machine is used for each component. The production rates of these machines are preferably the same thereby ensuring that the different components can be both separated from their sprues and arrive at an assembling station at the same time. Thereby is it possible to successively assemble the components in the same sequence as they arrive at the assembling station.

The production capacity is, however, limited by the possible production rate at the separation station and assembling station. This production rate is relatively low, since the different components arrive to the stations in an unarranged orientation and therefore first need to be correctly orientated. The separation and assembling of the components is therefore also relatively labour-intensive and costly in this case.

In one aspect according to the invention is provided a method of the type mentioned in the opening paragraph for in an easy and an expedient way transporting and/or assembling inject- moulded plastic components by means of the sprue originally connected to the components.

In another aspect according to the invention is provided a plant of the type mentioned in the opening paragraph, which is less labour-intensive and costly than known hitherto.

In third aspect according to the invention is provided a plant of the type mentioned in the opening paragraph, which has a higher production rate than known hitherto.

In a forth aspect according to the invention is provided a plant of the type mentioned in the opening paragraph, which has a simple, cheap and effective conveying system for conveying the components of the products through the plant.

In a fifth aspect according to the invention is provided a plant of the type mentioned in the opening paragraph having a conveying system which automatically orientates the components in the correct way during the production process.

In a sixth aspect according to the invention is provided a plant and a method of the type mentioned in the opening

paragraph having a conveying system used in the separating and assembling operations.

In a seventh aspect according to the invention is provided a method of the type mentioned in the opening paragraph to, in a simple, cheap and effective way, assemble injection-moulded plastic components of different kinds into finished products at a higher rate than known hitherto.

The method according to the invention comprises that the components are injection-moulded in such a way, that at least two components get a common sprue for each inject-moulding operation and that said sprues are used for transporting and/or assembling the components.

The sprues are conventionally disconnected from the components immediately after each injection-moulding operation, whereby the components need to be orientated before at least the assembling operation. This orientation process is labour- intensive and costly. This problem is, however, advantageously remedied by according to the invention using the sprues for transporting and assembling the components manually or by means of robots.

The plant according to the invention comprises a conveying system for conveying the sprues, still connected with the components, formed during the injection-moulding process, from the injection-moulding machines to the assembling station in such a way that the sprues arrive to this station in a predetermined orientated state.

The mould for injection-moulding a component is normally equipped with channels for injecting the hot and plasticized plastic into the cavity formed in the mould for moulding the component as a cast of the cavity, thereby at the same time also moulding the sprues as a cast of said channels.

For obtaining a large production rate and an economic production, the mould will normally be designed to mould multiple components simultaneously, whereby these components get a common sprue.

As is clear from the above-mentioned explanation the sprues are necessary for injection-moulding the components. But in a conventional plant they are labour-intensive and costly to handle in the subsequent production where they are normally separated from the components in a production step immediately after the moulding operation.

In contrast, the sprues, in the plant according to the invention, are utilized in the production process for carrying the components from the injection-moulding machines to the assembling station in a predetermined orientated state, allowing the components to be securely, easily and quickly assembled, resulting in a high production rate with less effort and cost than in conventional processes.

A feeding robot can be placed at each injection-moulding machine for catching the sprues, when being ejected from the injection-moulding machine, and carrying them at least part of the way to the assembling station. In addition at least one assembling robot can be placed at the assembling station for receiving and assembling the components. The orientation of the components, which arrive at the assembling station, is therefore advantageously predetermined already from the beginning of the process.

The conveying system can, when only a smaller production capacity is required, be arranged in such a way that the assembling station receives the sprues, connected with the components, directly from the feeding robots. The plant according to this embodiment is very simple and cheap.

When a larger production capacity is required, the conveying system can be comprised of at least one conveyer extending between the feeding robots and the, at least one, assembling robot. The feeding robots feed the conveyer during production with sprues, connected with the components, which at the end of the conveyer are handed over to the assembling robot.

The conveyer can, in a preferred embodiment, comprise one or more rails, each having a longitudinal groove for accommodating at least one part of each of the sprues. The conveyer can moreover have means in the form of pneumatic cylinders or air jets for slidably displacing said suspension parts in the longitudinal grooves. Said part of each of the sprues is in this case formed as a suspension part, which the feeding robots insert in the longitudinal groove, during the production.

For ensuring that the sprues with the components arrive at the assembling station in the desired orientation the suspension parts and the grooves can be formed in such a way that the suspension parts cannot turn or only turn a little in the grooves around an axis extending in the longitudinal direction of the actual rail. The components will therefore always be kept in the same or nearly the same orientated position in planes extending perpendicular to the rails.

In an advantageous embodiment, where the suspension parts are securely guided in this way in the grooves, the cross section of each groove of the rails can have the shape of a cross and the suspension part of the sprues has a corresponding cross shape.

The component will also be kept in the same or nearly the same orientated position in planes extending in the longitudinal direction of the rails when each sprue has more than one

suspension part, whereby the sprues are prevented from turning around axes extending perpendicular to said planes.

