DE2265183A1 - Automatically operable component mounting appts. - inserts and clinches leads extending in radial or parallel relationship - Google Patents

Abstract

An electrical component mounting apparatus comprises a plurality of magazines for accommodating a stack of component substrates each carrying electrical components with the leads secured between a sheet and an adhesive tape. An ejecting mechanism ejects one of the component substrates from one of the magazines and the components are separated in succession from the substrate. They are then transported and mounted on a workpiece with the leads guided into corresponding holes in the workpiece. The ejecting mechanism may include rollers and a pair of parallel rods engaging a clutch block.

Description

Matsushita Electric Industrial Co., Ltd. 1006, Oaza Kadoma, Kadoma-shi- Osaka-fu, Japan

MOUNTING DEVICE

The invention relates to an assembly device for structural elements, in particular for the automatic successive loading of a workpiece with a number of components, each of which has at least one radially or parallel protruding pair of connecting wires.

The exemplary embodiment on which the description is based relates to a mounting device for attachment of disc capacitors; However, this does not represent a limitation of the invention, rather the is suitable Device for processing a wide variety of components, both electronic and others, especially those with inconsistent shapes.

A device known from US Pat. No. 2,850,737 for this

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Type refers to a mounting device for attaching disc-shaped electrical or electronic Components, which usually have radial connecting wires, on a chassis. Furthermore, from US-PS 2 916 165 a mechanism known that is in the frame the aforementioned device can be used and is suitable for feeding these disc-shaped components and to be controlled in such a way that they are aligned uniformly and then processed further precisely and appropriately can be.

In each known from the aforementioned US patents Devices are poured unsorted disc capacitors into a funnel and from there over a slide, which is adapted to the shape of the capacitors, fed to a component placement unit. Each of the correct aligned capacitors is from the broad side of the placement unit in the aligned state on a printed circuit board mounted and held in place by means of a pressure element.

However, these known devices could not be completely satisfactory when used in the production process, because they have the following disadvantages:

a) Since each of the conventional devices only for processing a very specific electrical component is suitable, a particular device must be made for each of the various components being processed and kept in stock, which not only increases production costs, but also significantly Load space claimed.

b) Since the electrical components are poured unsorted into a funnel, they are at risk of damage suspended when the hopper rotates; In addition, the connecting wires of the capacitors are completely

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are disordered and tend to jam when they are conveyed from the funnel to the printed circuit board will.

c) Since every electrical component is sucked from the funnel to the slide by means of a vacuum suction device it has been found that this suction device often fails, so that disturbances in the conveyance of the components occur.

d) The electrical components are stacked one behind the other within the slideway. With tolerances in the The external shape of the components can easily become blocked, which disrupts the production process.

e) Because the subsequent insertion and assembly process is very "is complicated, the device itself falls accordingly expensive to manufacture and maintain.

f) Every electrical component becomes in the course of its Insertion process into the circuit board of four guide pieces, which an additional space claim, so that the packing density of the components on the circuit board is disadvantageous for device reasons is restricted.

g) Since the device is only able to assemble the same components one after the other in the same orientation, it can not be used for a variety of electrical components with different dimensions and in different orientations on a predetermined portion "of a printed circuit board assemble.

The invention is based on the object of building a device of the type mentioned simply and cheaply and so on to train that, while avoiding the following

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automatically and reliably share from a number of different electrical components with lead wires selectively selects a desired / component, aligns with a printed circuit board to be assembled that Bringing connecting wires into a desired shape, introducing each electrical component into the printed circuit board and finally attached it by bending the protruding lead ends on the circuit board.

According to the invention, this object is achieved by a mounting device which is composed of a number of magazines, each of which contains a stack of component substrates, which the components with between a Plate and an attached adhesive strip to carry lead wires located thereon; an ejection device from component substrates from a predetermined magazine; a device for sequential separation the component from its ejected substrate; a transport device for separated components; and by a device for attaching the transported component to the workpiece with the introduction of the connecting wire pair solved in a predetermined pair of holes in the workpiece.

The feed device preferably includes a device for aligning each individual component in a predetermined one Position, and a receiving device for the incoming components from the feeding device. Also owns the device preferably below the workpiece a bending device for fastening the electrical Component on the workpiece.

The device has the advantage that with its help a circuit is equipped with various electrical components because it has a number of magazines in each of which one type of component on a component plate or a substrate is stored.

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The feed device with its separating device can be operated so that due to a suitable electrical signal always a certain component substrate is selected, from which then a single Component is separated. Different types of component substrates become due to different electrical signals selectively ejected from the feeder and the severing device in a predetermined sequence fed. Subsequently, each separated electrical component is conveyed by means of a conveyor device Feed device supplied, which, as described above, has an alignment device, which the components brings into a predetermined position and thus the attachment device to work when inserting into the printed circuit board facilitated. After aligning the components, the connecting wires of the components fed to the receiving device, where the connecting wires obtained a predetermined shape.

The attachment device can advantageously with a pair of pliers are provided, which grips the components with downwardly directed connecting wires. These pliers can not only move vertically, but also rotate around its longitudinal axis, if a corresponding electrical Signal is delivered to the component while at the same time inserting the connecting wires into corresponding holes in the Introduce the workpiece or the circuit board. The connecting wire ends protruding downwards are described in FIG Way bent so that the component is firmly connected to the circuit board.

The mounting device according to the invention has many advantages. For example, the processed electrical Do not touch and damage components. Also, different electrical components are used one after the other in a very specific situation and extremely rational

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attached to a printed circuit board without any special gaps between adjacent components are required on the circuit board. The device according to the invention thus contributes significantly to rationalization the manufacturing process of printed electrical circuits.

Further details and advantages of the invention can be found in the following description of a preferred exemplary embodiment with reference to a drawing.

Show it:

1 shows an assembly device in a perspective illustration;

2 shows a substrate with a number of electrical components fastened thereon in schematic form Depiction;

3 shows a schematic representation of the conveying path of an individual component to the feed device ;

FIG. 4 shows a section of an attachment device from the device of FIG. 1; FIG.

5 shows a view from below of a detail of the device, shown on an enlarged scale 4 with an ejector device for a component substrate from a Magazine;

Fig. 6 is a schematic side view of the device of Fig. 4;

7 shows a partially sectioned side view of a cutting device;

8 shows a section through a coupling block from the attachment device;

Figure 9 is a side view of the details of Figure 8;

Fig. 10 is a "side view of a portion of a

Substrate stripping means from the attaching means;

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11 shows a schematic representation of a feed device with a receiving device;

FIG. 12 shows a section through an alignment device from FIG Fig. 11;

13 shows an enlarged detail from FIG. 12 in perspective Depiction;

FIG. 14 shows a component in an upright position on a turning strip from FIG. 13; FIG.

FIG. 15 shows a view similar to FIG. 14, but with the component in the inverted position; FIG.

