DE1086930B - Punch drive for devices for punching or notching recording media - Google Patents

Description

As is known, the can on the movable armature of an electromagnet with a variable air gap exerted attraction force when energizing the electromagnet approximately as inversely proportional to the Square of the air gap width. This means that this power grows very quickly as soon as the Air gap reduced. In punch drives, in particular for punching recording media, is it is desirable that the maximum force be available as soon as the electromagnet is energized and then subsequently has a smaller force.

There are known designs of electromagnets which meet this latter condition (Plunger core electromagnet without bottom piece or electromagnet with constant air gap), but this one Versions that do not have a good level of efficiency given the power consumption in relation to the power supplied have, work with consistent performance and require significantly more space than that Electromagnet with variable air gap.

The object of the invention is a punch drive with better utilization of the variable force, which depends on the movable armature of an electromagnet with a variable air gap is supplied by the change in the air gap during closing.

The arrangement according to the invention is particularly based on electromagnetically operated mechanisms for punching or notching recording media made of solid material such as paper, cardboard, Plastic or metal, applicable.

The arrangement according to the invention enables better utilization of the armature of an electromagnet supplied force and a significant reduction in the power requirement of the electromagnet for a certain job.

Another advantage of the invention is that due to the reduction it allows the power requirement of the electromagnet for a specific job, the construction is more compact and the mechanism can be simplified.

In the arrangement according to the invention, the electromagnet during the first part of the Closing movement of its armature developed energy via an elastic intermediate link on the punch transfer. Intended stops limit the extent of the change in shape of the elastic intermediate link, these stops are arranged such that the initial resistance of the to during the punching process punching material against the punch movement causes the change in shape of the elastic intermediate member and then the force delivered during the further armature movement via a stop to the actual Punch is transferred to the punch, punch drive for devices

for punching or notching

of recording media

Applicant:
Compagnie des Machines Bull, Paris

Representative: Dipl.-Ing. B. Wehr, Dipl.-Ing. H. Seiler,

Berlin-Grunewald, Lynarstr. 1,
and Dipl.-Ing. H. Stehmann, Nuremberg 2, patent attorneys

Claimed priority:
France, 5 October 1956

whereupon the pontic relaxes and transmits an additional movement to the punch, the drives the punched-out waste part through the perforated die.

It shows

Fig. 1 is a schematic view partially in section the actuators of the punch a electrically controlled punching machine of known type for punch cards or punched strips, which still is not provided with the improvements according to the invention,

2 shows a schematic section of a punch drive with an arrangement according to the invention,

Fig. 3 is a diagram in dash-dotted lines for a known device and in full Lines for a device according to the invention approximately on the one hand the course of the force which the movable armature of an electromagnet when energized can exert as a function of approach its air gap, on the other hand the course of this electromagnet on the punch during • represents the force transmitted by a punching process,

Fig. 4 is a diagram showing the relative changes in position of the solenoid armature and the punch represents in an arrangement according to the invention,

009 570/218

Fig. 5 is a schematic, section through a with an arrangement according to the invention provided punch drive,

Fig. 6 is a view in the direction 6-6 of part of Fig. 5 showing an embodiment detail the elastic member of the punch drive,

7 shows another embodiment of a punch drive according to the invention,

FIG. 8 is a sectional view along the line 8-8 of FIG. 7 with the representation of execution details of the elastic member of the punch drive.

A registration card 10 (Fig. 1) is inserted into a punching device which contains a number of punch * 5 stamps; of these, only one punch 11 is visible in the sectional view, while the others are hidden behind the punch shown. The stamp 11 is normally pressed down by a spring 12 which is clamped between a collar or collar 11a firmly connected with the ao stamp on the one hand, and a fixed rail lic on the other, in which the guide openings for the stamps are attached. The collar 11 α of the stamp rests on another stamp as guide rail 11 b, which is immovable and firmly connected to the housing of the machine. If the punch is pushed upwards by an actuating mechanism to be described immediately, the collar 11a of the punch compresses the spring 12, and the punch 11 penetrates a perforated die 13 which is mounted in a die bar 13 α. If a card 10 is inserted between the punch and the die, it is punched, and the paper cut out of the card is pierced by the punch through the die and taken up by a channel 14 from which it is removed by a suitable device, not shown . The force exerted on the punch for punching is supplied by energizing an electromagnet 15, which attracts a movable armature 16 that is firmly connected to a punching bar 17. The rail 17 can only act on the punch via an intermediate piece 18 which, under the action of the movable armature 20, pushes an electromagnet 19 between the head 11 d of the punch 11 and the punching bar 17. A return spring 21 pulls the intermediate piece 18 against the stop 22 when the electromagnet 19 is no longer excited after the piercing process. The basic arrangement described above is very widespread in the machines used for punching registration cards or strips, -It has the main advantage that it allows control of the spacers for the stamps with relatively weak currents, but that for exciting the electromagnet 15, which supplies the punching job, the current required is very much larger. The dimensions of the electromagnet 15 are also much larger than those of the electromagnets 19 which merely control the spacers. A disadvantage of this arrangement is that the adjustment of the spacers introduces a dead time into the sequence of the partial operations which together form a working cycle of the punching device. This is a very significant disadvantage for the quick punch that will be used in particular for punching 6g strip, "There. Have been proposed fast operating machines for .Lochen of strips in dene_n _r the perforations of a stamp are produced by pressing down, the most The end of the armature of an electromagnet is secured with sufficient power to punch the paper immediately Intermediate pieces have been left, but which works less quickly in principle.