When each sprue is formed with only two suspension parts interconnected with a cross bar it is advantageously obtained that the sprues are allowed to pass curves on the rails without bending the cross bar, which often consists of stiff plastic.

The conveying system can, for obtaining a very large production capacity, have one or more main rails, each of which is connected with one or more branch rails each being fed by a feeding robot with sprues interconnected with components. The main rails are then supplied with said sprues from their associated branch rails, whereby the different components are conveyed to the assembling station by means of each of their main rails in positions orientated in such a way that the components quickly and easily can be assembled to the desired product.

The invention will be explained in greater detail below where further advantageous properties and example embodiments are described with reference to the drawings, in which Fig. 1 is a flow chart for an embodiment of the plant according to the invention for producing products assembled of injection-moulded plastic components, Fig. 2 shows in a larger scale, seen in perspective, a part of the conveying system of the plant with a number of rails, Fig. 3 shows a section taken along the line III-III in fig. 2, Fig. 4 shows a fragment of the same in a longitudinal section, seen from the side,

Fig. 5 shows a section of another embodiment of a rail to the conveying system, Fig. 6 shows a fragment of the same in a longitudinal section, seen from above, Fig. 7 shows, seen in perspective, a fragment of the rail shown in fig. 3 and 4 formed with an in-feed for the components, Fig. 8 shows an assembling station for assembling the component to a finished product, Fig. 9 shows a product produced by means of the plant, and Fig. 10 is a flow chart for another embodiment of the plant according to the invention for producing products assembled of injection-moulded plastic components.

The plant shown in fig. 1 is in this case used for producing a product assembled of three different injection-moulded components. The product and the components are shown here only as signatures.

The plant comprises a first, a second and a third production line 1,2 and 3, an assembling station 4 and a conveying system 5 consisting of a first conveyer part la of the first production line 1, a second conveyer part 2a of the second production line 2, and a third conveyer part 3a of the third production line 3.

The first conveyer part la consists, in this case, of a first main rail lb, which is connected with two first branch rails lc'and lc'', the second conveyer part 2a consists of a second main rail 2b, which is connected with two second branch rails 2c'and 2c''and the third conveyer part 3a consists of a

third main rail 3b, which is connected with two third branch rails 3c'and 3c''.

The first production line 1 comprises two first injection- moulding machines Id'and ld''for injection-moulding a first kind of injection-moulded plastic component le, the second production line 2 comprises two second injection-moulding machines 2d'and 2d''for injection-moulding a second kind of injection-moulded plastic component 2e, and the third production line 3 comprises two third injection-moulding machines 3d'and 3d''for injection-moulding a third kind of injection-moulded plastic component 3c.

The first production line 1 further comprises two first feeding robots If'and f'for placing the sprues with components le injection-moulded by the two first injection- moulding machines 1d'and 1d"on the two first branch rails lc'and lc'', the second production line 2 comprises two second feeding robots 2f'and 2f''for placing the sprues with the components 2e injection-moulded by the two second injection-moulding machines 2d'and 2d''on the two second branch rails 2c'and 2c'', and the third production line 3 comprises two third feeding robots 3f and 3f'for placing the sprues with the components 3e injection-moulded by the two third injection-moulding machines 3d'and 3d''on the two third branch rails 3c'and 3c''.

Means (not shown in fig. 1) serve to push the sprues with the components in the direction of the arrows along the branch rails to the main rails and further along them in the direction of the arrows to a separating and assembling station 4.

The assembling station 4 comprises two assembling robots 4' and 4''for first assembling the first and second components le and 2e on the second main rail 2b and then assembling the

already assembled components le, 2e on the second main rail 2b with the third component 3e on the third main rail 3b to the finished product le, 2e, 3e, which in the direction of the arrow is carried to a packing station and/or a storage (not shown).

Fig. 2 shows in perspective and in a larger scale the first conveyer part la with the first main rail 1b connected with the two branch rails lc'and lc''by means of connections lg' and lg''guiding the sprues with the components le from the branch rails lc'and lc''into the main rail 1b along curves lh'and lh''merging with the main rail la.

The sprues with the components le are, during the production, pushed in the direction of the arrows along the branch rails lc', lc'' to the main rail la via the curved connections by means of pneumatic cylinders 5 and along the main rail la towards the assembling station.

Fig. 3 and 4 show, in a first embodiment, e. g. the main rail 1b with injection-moulded components le, which are still connected to the sprue 6, which is injection-moulded together with the components.

The sprue has two suspension parts 7 connected with a cross bar 8. Each of the components le is connected with the cross bar 8 by means of a tenon 9.

Each suspension part is formed with a cross 10, which is inserted into a correspondingly shaped longitudinal groove 11 in the rail lb. Each suspension part is furthermore formed with a spacing piece 12 for keeping the sprues with their components at a predetermined mutual distance from each other when being pushed along the rail. A rib 13, which is formed on the rail, serves for hanging up the rail to e. g. the ceiling of the building in which the plant is situated.