16 shows a saddle-like element from the receiving device;

FIG. 17 shows a section along a line XVII-XVII of FIG. 11;

18 shows a saddle-like element of the receiving device with attached component;

19 shows an exploded arrangement of the individual parts from FIG. 18;

Fig. 20 is a view similar to Fig. 18, wherein the saddle-like element is in an upright position Position was brought while a wearer of this element is outside a Platform is located;

Fig. 21 is a partially sectioned side view of a component mounting device;

Fig. 22 is a front view of the device of Fig. 21;

23 shows a section along a line XXIII-XXIII in Fig. 21;

24 shows a perspective illustration of a guide element from the attachment device;

25a-d show how the position of a connecting wire pliers and guiding through an outer and an inner hollow shaft which mesh with one another are determined;

26a-g show various phases in which an electrical Component is picked up, released and inserted into a workpiece;

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27 shows a bending device in side view; 28 shows a pair of anvils from the clincher;

29a and b show a deformed by elements according to FIG and assembled electrical component;

30 shows another pair of anvils in a modified design for a bending device;

31a and b show a representation comparable to that of FIGS. 29a and b, in which the connecting wires of the Component was deformed by a pair of anvils according to FIG. 30;

32 shows another exemplary embodiment for an alignment device ;

FIG. 33 is a section through the device of FIG. 32;

FIGS. 34a-f show some subsequent steps from the mode of operation of the modified alignment device, respectively with a standing and with an inverted component;

35 shows a view similar to that in FIG. 32, but with an alignment device which is again modified;

FIG. 36 shows a section through the device of FIG. 35;

37 shows an exploded view with parts of the device from FIG. 35;

38a and b show another modified embodiment for an alignment device;

39 shows a further embodiment for an alignment device;

Figure 40 is a side view of the device of Figure 39; and

FIGS. 41a and b show a further exemplary embodiment for an alignment device, once with an upright once with the component reversed.

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An embodiment shown in Fig. 1 of the drawing for a mounting device according to the invention consists essentially of a storage unit 1 with several magazines 2 for receiving a stack of Component substrates, each of which is equipped with a number of electrical components of the same type is, a cutting unit 3, which has essentially as many cutting devices as magazines 2 are present and each of which is used to sequentially separate electrical components from their substrate are set up, a feed device 4, a receiving device 5 for receiving via the feed device 4 supplied components, an insertion unit 6 for receiving the components from the receiving device 5 and for the successive insertion of the components into holes in a circuit board, and from a positioning unit 7 for aligning the circuit board opposite the insertion unit 6 and a bending device below the circuit board, which with the Positioning unit 7 is connected and one after the other each inserted electrical component on the circuit board attached.

Each of the magazines 2 can be either detachable or fixed to the device. The former case has a special advantage because quickly leaves _for 2 Insert a new Maga, if the components are consumed in the current-use magazine. 2 The substrates within the individual magazines 2 are preferably the same in terms of their dimensions, and each of them contains a number of electrical components of the same dimensions or the same electrical properties. Accordingly, 2 stacks with component substrates can be accommodated in the various magazines, which electrical components

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contain elements of various types. If you want, for example, by means of the assembly device, a certain electrical Assemble printed circuit board which contains a number of resistors, capacitors and other similar components is required, the device carries out the loading process automatically if you have a different one in each magazine Type of components accommodates and this is taken into account accordingly in the programming.

The magazine and the component substrate housed in it are each on top of one another in terms of dimensions or design Voted. A component substrate, indicated schematically in FIG. 2, consists of a number of Disc capacitors 10 each with two parallel and radially outwardly extending connecting wires 11. The connecting wires do not necessarily have to run parallel, but in the present exemplary embodiment of the assembly device the best results can be achieved if the free ends of the connecting wires 11 are spaced apart from one another do not exceed the width of their associated electrical component, which is essentially square or is rectangular in shape.

The component substrate consists of a strip of cheap paper, cardboard, not shown in the drawing or the like. and a commercially available adhesive strip 12, which has essentially the same width as the paper strip. Between the adhesive strip 12 and the one below it Paper strips are glued to the connecting wires 11 of the capacitors 10 in such a way that the free Ends of the connecting wires protrude. In this type of packaging, the capacitors 10 are uniform Clearances and therefore need to be handled particularly carefully in bulk processing.

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The various units 1 to 7 of the assembly device according to the invention already mentioned are described below described in detail.

In addition to the magazines 2, the storage unit 1 has the same number of ejectors 20 as shown in FIG. 5 are shown. Since magazine 2 and ejector 20 are each coordinated in their construction are, for the sake of simplicity in the following a single magazine 2 with its associated ejector 20 described.

According to Fig. 1, 3 and 4, the magazine 2 consists of two U-profiles 2a and 2b, in their facing each other Recesses the ends of the component substrates are guided, and which are connected to one another by two tabs 2c are. The component substrates labeled CS are in rows between the U-profiles 2a and 2b stacked the way that the capacitors 10 protrude on the opposite sides of the tabs 2c. Above the top component substrate CS is a weight 2d is placed which prevents warping of the substrates · CS. The weight 2d can be omitted if the Distortions can be prevented in other ways.

The magazine 2 is releasably or non-releasably attached to a table top 8 which is supported by a frame or the like will. As FIG. 6 shows, the magazine 2 is located behind the cutting unit 3 and above the ejector 20, which is attached below the table top 8.

The ejector 20 has two nail elements 21, which are not thicker than the substrates CS and by corresponding Slots 22 in the table top 8 to the upper

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side of the table top 8 protrude. As will be described later, the nail elements 21 are essentially at right angles and synchronously with the substrates CS stacked in the magazine 2 in order to eject the lowest substrate CS in the stack sideways.

All existing ejectors 20 have two common push rods 23 below the table top 8, a hydraulic cylinder 24 as a drive device, and also two clutch blocks 25, which each Nail elements 21 are assigned and the sliding movement of the push rods 23 is transferred to the nag elements 21. According to FIG. 5, a piston of the hydraulic cylinder 24 is connected to the piston rod 24a and a cross member 24b two push rods 23 connected.

The coupling blocks 25, which are designed identically for all existing nail elements 21, can be seen in FIGS. 6, 8 and 9. The coupling block 25 consists of a solid body 25a with a protruding through the slot 22 shoulder 25b and a recess 25c, which includes the underlying push rod 23 with a sliding fit and parallel to the sliding movement of the nail element 2Λ . Below the push rod 23, the recess 25c is closed by a plate 25d, which at its other end carries a coil 25e with an iron core 25f, which can be moved into and out of the coil 25e. In the right delimitation wall of the recess 25c in FIG. 8, a pin 25g with a sliding fit is inserted, the left end of which in the drawing engages in an annular groove 23a of the push rod 23, and the other end of which is provided with a spring seat 25h. Between the outer wall of the body 25a and the spring seat 25h there is a pressure

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spring 25i, which normally pushes the pin 25g out of the annular groove 2 3a and the iron core 2 5f into the coil 2 5e. When the coil 2 5e is excited, the iron core 25f is pushed outward and overcomes the force of the compression spring 2 5i, and the pin 25g slides into the annular groove 23a of the push rod 23. If the hydraulic cylinder 24 is now actuated, it inevitably takes the clutch block 25, which is now engaged, with it, and the associated nail element 21 leads his previously described movement.

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To an undesired entrainment of the clutch block 2 5 due to the friction between his body 25a and the To prevent push rod 23, a lock is provided. This lock includes a below the Table top 8 fixed housing 25j with a relative to the body 25a open chamber 25k. Compared to this Chamber 25k, the body 2 5a has a recess 25o into which a ball 2 5m located in the chamber 2 5a, which is biased by a spring 25n, slidably locks into place. Thus, the coupling block 25 is locked as long as how the coil 25e is at rest. As soon as the coil 2 5e is energized, the one previously described engages Lock off.

On the table top 8 there are two drive rollers 26 and 27 for pulling off the component substrate ejected from the magazine 2 CS arranged, each with a pinch roller arrangement g 28 or 29 of the same construction work together. Both drive rollers 26 and 27 on common Waves 30 and 31, and their mutual distance is smaller than the length of the substrate CS.

An electric motor 32 with shaft 32a and gear 33 attached to it drives the two shafts 30 and 31 in the same direction of rotation via two further gear wheels 34 and 35. The direction of rotation of the shaft 30 is such that the substrate CS is drawn to the left in FIG. The shaft 31 is driven in the same direction by the shaft 30 via two pulleys 36 and 37 and a belt 38.