To the advantages of the invention, which will be shown later in detail, over those described above To better emphasize arrangements, reference is made to the diagram of Fig. 3, the in dash-dotted lines the operation of a punch drive when working with or without Intermediate pieces shows. The changes in the air gap of the electromagnet are plotted as abscissas, and the reference number 2 corresponds to the largest air gap at which the developed by the electromagnet Force is smallest when it is excited, and the reference number 0 corresponds to the smallest Air gap where the force developed by the electromagnet is greatest. As ordinates are the forces plotted, and the curve 30 represents approximately the course of the movable armature of the electromagnet available force as a function of the change in the air gap when winding the electromagnet is excited with a direct current of substantially constant voltage. The curve 31 in the same Figure represents the change in the transmitted from the electromagnet to the punch during punching Force.

To illustrate 1 of the drawing is made to FIGS. Reference is made, but in order to simplify the train of thought, apart from the intermediate portion 18, and, assuming that the head of the punch 11 have the shape shown by the line 11e and to the immediate vicinity the rail 17 is changed in the rest position. Under these conditions, when the electromagnet 15 is excited, the armature 16 is attracted and the punch bar 17 is brought into contact with the head of the punch 11, which it lifts. The electromagnet must then deliver the force required to compress the spring 12; this force is shown at the beginning by the ordinate point 32 in the diagram of FIG. The punch then comes into contact with the card 10, which is supported against the die 13 and offers substantial resistance to the passage. The force delivered by the electromagnet increases rapidly, as indicated by the line between points 33 to 34 on curve 31 of the diagram. At a given instant, the punch penetrates the card and cuts a hole in it, while the force of the electromagnet remains almost the same, as indicated by points 34 to 35 on the curve. As soon as the stamp has broken through the card, the force supplied by the electromagnet decreases very quickly, as the curve, starting from point 35 to point 36, shows. At this moment the electromagnet only supplies the force that is required to compress the spring 12 and to expel the punch waste through the die, as is indicated by the curve from point 36 to point 37. When the electromagnet is de-energized, the spring 12 returns the punch to its lower rest position and also the punch bar 17 against the stop 23, to which it is applied by a return spring 24, the role of which has been omitted in the above explanation. ■.

In order for the stamp to punch the card with security against the card 51, the spring lJ can, must obviously the curve 30, which is the most between the guide plate 52 and the end face 53 movable armature of the electromagnet available force of the hollow cylinder 44 is compressed. These reproduces at 38 (Fig. 3) substantially above the force increases during the compression of the The apex 34-35 of the curve 31 run. The tip 35 5 spring 49 easy to, as in the diagram by the determines how big the power of the electromagnet line between the point 32 and the point 33 in have to be. At times this curve is allowed to be shown in FIG. If then the compression begins very close to part 34-35 of the curve and even under the spring 43, that of the electromagnet grows half of it by the force supplied by the reaction, like the line in the diagram of 33 which shows 10 to 61 stored in the moving parts of the drive. It then occurs through line 61 bis kinetic energy is calculated. A Co-Foundation Force displayed on this 62 of the graph executed drive, however, does not result in pressure on the spring 43. As soon as the stop 46 sufficient operational safety. of the stamp against the bottom 47 of the spring

The removal of the hollow cylinder held by the stamp from the card pushes the force of the punched paper through the die is 15 electromagnets, as shown by the line 62-63 of the slide of great importance, because if this paper gram is displayed. At this point in time the waste is pushed far into the die, the force exerted by the armature 40 of the electromagnet can return with the punch and lay across a card hole that is directly transferred to the punch, where it forms a thickening. At a given moment represented by the point 63 of the diagram and the displacement of the card in front of the punches 20, the card suddenly gives way for the setting of another entry column; In certain cases, such a piece of paper can be separated from the card, and the machine opposite the jammed card to the advance of the stamp can only be removed by tearing it from the card. This disadvantage is particularly resistance decreases quickly, as indicated by the line 60 in the so-called "punching machines with sight cards" 35 of the diagram. Fear the spring 43 relaxed, in which the punching is done from below, from point 64 to 65 of the diagram and thus pushes the card from the view of the operator quickly Matri- 54 through. After releasing the spring 43 moves zenzeile is covered. _{In this arrangement shown in FIGS} . 1, 5, according to points 65 and 7, there is not only the 3o to point 37 of the diagram, with the effect of the risk that the punched out and from the card 'movable Electromagnetic armature. The spring 49, which separated paper by the punch, is brought back into the card plane by the movement of the movable solenoid, but also that it falls back there under the armature compressed during the punching action of its weight; therefore, was relaxed at its deenergization and it is important that the waste paper by the punch ^ throws the movable armature against the repose stop very far advanced or excluded from the die 50 back.