Due to the cross shape of the groove and the suspensions parts and also to the fact that the sprue has two suspension parts placed at a mutual distance from each other, the sprue and thereby the components are prevented from tilting in any direction in relation to the rail. The components will therefore advantageously arrive at the assembling station in an already orientated state, whereby it is possible to securely, quickly and easily assemble the components.

Fig. 5 and 6 shows e. g. the main rail 1b in a second embodiment. An air tube 14 is formed at the side of the rail.

This air tube is connected with a supply of pressurized air (not shown). The suspension parts 7 of the sprue 6 with the components le is guided in the longitudinal groove 11 formed in the rail. In the wall 15 between the air tube and the groove a number of air nozzles 16 are formed for, in a direction forming an acute angle with the conveying direction shown by the arrow, sending air jets 17 against the components during operation of the plant, thereby blowing the suspension parts along the rail.

Fig. 7 shows a fragment of e. g. the first branch rail lc'. The first feeding robot If'seizes, during production, the sprue 6 with the components le in synchronization with the production rate of the first injection-moulding machine ld'and inserts the suspension parts 7 in the longitudinal grove of the rail.

This operation is safely and accurately made by means of an in-feed 18 formed like a funnel.

Fig. 8 shows the separation and assembling station 4 for the plant according to the invention. It is, by way of example, assumed that the product produced by means of the plant is a regulator 19 to the infusion set described in the applicant's patent application SE 0300137-7.

This regulator 19 is shown in fig. 9 and is assembled of three injection-moulded components, namely a housing 20, a floater 21 and a cap 22 with a spike 23.

The sprues with these components are pushed forward on the main rails lb, 2b, 3b, the floater 21 on the main rail lb, the housing 20 on the main rail 22 and the cap 23 on the main rail 3b. The rails are in this case placed above each other but could also be placed side by side.

The sprues and thereby the components are, as previously mentioned, correctly orientated when arriving at the assembling station thereby allowing the robots 4'and 4''to securely, easily and quickly assemble the components. The components are separated from their sprues by means of e. g. shears (not shown).

The assembly operation takes place in the following way.

The assembling robot 4'seizes the floaters 21, which are now separated from their sprues on the first main rail lb, and places them inside the housings 20, while these are still connected with their sprues on the second main rail 2b.

The assembling robot 4''then seizes the assembly 24 of the housings 20 and the floaters 21, which are now separated from the sprues of the housings on the second main branch 2b, and assembles this assembly 24 with the caps 23 on the third main rail 3b.

The assembled regulators 19, which are still connected with the sprues of the caps on the third main rail 3b, are on this main rail then transported to a packing station and/or a storage station (not shown), where the regulators are separated from the sprues and packed into packaging for being supplied to the consumers, e. g. hospitals.

By means of this embodiment of the plant according to the invention a very high output can be obtained.

As an example, the output of a plant for producing products composed of 3 parts, having three production lines each fed by 9 injection-moulding machines is about 11.000 finished products per hour.

In a variant of the above-described plant there is only one production line, which alternatingly is fed with components from two or more injection-moulding machines. The assembling station then is arranged for assembling the components arriving to the assembling station in this way. This plant is suitable for productions where a very high output is not required.

Fig. 10 shows another embodiment for a plant according to the invention for producing a product assembled of two different injection-moulded components 25 and 26. Also in this case there is only one production line, which fundamentally corresponds to the production line 1 shown in fig. 1. The same reference numerals as in fig. 1-9 are used for the same parts.

The six components 25 and 26, are respectively, during the production, injection-moulded by means of the injection- moulding machines ld'and 1 d''. The components are in fig. 10 seen immediately after they have been ejected from said machines and are still interconnected with their sprues 27, which in this case are without suspension parts.

The feeding robots If'and If''catch hold of the sprues 27 and hand them over to the assembling robot 4', which assembles the two parts 25 and 26.

The two sprues 27 are, in this case, formed in such a way that the mutual distance between the six components 25 is the same as the mutual distance between the six components 26. The components 25 and 26 can therefore be assembled while still being interconnected with their sprues 27, thereby improving the speed of the process greatly and even further avoiding the troublesome process of having to orientate and assemble components that have already been separated from their sprues after the injection-moulding process.

A further robot 28 catches hold of the assembled components still interconnected with their sprues 27 and brings them to a separation and packing station (not shown).

From the above, it is obvious that keeping the components on the sprue is not only advantageous when using a conveyor system comprising of rails, but also advantageous when the sprues are transported by other means between the different stations, such as an assembly station and a packaging station.

As can be understood, it is essential to keep track of the orientation of the sprue, e. g. by robots or rails, whereby the sprues will be transported and assembled quickly and easily and at a much faster rate than if the components were separated from their sprue immediately after they were ejected from the injection-moulding machine.

In the above named description is with reference to the drawing described fully automatically operated embodiments according to the invention using the sprues for transporting and assembling the components.

The sprue can, however, within the scope of the invention also advantageously be used for manually transporting and assembling the components.