The pinch roller arrangements 28 and 2 9 are located below the drive rollers 26 and 27 under the table top 8, and each has an electromagnet 28a or 29a and an L-shaped angle 28b rotatably mounted at 28c or 29c or 29b. The long leg of the angle 28b or 29b

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can be attracted by the electromagnet 28a or 29a. One with its one end on a pinch roller 28e or 29e attached leaf spring 28d or 29d is with its other end on the short leg of the angle 28b or 29b attached, and a stop '28f or 29f limits the stroke of the angle 28b or 29b under the influence of the electromagnet 28a or 29a. Thus, the pinch roller 28e or 29e is pressed upwards when the electromagnet 28a or 29a attracts the long leg of the angle 28b or 29b.

A guide rail runs below the drive rollers 26 and 27 39 with a groove 39a, which serves to guide the respective ejected substrate CS. In the main plane of the pinch rollers 28e or 29e, this has guide rail 39 corresponding openings so that the pinch rollers can contact the drive rollers 26 and 27. These openings are not shown in the drawing.

When the device is in operation, the lowermost substrate CS in a specific magazine 2 is replaced by the corresponding nail element 21 ejected by actuating its coupling block 25, the front end of this substrate CS clamped between the drive roller 26 and the pinch roller 28e. While the drive rollers 26 and 27 are constantly rotate, they can move the ejected substrate further if the corresponding electromagnet 28a or 29a has tightened and presses the corresponding pinch roller 28e or 29e against the drive roller. The ejected substrate CS is first fed to the drive roller 27 and pinch roller 29e, and while its front end is the drive roller 26 approaches with a pinch roller 28e, it is guided through the groove 39a of the guide rail 39. The electromagnets 28a or 29a can be excited separately or synchronously and switched off again.

In the manner described, the pinch roller arrangements are

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gen 28 and 29 of the respective magazine 2 operated intermittently, and the component substrates CS are in the Transported manner that each time a capacitor 10 attached to the substrate is in a cut-off position is brought, which will be described later, whereupon the corresponding electromagnet is switched off again.

It should also be noted that the hydraulic cylinder 24 and each pair of coupling blocks 2 5 and thus of nail elements 21 is operated selectively in a predetermined switching sequence, which is based on the component distribution of the printed circuit board is matched.

The cutting unit 3 consists of a number of cutters 40, one for each magazine 2; the cutter 40 are located between the drive rollers and 27 on the table top 8, and since they are all constructed in the same way only one of them is described in connection with FIG.

Each cutter 40 has a block 41 which is screwed to the table top 8 with screws 41d and a Has vertical bore 42. A hydraulic cylinder 43, the piston rod of which is attached to the block 41 via a bracket 44 43a is normally retracted, but can be extended by filling the cylinder. This piston rod 43a is located in the extension of the longitudinal axis of the vertical bore 42. One movable within the vertical bore 42 Rod 45 is firmly connected to piston rod 43a and carries a cutting element 45a at its lower end Cutting edge 45b and with a recess 45c for receiving a retaining block 46, which in each case from its substrate CS to be cut capacitor 10 holds. The pressure of the retaining block 46 ″ follows by means of a compression spring 47, which is inserted between the retaining block and the rod 45. A pin 48 fastened in the retaining block 46 is located located within a vertical slot 45d of the cutting

element 45a, which is substantially at right angles to The longitudinal axis of the vertical bore 42 runs. This slot 45d also serves to limit the stroke of the relative movement between rod 45 and retaining block 46, as will be explained below.

A knife 49 fastened in a corresponding position to the guide rail 39 works with the cutting element 45a the rod 45 together when the piston rod 43a makes a stroke.

During operation, the component substrate CS is conveyed through the groove 39 a of the guide rail 39 in the manner already described in such a way that the capacitors 10 are located outside the groove. As soon as the clamp. rollers, 28e and 29e have detached from their respective drive rollers 26 and 27 and the substrate CS has thus come to rest within the guide groove 39A, the hydraulic cylinder 43 is actuated and, via its piston rod 43a, presses the rod 45 downwards, which via the compression spring 47 exerts a pressure on the retaining block 46. The compression spring 47 is only compressed when the holding block 46 rests on the guide rail 39 or the connecting wires 11 of the capacitor 10 located above it. Thus, the component or the capacitor 10 is fixed, and in the course of the stroke of the piston rod 43a, the cutting element 45a lowers against the force of the compression spring 47 so that the capacitor 10 is now separated from its substrate because its connecting wires between the cutting edge 45b and the fixed knife 49 are cut off. Then the piston rod of the hydraulic cylinder 43 is moved back to its starting position, and the condenser 10 that has just been cut falls under the influence of gravity through an opening a in the table top 8 into the aforementioned feed device, which is located just below the cutter 40.

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The spent substrate sections, all of which are capacitors are separated, are fed to a waste box (not shown) on the front of the table top 8. The feed device 4 includes two oppositely arranged endless conveyor belts 50, only one of which is indicated in FIG. 1. The conveyor belts 50 are used for Transport of the capacitors separated by the cutter 40 to a funnel 51. Since this funnel 51 is in the middle between the two conveyor belts 50 is located, the conveyor belts 50 of course run in opposite directions Directions.

Each conveyor belt 50 consists of an endless belt 50c which is driven by two rollers 50a and 50b each of which the inner roller 50a is connected to a drive device, for example from the already The motor 32 described could consist of a suitable gearbox. In the present embodiment however, the driven rollers 50a are driven by a separate motor 50d with pulley 50f. One 50g strap connects a motor shaft 50e with the driven rollers 50a, by means of a pulley 50h and intermediate pulleys, as well as two endless belts, which are not shown and for the different directions of rotation of the two rollers 50a. In any case, it is crucial that both belts 50c on both sides of the funnel 51 in each in the opposite direction to each other.

An automatic position control device belonging to the feed device 4 53 corrects the position of the items supplied from the cutting unit 3 by means of the conveyor belts 50 Capacitors 10 in such a way that their connecting wires 11 point down. As can be seen from FIGS. 11 to 15, the capacitors arrive individually and one after the other from the funnel 51 to the receiving device 5 via a first slide 52a, then via dif? Position control device 53, where their connecting wires 11 uniformly after

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are aligned at the bottom and finally via a second slide 52b. (Capacitors aligned in this way are hereinafter referred to as "standing capacitors", while capacitors whose connecting wires face upwards show, are referred to as "inverted capacitors".) The position control device 53 is thus located between the two slideways 52a and 52b.

The position control device 53 includes a massive block 54 each with a large and a small stepped bore 54a and 54b, the design of which can be seen in FIG. Inside the larger bore 54a is an in its contours about the bore adapted rotor 55 rotatably mounted. A pin 55a on the back of the Rotor 55 carries a gear 56, and the entire rotor 55 is provided with a central bore c which is coaxial runs to the bore 54a. This central bore 55c is used to receive a described below and shown in Fig. 13 shown reversing element.

A transverse groove 55b in the rotor 55, which is open at its end face, has essentially the same cross section like the two slideways 52a and 52b.

Within the smaller bore 54b, a smaller rotor 57 is rotatably mounted, its front end face with the front side of the block 54 is aligned and on its rear side a pin running parallel to the pin 55a 57a is attached. On the pin 57a sits a gear 58 meshing with the gear 56 on the other pin 55a, and the rear end of the pin 57a protrudes through a bore of a cover plate 59 and is connected to a not shown Drive shaft of an electric motor 60 connected. As can be seen from FIG. 11, the smaller rotor is 57

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on its front with a U-shaped groove 57b to Receiving a component equipped. The cross-sectional dimensions of this U-shaped groove 57b also correspond those of the two slideways 52a and b, as in the case of the transverse groove 55b of the rotor 55 already described.

Normally, the larger rotor 55 is so that its transverse groove 55b on the two adjacent slideways 52a and 52b is aligned to form a continuous slide path. (As will be described later, this continuous slide are blocked by a sliding reversing element.) The groove 57b of the rotor 57 is aligned also normally with a downwardly directed groove 54e in the block 54, which in the second slide 52 b transforms. For reasons explained below, one of the two rotors 55 and 57 is designed so that it only rotates 180. Correspondingly offset stops ensure compliance with this operating mode. Alternatively, however, the motor 60 can also be arranged so that it moves in opposite directions rotates around 180 ° each time.

All slideway sections 54c, 55b, 54d, 57b, and 54e are covered with a transparent front panel 59 a.

The reversing element 61, which is mounted centrally and movably in the central bore 55c of the rotor 55, is shown in FIGS 13 and has the shape of a cylindrical bolt with a through transverse hole 61a, in which engages a pin 62, both ends of which are firmly in the Pin 55a of the rotor 55 are anchored. Rotor 55 and reversing element 61 are thus fixed in the direction of rotation coupled together. If an electromagnet 64 is energized, the entire reversing element 61 is over its rear

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iron bolt end 63 displaced against the force of a spring 65 in FIG. 12 to the left. The hub is through the length of the transverse hole 61 ^ limits which the pin 62 encloses; the length of the stroke corresponds essentially to the depth of the transverse groove 55b on the face of the larger one Rotor 55 match.

Like the front end of the reversing element on the right in FIG 61 is shown in FIG. 13. A milled cut running through half the cross section of the reversing element 61 61d leaves a front wall 6le and is divided by upright partitions 61b and 61c. For a better introduction of components in the milled recess 61d, the front wall 61e is rounded.

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The following possibilities arise when operating the device:

If a standing capacitor falls out of the funnel 51 through the groove 54c, its connecting wires are supported according to FIG. 14 11 on the bottom of the milled recess 61d and encompass the two partition walls 61b and c. Falls against it 15 from the funnel 51, its body remains on the tips of the partitions 61b and c are, and its connecting wires 11 protrude upwards.

A photoelectric scanning device not shown in the drawing releases the electromagnet 64 with a delay off when a capacitor 10 falls into the transverse groove 55b. This scanning device preferably consists of one Photo cell and a suitable light source, which directs a light beam over the groove 54c in the block 54. Of the Motor 60 can thus be connected to electromagnet 64 via a suitable delay line (not shown) be that after completed left-hand movement of the reversing element 61 according to FIG. 12, this motor 60 is so driven is that it rotates the rotor 57 and synchronously rotates the rotor 55, the reversing element mounted therein 61 rotates with.

As Fig. 12 shows, the two rotors 55 and 57 are each slidably mounted in a bush 66a and 66b, respectively.

The position control device 53 functions as follows: If, according to FIG. 14, an upright capacitor falls out of the funnel 51, the electromagnet 64 is energized first. As a result, the reversing element 61 is withdrawn to the left in FIG. 12 and thereby clamps the connecting wires 11 between its front wall 61e and the front edge of the central bore 55c in the rotor 55 a. As soon as the reversing element 61 is completely withdrawn, the two rotors 57 and 55 guide

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under the influence of the motor 60 a pivoting movement by 180. Of course, the reversing element also leads 61 with the jammed capacitor 10 this pivoting movement with off.

By this pivotal movement about 180 of the two rotors 57 and the clamped member 61 by the reversal capacitor is reversed, and the groove 57b in the ^R otor 57 is now aligned with the underlying groove 54d. After the end of the pivoting movement by 180, the electromagnet 64 is switched off, the reversing element 61 moves forward again and releases the capacitor, which now falls through to the groove 57b due to transverse force. Immediately after the capacitor has fallen into the groove 57b of the rotor 57 in the reverse position, the motor is activated again and pushes the two rotors 55 and 57 back into their starting position. After this has been achieved, the capacitor located in the groove 57b falls by gravity into the second slide 52b.

On the other hand, if an inverted capacitor as shown in Fig. 15 from the funnel 51, the reversing element 61 also attracts, with its body on the partition walls 61b and c lying body of the capacitor 10 slides off and then falls further into by gravity the groove 54d without being pinched. After executing the first pivoting movement of the rotor, it falls into the groove 57b and has thus reached the same position as the previously described capacitor that arrived in a standing position. Of the The capacitor falling through rests against the circumferential surface of the rotor 57 during the first pivoting movement it is in the groove 54d until the groove 57b coincides with the groove 54d and the capacitor falls into it can. From the foregoing it has become clear that all capacitors, whether standing or vice versa fall out of the funnel 51, through the position control device

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device 53 are evenly aligned so that they have this facility in a standing position, so with downward Leave connecting wires 11.

The receiving device 5 has the task of receiving the components coming from the feed device 4 after enlargement the distance between their connecting wire tips to a predetermined value to be transferred to the insertion unit 6. According to Fig. 11 is the receiving device 5 on a guide plate 70 which is attached to a lower extension 54f of the Block 54 of the position control device 53 is attached in a suitable manner.

According to FIGS. 11 and 16 to 20 there is on the guide plate 70 a movable slide 71 supported and at one end loosely connected to a normally retracted piston rod 72a of a hydraulic cylinder 72, which in turn is attached to an extension 70a of the guide plate 70 is. The other end of the slide 71 is worked out into two bearing blocks 71a (FIG. 19). Between these pedestals 71a, a saddle element 73 is pivotably mounted by means of a pin 73b, which with one over both Sides extending curved recess 73a is provided. A spring 73 presses the saddle element 73 into a position shown in FIG. 20 basic position shown. However, as long as the slide 71 and the piston rod 72a are in their retracted position 11, the saddle element 73 is over its lower end into a switching position shown in FIG pressed, which coincides in the direction with the inclined slide 52b from which a capacitor comes slipped.

If the piston rod 72a is extended to the left in FIG. 11, the slide 71 is only taken along when the piston rod moves against a stop 71b; at the end of this sliding movement, the slide 71 has reached a position which

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in Pig. 20 is shown.

At the free end of the piston rod 72a, which is in the retracted state between the upright The end of the slide 71 and the stop 71b is provided with a firmly attached plate 74.

An approximately triangular hammer 75 with a hammer attachment 75a for machining a capacitor, the saddle element 73 was fed and sits on it by its connecting wires 11 so in the curved recess 73a engage so that the capacitor is firmly seated on the saddle element 73, is rotatable by means of a pin 76 mounted on a carrier 77, which is an integral part of the second slide 52b. The one attached to the hammer 75 Pin 76 also carries a lever 78 which is articulated to a drive rod 79 via an intermediate lever 80.

The drive rod 79 carries a plate 81 with an adjusting screw 82, which with the plate 74 on the Piston rod 72a can interact. (Fig. 16). One loosely pushed onto the other end of the drive rod 79 Compression spring 83 biases the drive rod 79 in FIGS. 11 and 16 to the left in a predetermined direction, while the adjusting screw 82 determines the end position for this. So the drive rod 79 moves below the force of the compression spring 83 to the left, the hammer 75 executes a rotary movement and its hammer stop Set 75a touches the body of the capacitor riding on the saddle element 73, as indicated in Fig. 18, but only when the piston rod 72a is extended. It should be noted that the hammering movement of the hammer neck 75a is terminated before or at the same time,

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22S5183

in which the free end of the piston rod 72a abuts against the upright stop 31b of the slide 71. If the hammer 75 assumes its position indicated in FIG. 18, there is a further movement directed to the left the drive rod 79 is limited by the fact that the plate 81 against the lower projection 54f of the block 54 moves without the further movement of the piston rod 72a being hindered.

On the underside of the slide 71, the slide is seated in a recess 71c, a screw stop 84. By means of a set screw 85 can be aligned 71 so that its saddle member 73 is aligned with the lower chute 52b, and .the therein can absorb falling components.

The section laid out in FIG. 17 runs on a line XVII-XVII of FIG. 11 and shows that the guide plate 70 has a channel-like cross section and receives the slide 71 in it, two cover strips 86 close upright walls 70b and 70c so that within the guide plate 70 between a floor 70d and the cover strips 86 a covered guide channel is formed. A ball is seated in a transverse bore of the slide 71 87, which is biased outward by a spring 88. The ball is thus against the upright wall 70b pressed and ensures that there is friction between slide 71 and guide plate 70. These Friction prevents undesired displacements of the slide 71 relative to the guide plate 70.

As long as the piston rod 72a is in its retracted position Position shown in FIGS. 11 and 16 is also taken by the rest. Components of the receiving device 5 the

609842/0365

22S5183

positions shown there. A capacitor 10 arriving on the lower slideway 52 b is from a stop 75c ^ n hammer 75 held, with its connecting wires 11 ready for engagement in the curved recess 73a of the saddle member 73 are. Once the aforementioned photoelectric scanning device emits a signal in the slideway when passing a component, the hydraulic cylinder 72 is in operation set. Then its piston rod 72a with the plate 74 fastened thereon performs a forward stroke the end. Here, the drive rod 79 moves under the force of the compression spring 83, while the Adjusting screw 82 is in constant contact with plate 74. This feed movement runs relatively quickly, and the hammer 75 also rotates around its pin 76 - and thereby releases the capacitor with its stop 75b free so that the hammer shoulder 75a hits the capacitor from above and presses firmly on the saddle element 73. Finally, the front free end of the piston rod 72a meets the vertical stop 71b of the slide 71 and pushes the latter in the appropriate direction. When the piston rod 72a has reached its end position, that stands Saddle member 73 is vertical, as shown in Fig. 20, and the capacitor 10 seated thereon is located exactly below the insertion unit 6, as follows is described.

After the capacitor 10 located on the saddle member 73 is below the insertion unit 6 in the following has been gripped in the manner described, the piston rod 72b returns to its retracted end position. The plate 74 pulls not only the slide 71 but also the drive rod 79 into its starting position return. The return of the drive rod 79

6 0 9 8 U 2 I 0 3 G 5

is therefore dependent on the return stroke of the piston rod 72a, and the hammer 75 also returns to its opposite one Pivot position back, in which the stop 75b is ready according to FIG. 11, the following from the Slideway 52b to catch the incoming capacitor.

The insertion unit 6 shown in particular in FIGS. 21 to 23 has two driver pieces 91 which are rotatably mounted in a hollow shaft 92, and to which two opposing guides 90 are attached are. Adjusting screws 93 are screwed into the fitting pieces 93a attached to the hollow shaft, with which, by turning in opposite directions, the opening width between the opposite ones Can adjust guides 90 or between their free tips. Both driver pieces 91 are normally in opposite directions on their respectively assigned adjusting screw by not springs shown preloaded, which preferably have only a low resilience.

The hollow shaft 92 can be in a bearing block 94, which is fastened to a base plate 95 of a frame 296, twisted and shifted.

A pair of pliers 96 provided with elastic inserts 97 is connected to one via two levers 99 and pins 100 and 102 Central bolt 101 connected, which housed in a bore of an inner hollow shaft 103 and normally is biased by a compression spring 104 in the upward direction. Will be the central bolt 101 in later as described, lowered against the spring force, the free ends of the pliers 96 open and are thus ready to put one on the saddle element 73 of the slide

609842/0 36 5

22S5183

71 riding capacitor 10 to capture. However, as long as no force acts on the central bolt 101, remains he up, and the tongs 96 remain closed. Since the lever with its pins 100 inevitably spreading movements execute, the hollow shaft 103 has recesses 105 so that the lever 99 does not move downwards can collide.

A block 106 rotatably mounted on the hollow shaft 92 is secured to the hollow shaft 92 and by a flange 92a a stop ring 107 with a thrust washer 108 is limited in the axial direction with respect to the hollow shaft 92.

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The Kl./tz has bearing bushes 110 which are attached to a top plate 111 of the block 106 and for receiving serve of displaceable guide columns 109, which protrude vertically upwards.

Furthermore, the movable block 106 has two spacers 112 which are elastically bridged by a leaf spring 113 will. A middle section of the block spring 113 is firmly connected to a holder 114, which is elastic on a lateral Projection 115 of the hollow shaft 103 rests; the hollow shaft 103 has such a projection 115 on both sides. The engagement of the holder 114 on the projection 115 prevents the hollow shaft 103 from rotating unintentionally about its own axis turns. On the other hand, a torque can be exerted on the hollow shaft 103 by the holder 114 and the lateral projection 115 or transferred to the outer hollow shaft 92 in order to rotate both together in the same direction by the same angle, as long as the engagement between these two elements 114 and 115 continues.

A hydraulic cylinder 116 with a movable piston rod 116a is attached to the movable block 106 by means of a carrier 117 attached. The free end of the piston rod 116a, which is provided with a fixed ring 119, protrudes through a hole in a cover 118 through which the upper end of the hollow shaft 103 is closed. One between the hydraulic cylinder 116 and the cover 118 clamped compression spring 120 exerts a constant downward pressure on the hollow shaft 103 off. As FIG. 21 shows, when the piston rod 116a is retracted, the downward movement of the hollow shaft 103 is effected the ring 119 limits - on which the cover 118 rests.

As noted in advance, the hydraulic cylinder 116 is used to actuate the hollow shaft 103 and the central bolt 101 Actuation of the inner hollow shaft 103 and the outer hollow shaft 92 as well as the movable block 106 is a different

609842/0365

£ 265183

their hydraulic cylinder 121, the piston rod of which is attached to the block 106.

The outer hollow shaft 92 carries a gear 124 which is constantly in mesh with a gear 123, which is in turn firmly attached to a shaft 122a of a swivel motor 122. This gear 124 is slidable per se on the outer hollow shaft 92, but has an inwardly protruding nose which into a groove 22b engages the outer periphery of the hollow shaft 92. This groove 92b runs parallel to the longitudinal axis of the hollow shaft 92. In this way, the hollow shaft 92 can be rotated arbitrarily in both directions via the swivel motor 92.

The outer hollow shaft 92 can be selectively predetermined from its basic position via a first and a second Rotate angles, which are preferably offset by 90 ° from one another. To this end, gear 123 has on his Underside a recess 123a, in which a stop 125 engages on the base plate 95 and thus the angle of rotation limited by gear 123 and the hollow shaft 92. If the gear 12 3 runs from one side against the stop 125, so the outer hollow shaft 92 has passed through its first predetermined angle of rotation. The twisting of the outer hollow shaft 92 over the second predetermined angle of rotation 'is through the engagement of a breaker 126 in the recess 123a determined. The breaker 126 is engaged by energizing a solenoid 127; in the In the idle state of this electromagnet 127, the interrupter 126 releases the path of the gear 123.

According to FIGS. 22 and 25, the outer hollow shaft 92 has two opposite ends offset by 90 ° at the upper end Recesses 92c and 92d with different depths. The opposing recesses 92c and d engage in these two recesses lateral projections 115 of the inner hollow

6 0 9 8 U? / 0 3 G Γ> ORIGINAL INSPECTED

22g b 1 83

shaft 103 and limit its downward stroke.

When the two hydraulic cylinders 116 and 121 are in the idle state, various components are in one position as indicated in FIGS. 21, 22 and 26a. If the hydraulic cylinder 116 is actuated from this position and moves If its piston rod 116a extends, the inner hollow shaft 103 lowers under the action of the compression spring 120, and likewise the pliers 96. This downward movement continues until the lateral projections 115 of the inner hollow shaft 103 into the two opposing recesses 92c have arrived at the upper end of the outer hollow shaft 92. Sets the piston rod 116a now continues its downward stroke, the ring 119 attached to the piston rod presses against the upper end of the central bolt 101 and moves it downwards against the spring 104.

During the downward movement of the central bolt 101, the levers 99 move in opposite directions outward, and the pliers 96 open (see Fig. 26b). The hydraulic cylinder 72 of the receiving device 5 then comes into operation, so that its saddle 73 with a capacitor 10 on it is brought into a position in the manner described above, in which the tongs 96 can grasp it. (Fig.26b). The piston rod 116a is then retracted again and the Central bolt 101 is pressed upwards by spring 104. Even before the central bolt's upward stroke ends is, the free ends of the tongs 96 have closed around the capacitor located therebetween. The elastic Deposits 97 of the pliers 96 prevent the capacitor from being damaged.

In the further course of the upward stroke of the piston rod 116a the ring 119 pushes against the underside of the cover 118, so that now the inner hollow shaft 103 against the compression spring 120 is raised in its starting position. In the course

609842/0 3 65

?. 2 S 5 1 B 3

The upward movement of the inner hollow shaft 1G3 also returns the saddle element 73 of the slide 71 to its starting position return. 26c shows how the inner hollow shaft 103 with its pliers 96 and the clamped therein Capacitor has returned to its original position. When the position shown in FIG. 26c is reached the swing motor 122 is switched on and rotates the outer hollow shaft 92. Suppose the electromagnet 127 is located in the idle state and the interrupter 126 thus limits the gear 12 3 by engaging in the recess 12 3a, so this is carried along by the swivel motor 122 until its recess 123a runs against the stop 125. I.e. that the outer hollow shaft 92, for example, by 90 ° with respect to the inner hollow shaft 103 by engagement of a gear 123 is twisted into 124. In the course of this 90 ° rotary movement, the opposing recesses 92c arrive at the upper end of the hollow shaft 92 out of engagement with the lateral projections 115; but now the opposite ones are running Recesses 92d of the hollow shaft 92, which are offset by 90 ° with respect to the other recesses 92c, in engagement with the projections 115 as shown in Fig. 25b. During the rotation of the outer hollow shaft 92 the inner hollow shaft 103 remains stationary because, according to FIG. 1, the holder 114 acts on the lateral projections 115.

While the outer hollow shaft 92 rotates in the manner described above over an angle of 90 °, the their lower end pivotally arranged guides 90, which previously in a running through the condenser Level were brought / moved in such a way that they take up the guide wires of the condenser and so lead that they can be inserted in a predetermined position in a circuit board 500 (FIG. 1). This predetermined position

609842/0365

~ ³⁴ ~ 22SS183

is called the X-position.

However, if the capacitor is to be installed in a Y position offset by 90 °, the electromagnet 127 must be actuated so that the interrupter 126 releases the path of the gear 123. If then the swivel motor 122 moves, the gear 123 can move from one side of the stop without being hindered by the interrupter 126 Turn 125 to the other side. This results in a rotation of the outer hollow shaft 92 by 180.

The first half of this 180 turn proceeds as previously described, and the second half of the turn joins the flange 92a at the upper open end of the outer hollow shaft 92 against the associated lateral projection 115, so that now the inner hollow shaft 103 is taken along because the holder 119 is under the pressure of the leaf spring 113 rests against the projection 115. The changes occurring in the process correspond to the illustration in FIG. 26a via the intermediate position from 26b to the end position according to FIG. 26c. The capacitor detected by the clamp 96 is now ready to be plugged into the Y-position in the circuit board 500, with the connecting wires through the Guides 90 are guided.

As can be seen, not only are the guides 90 aligned with the pliers 96, but an X position can also be used or Y-position with respect to the printed circuit board 500 must be maintained.

The depths of the recesses 92c differ from the other recesses 92d so that the inner Hollow shaft 103 can perform a different stroke with the pliers 96, depending on whether a capacitor

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'Ü2S5183

picked up by saddle element 73 or by forceps 96 is to be plugged into the circuit board 500.

When the capacitor is plugged in, the inner hollow shaft 103 returns to its starting position with tongs 96, the outer hollow shaft 92 rotates back in the opposite direction, causing the flange 92a to run against the projection 115, as shown in Fig. 25d, and then the inner hollow shaft 103 by abutment of the flange 92a entrained at the corresponding projection 115 by the outer hollow shaft 92 until the starting position according to FIG. 25a is reached again. In this position, the holder 114 engages the lateral projection 115 again.

As the leads of the capacitor are inserted into the circuit board 500, the guides 90 and the tongs take hold a position according to FIG. 26d. Then, when the hydraulic cylinder 121 is operated, the downward movement occurs its piston rod transferred via the movable block 106 to both hollow shafts 92 and 103, so that both are downward move. At the end of this downward stroke of the two hollow shafts 10 and 103, the tips of the guides 90 touch the top of the circuit board 500 above two holes 500a (see Fig. 26e).

The hydraulic cylinder 116 is now actuated again, and its piston rod 116a lowers the inner hollow shaft 103 with it the pliers 96 until the lateral projections 115 in: the opposite recesses 92d at the upper end of the Engage hollow shaft 92. During this downward movement of the inner hollow shaft 103 with the tongs 96, the of The pliers-grasped capacitor is pushed into the circuit board 500, with its leads from the guides 90 are inserted into the corresponding holes 500a,

INSPECTED 609842/0365

■ ³⁶ ~ 22SL) 1 83

so that the state shown in Fig. 26f is reached.

Now the downward movement of the inner hollow shaft 103 is limited by the recesses 92d, while in the The continuous downward movement of the piston rod 116a of the ring 119 onto the central pin 101 is in progress presses so that it opens the tongs 96 on its downward movement and releases the capacitor.

Then the inserted connecting wires of the capacitor are underneath by means of a bending unit of the printed circuit board 500, as will be described below in connection with FIGS. 27 to 31. In order to the capacitor is firmly connected to the circuit board 500.

According to FIG. 24, each of the guides 90 has a narrowing guide shaft 90a for introducing a Conductor wire of the capacitor into a hole 500a. In addition, the inner hollow shaft 103 has at its lower Part of lateral projections 103a (Fig. 26d to g), which with the correspondingly shaped driver pieces 91 only then come into engagement when the tongs 96 and the two guides 90 are in the same direction. During the insertion operation of the capacitor into the printed circuit board, the lateral projections 103a slide between the driver pieces 91 in conjunction with the adjusting screws 93 through and ensure that the guides 90 a take a predetermined distance between the tips. After the component has been plugged in, there is no longer any engagement between the projections 103a and the driver pieces 91 instead, as can be seen from Fig. 26f or 26g.

ORIGINAL 609842 / 03GB

When the component insertion process is complete, the hydraulic cylinder 121 retracts its piston rod, and the movable block 106 returns along with the two Hollow shafts 103 and 92 return to its upper end position. In the course of this upward movement, the lateral ones come Projections 103a again disengage from the driver pieces 91, and the guides 90 can freely move around the pins twist on which the driver pieces 91 at the bottom End of the outer hollow shaft 92 are rotatably mounted. Since the block 106 is together with the two hollow shafts 103 and 92 moved upwards, the guides open outwards, as indicated by arrows in FIG. 26g the capacitor plugged into the circuit board 500 is thus released.

Then the piston rod 116a is further up retracted to turn the inner hollow shaft 103 in the manner described above, and if then the Swivel motor 122 is switched on, the hollow shafts 103 and 92 return to their respective starting positions, so that the component insertion cycle is now fully completed.

In this way, an electrical component, such as a disc capacitor, for example, can be parailed with two Reliably mount connecting wires on a circuit board; by adjusting the adjusting screws 93 the distance between the tips of the guides 90 and thus the distance between the lead wires of the capacitor change at will.

The bending unit, not shown in FIG. 1, is seated below the printed circuit board 500 ″ connected to the positioning unit 7 and exactly below the guides 90 of the infeed unit 6. The bend shown in Fig. 27

609842/0365

Unit 150 has a base body 151 fixed in a suitable manner in a stationary manner and having a lower cylindrical one Extension 151a, which contains a chamber 152, and an upper cylindrical extension 151b. A cylindrical piston 153 has a shoulder 153a on which a seal 154 rests, fitted within the chamber 152 with a sliding fit is and thereby seals against the inner wall of the lower cylindrical extension 151a. The top of the Piston 153 is open and is located within the upper cylindrical extension 151b, and the lower end of the piston 153 is fitted with a sliding fit in an end ring 155, which at the lower open end of the lower cylindrical extension 151 is screwed by means of some screws 156. It should be noted that the chamber 152 by the shoulder 153a of the piston 153 is divided into two working chambers 152a and 152b.

In an inner annular groove of the end ring 155, a seal 157 is housed, which the second working chamber 152d seals against the outside atmosphere. The first working chamber 152 a is provided via an outlet channel oil 158 in connection with the atmosphere; within the outlet channel 158 is a spring 159 which is between a lower surface of the main body 151 and the shoulder 153a is clamped so that the piston 153 is constantly after is biased at the bottom. The second working chamber 152b is connected to a connection 160 and a channel 161 suitable air source.

If a pressure medium reaches the working chamber 152b via the channel 161, the piston 153 is counteracted by the force of the Spring 159 is pressed upwards, and the medium standing in the first working chamber 152a is discharged via the outlet channel 158 pressed into the open. The piston 153 returns to its drawn

609842/0365

It is back to its original position as soon as the print medium is drained again. As you will see later, you can the piston 153 not only move vertically, but also rotate about its longitudinal axis.

An insert which is subdivided at its upper end by a milled cut into two opposite supports 162a 162 is inserted into a longitudinal bore of the piston 153 and on its underside opposite the piston by a Flange 162b fixed. This flange 162b is screwed to the piston 153 with screws 163, so that the insert 162 must join the movements of the piston 153. A bore 165 opening coaxially into a recess 164 inside the insert 162 opens into the open between the two supports 162a. In the hole is one with one Conical tip 166a provided plunger 166 guided displaceably, which on its underside with a collar 166b is provided, which is slidably housed in the recess 164. A sealing ring 167 in a groove from The collar 166b seals it against the inner wall of the recess 164.

The open end of the recess 164 is closed by a screw bit 168 with an air inlet 168a. The recess 164 is thus through the collar 166b of the plunger 166 into a first working chamber 164a and a second working chamber 164b divided. The first working chamber 164a contains a spring 169 which presses the plunger 166 downwards, while the second working chamber 164b is in communication with a suitable air source via the air inlet 168a, so that when the pressure medium is fed into the second working chamber 164b, the plunger 166 against the spring 169 upwards can be moved.

Near the top of the bore 165 is a toothed ring 170

609842/0365

mounted on the base body 151, namely above the upper edge of the cylindrical projection 151b. Part of the insert outer surface is designed as a guide 162c extending vertically to the longitudinal axis of the insert 162, and A screw 171 seated in the toothed ring 170 engages in this guide in a displaceable manner. A driver 173 acts on the toothed ring 170 in such a way that it rotates when an associated hydraulic cylinder 173 is actuated will. The rotary movement of the toothed ring 170 is activated by means of the screw 171 engaging in the guide 162c the insert 162 and the piston 153 transferred. On the other hand, the guide 162c is long enough to prevent vertical movement of the insert 162 can be transferred to the ring gear 170.

Two anvil pieces 174 formed at their upper ends as shown in FIGS. 28 and 30 are each at their lower end provided with a rotatable roller 175 and on a common axis 176 between the two supports 162a of the insert 162 movably mounted. The two anvil pieces 174 are normally pressed together by means of compression springs in such a way that that their rollers 175 lie against one another as shown in FIG.

If, during operation, one between the two connecting wires of the capacitor inserted into the circuit board 500 running imaginary line not one running between the profiled ends of the two anvil pieces 174 the imaginary line, the insert 162 by means of toothed ring 170 and hydraulic cylinder must first be rotated together with the piston 153 so that the correct angular position is established.

Subsequently, a pressure medium is admitted into the second working chamber 152b via the connection 160 and channel 161, so that the piston 153 with the insert 162 against

609842/0365

? 2β5183

the force of the spring 159 is driven upwards. In the end position of this upward movement are the
profiled ends of the two anvil pieces 174 near the underside of the circuit board 500, through whose bores 500a the ends of the connecting wires of the capacitor protrude and are now located between the two profiled ends of the anvil pieces 174.

If the insert 162 is in its upper end position, a pressure medium is filled into the second working chamber 164b via the air inlet 168a, which presses the plunger 166 upwards against the force of the spring 169. In doing so, didconical tip 166a moves between the rollers
175 and thereby presses the two profiled ends of the anvil pieces 174 together by means of leverage, so that the ends of the capacitor connecting wires located between them are firmly clamped. This process
occurs very quickly, and the force transmitted from the profiled ends to the connecting wires is sufficient to deform the wires according to the shape of the profiled ends of the anvil pieces 174.

After the pressure medium has been released from the second working chamber 164b, the plunger 166 returns to its lower starting position by spring force, and so does the
Anvil pieces 174 resume their starting position shown in FIG. The hydraulic cylinder 173 is then brought back into its starting position, so that the toothed ring 170 moves the insert 162 and the piston 153 back into their respective starting positions during its return movement. The entire cycle of the bending unit is now complete.

Fall the profiled ends of the two anvil pieces 174
have opposite recesses, as in Fig. 28

609842/036

22Sb183

shown, the ends of the connecting wires of the capacitor are bent in opposite directions, as shown in Fig. 29a and b is shown. The capacitor is thus connected to the printed circuit board 500 in such a way that it cannot be lost. If the two ends of the anvil pieces 174 as shown in FIG. 30 complement one another, so the ends the leads of the capacitor are flattened as shown in FIGS. 31a and b. The crush sections at the conductor wire ends are wider than the holes 500a in the circuit board 500, so that here too a captive Connection is guaranteed.

The bending unit thus deforms the downwardly protruding tips of the connecting wires of the capacitor opposite curvatures or by flattening without there being substantial contact between the Anvil pieces 174 and the circuit board 500 comes. The circuit board is therefore not scratched. The previously used The capacitor maintains its position constant during the bending operation, and the bending or. Crushing operation will not hindered by the capacitor itself.

The following is a description of preferred embodiments, all of which relate to the position control device 53 within the feed device 4. And that is Modified exemplary embodiments in each case are shown in the drawings 32-34, FIGS. 35-38, and FIGS. 39-41. For the sake of better Overview, the same reference numerals are used in FIGS. 32-41 as previously in FIGS. 11 and 12.

In the embodiment shown in FIGS. 32-34, the reversing element 61 known from FIGS. 11 and 12 is missing with electromagnet 64 in the bore 55c of the rotor 55. Instead, in the front of the rotor 55 is an almost circular

609842/0365

2183

Shaped recess 200 introduced, the ends 200a and 200b are close to each other, and the end 200a normally forms an extension of the groove 54c (Figure 32). The other rotor 57 has an approximately U-shaped recess 57b ¹ in its corresponding front side, the opening width of which corresponds approximately to the sum of the opening widths of the two recesses 200a and b of the recess 200 in the rotor 55.

A step 200c within recess 200 is intended to have a capacitor entering through open end 200a stop if this capacitor arrives standing; becomes a capacitor arriving in the opposite position not stopped. According to Fig. 34a-c, a standing incoming capacitor remains with the end of its one terminal. wire hanging in stage 200c and is used in the beginning Revolution of the rotor 55 taken along. As is known, the rotor 55 is over the other rotor 57, gear 58 and motor 66 rotated.

As soon as the state shown in FIG. 34c is reached and the two open ends of the recess 200 are located exactly opposite the groove 57b ^{1 of} the rotor 57, the capacitor falls into the groove 57c ¹ with its body pointing downwards.

As shown in FIGS. 34d-f, a capacitor that falls in the reverse position into the recess 200 also falls with its body facing downwards into the groove 57b, because the condenser during the rotation of rotor 55 does not get stuck in step 200c, but slips through smoothly.

Once the capacitor is in the body facing down

60960/03 f> 5

Groove 57 'is located, runs as described above Embodiment of the motor 60 in the reverse direction back, and the rest of the process runs as described there

In the next embodiment, which is shown in Figs.
35-38 is shown, the previously described step 200c is missing within the recess 200 of the rotor 55 as a determining element of the position control device 53, because
in their place a pawl arrangement is provided. Seated in a recess 300 at the edge of the recess 200
a pawl 301 with a pressed-in pin 302 which connects the rotor 55 by wire and on its other side
an actuating piece 303 carries. Normally, a spring 304 constantly presses on the actuating piece 303 so that
a gap 305 is formed between the pawl 301 and an edge 200d of the recess 200.

According to Fig. 35 or 36 is located in the inner bore
of the block 54 for receiving the rotor 55 is a segment
305a, over which the actuating piece 303 glides during the rotation of the rotor 55 and thereby the pawl 301
presses against the edge 20Od.

The function of this exemplary embodiment for a position control device is similar to that described above. In the embodiment according to FIGS. 35-37, at least one of the two connecting wires of the capacitor, which falls into the recess 200, is between the pawl 301
and the edge 200d clamped while the actuator 303 slides over the segment 305a, as shown in Fig. 38a. If, however, according to FIG. 38b, the capacitor falls in the opposite position into the depression 2oo, then it can
his body initially get caught on the edge 200d, but is then immediately pushed away and not

609847/036 5

clamped. Of course, with this position control device both square and right-angled electrical components in the frame of the fixture to process.

The exemplary embodiment for a position control device 39 to 41 has two at a distance parallel plates 400a and 400b, which are separated from each other by spacers are separated and form the already mentioned slideways 52a and 52b. In the space between the two plates 400a and b there is an angle piece 401 with an axis 402, which with one end in the plate 400a and attached with its end protruding through the other plate 400b to a rotary magnet 60a, is that when this rotary magnet is actuated, the angle piece 401 executes a rotary movement. One on a short leg 401a of the angle piece 401 attached tongue 403 points with its free end in the direction of the slide 52a, while a long leg 401b of the elbow 401 slides on a curved surface 404a of a solid Wall piece 404 of the slide 52a rests. If the left piece 401 is now rotated by the rotary magnet 60a, The end of its long leg 401b slides along this cam surface 404a without forming a gap.

In this gap between the two flats 400a and b, a U-piece 405 can also be rotated on a shaft 406 stored; this shaft 406 is connected to a further rotary magnet 60b, and the U-piece 405 normally stands so that a capacitor brought by the angle piece 401 must fall into it. The U-piece 405 can Twist until its middle recess coincides with the slide 52b.

609842/0365

The function of this position control device is shown in FIGS. 41a and b. Becomes the position control device 53 a reversed capacitor is fed via the slide 52a, the capacitor collides with its Body against the tip of tongue 403, as shown in solid lines in Figure 41a. If now the If the rotary magnet 60a is switched on, the long leg 401b slides along the cam surface 404a, as described. During this rotational movement of the elbow 401, the capacitor rotates around its own axis until its left connecting wire rests on the tongue 403, as indicated in Fig. 41a with broken lines. Finally, the elbow 401 reaches its lower end position, where its long leg 401d with the left Legs of the U-piece 405 match, while the tongue is directed into the recess of the U-piece 405. The capacitor now falls into the recess of the U-piece 405 with its body pointing downwards, as in FIG 41a is also indicated with broken lines. The other rotary magnet 60b is now switched on and rotates the U-piece 405 to the left, as shown in Fig. 41a with broken lines. Inevitably The capacitor now slides into the slide 52b with the connecting wires stretched obliquely downward.

If, according to FIG. 41b, a standing capacitor comes out of the. Slideway 52a, then the tongue 403 lies between the connecting wires from below against the body of the capacitor ^ as shown in Fig. 41b with solid lines is. Like the various intermediate stations shown in broken lines in Fig. 41b can be seen, the capacitor in this position is carried along by the longer leg 401b and falls with it body facing downwards into the recess of the U-

609842/0365

22S5183

Piece 405, the condenser in the course of its 90 -swiveling movement with directly downward Connecting wires conveyed into the slide 52b.

In particular, the last-described exemplary embodiment for a position control device has the advantage of being very to be easy and cheap to manufacture.

In principle, all of the exemplary embodiments according to FIGS. 32 to 34 or 35 to 38 or 49 to 41 are interchangeable with the first-described embodiment according to FIGS. 11 to 15, without the inventive Assembly device would be limited in its performance.

Of course, the invention is not restricted to the exemplary embodiments described above ^; Numerous modifications are possible within the scope of the invention.

In summary, the invention relates to a mounting device for the automatic insertion and subsequent bending of radial and / or parallel to one Component or other body protruding connecting wires on a workpiece, which essentially from a storage unit with a number of component magazines, a cutting unit for separating the individual components Components from a carrier, a feed device with position control device for even Alignment of all components in a predetermined position, a receiving device for transferring each one Component to an insertion unit, and from the insertion unit, which grips the components with pliers and releases them again, and a bending device possesses, which fastened the ends of the connecting wires to the workpiece to be fitted.

609869/03 Γ) 5

Claims (1)

Claim * 1. Assembly device for automatic sequential Equipping a workpiece with a number of components, each of which has at least one radial or has a pair of connecting wires protruding in parallel, characterized by a number of magazines (2) of each of which contains a stack of component substrates (CS), which the components (10) with between a Plate and an attached adhesive strip (12) carrying lead wires (11) located thereon; An institution (20) for ejecting component substrates (CS) from a predetermined magazine (2); a device (3) for the successive separation of the components (10) from their ejected substrate (CS); a feeding device (4) for separated components (10); and by means (6) for attaching the supplied component (10) on the workpiece (500) while introducing its connecting wire pair (11) into a predetermined one Pair of holes (500a) on the workpiece 609847 / 03SB