is thrown. From the following it can be seen that the diagram of FIG. 3 shows that by the

the forming the subject of the invention arrange- inventive arrangement of a resilient member voltage not only a better utilization of the in the hole punch drive results in the tip of the force supplied by the Move-Lochungselektromagnet, special ₄₀ loan solenoid armature for punching the card to the same time a better ejecting of the force supplied from point 35 to point 63 ensures paper waste. has been postponed. Because of this, the

Fig. 2 shows schematically in section a force developed by the electromagnet, for actuating an electromagnet actuated and equipped with a perforated mechanism under the same operational safety ^ - of the invention equipped 45 conditions required by the curve 30 punch drive on the curve 66, ie on the force curve of an electromagnet 41 with a punch 42 is an electromagnet that requires less space and a weaker actuating current due to a rod 48 and an elastic member. At the tied as examples, the one between a shown with the stamp in Fig. 3 approximation curves is z. B-. too firmly connected collar or collar 45 and the _5o see that in point 1, ie halfway the beBoden 47 of a hollow cylinder 44 clamped spring movable armature, which contains an electromagnet with 43. If the spring is additionally compressed within the properties of the hollow cylinder indicated by the curve 66, the force supplied moves essentially half the force of the stop 46 of the punch against the bottom 47 of the corresponding to that of an electromagnet with the hollow cylinder and limits the Compression 55 the curve 30 displayed properties is delivered to the spring. A spring 49 surrounding the plunger 42. The diagram in FIG. 4 shows the relative movement

is based on the one hand on a fixed plate 52 and movements of the movable electromagnet armature and the on the other hand, expresses the stamp, elastic stamp. The abscissas are the movements of the Organ, rod 48 and movable armature 40 of the movable armature (on the same scale as FIG. 3) Electromagnet existing unit applied against a the 60, and the displacements of the punch Stop 50 which determines the rest position. The springs are also designed as ordinates on the same scale so that the spring 49 is carried more easily. The line from point 70 to point 71 of the gives as the spring 43 and the spring 43 together- curve Fig. 4 indicates that the stamp is with the depressed state is not so strong that it moves the movable armature forward. The line from The stamp 42 can penetrate into the card 51. The we- 65 point 71 to point 72 indicates that the stamp of k way of the arrangement of the card shown in Fig. 2 is held up, while the spring 43 is now based on the diagram of Fig. 3 (Fig. 2) through the movement of the movable armature described. is squeezed. The point 72 gives the

If the electromagnet 41 is energized, the armature exercises the moment in which the stop 46 with the sufficient force to move the plunger 42 70 bottom 47 of the cylinder 44 'containing the spring 43

7 8

comes into contact. The line 72 to 73 shows approaching, taking the axis 90 towards the top the movement of the movable armature while it creates the elongated holes 93 and 94. The way of working Stamp pokes through the card. In the diagram of the arrangement of FIG. 5, the working Fig. 4, the part 72-73 is relatively extended, as in the arrangement according to FIG. 2, which has been described above a punch with a chisel or wedge-shaped 5 ben was.

Head is provided as indicated in FIG. When the solenoid 92 is energized, the

Point 73 of the curve shows the moment at which movable armature 91 is pulled down. Through the the punched-out paper separates, and the line hereby tensioned spring 95 and through the lever 86 73-74 represents the movement of the punch, while a movement is transmitted to the punch 80, the spring 43 relaxes and the punched-out paio that pierces the spring 83 by means of its collar 81 is pushed through the die. The presses and is now on the card to be punched Line from point 74 to point 75 shows that it supports 96. Under the one from the card the passage movable electro-magnet armature and the stamp their resistance opposite to the stamp becomes the End movement at the same speed. Spring 95 extended by the electromagnet the excitation of the electromagnet interrupted 15 pulled until the axis 90 reaches the lower edge of the is, the movable armature and the punch elongated holes 93 and 94 are created. From that moment together by a straight line 78 from 75 to on is the force developed by the electromagnet 70 illustrated movement under the action of the tabs 88 α and 88 & as well as through the relaxing spring 49 (Fig. 2) in the rest position to transfer lever 86 directly to the stamp, the returned. 20 holes the card. The part punched out of this gives

The spring 95 can contract through the line from point 74 to point 75, and the simultaneous rapidly advancing punch 80 indicated in the diagram of FIG through into which can appear superfluous; it would actually suffice in the sense of the collecting channel 98, from which it is actually sufficient, by means of an invention that is known per se, that the electric clearing element 99 is removed. If the electric armature stops moving forward as soon as the magnet 92 is no longer excited, the punch relaxes and has penetrated the card, and spring 83, by pulling the punch 80 out of the die, pulls the punched out paper waste from the die and the Movable armature 91 of electrical spring 43 through the die through the tromagnet returns to its rest position. The can butt, that is, that the movement of the armature is _{stopped on the 30} drives of the punch of a row of punches can vertical 73-76 of the diagram. in a punching machine alternately on one side and on the other, however, the consideration of operational safety has led to the described arrangement through the axis YY. This applied punch plane to be arranged around the order of magnitude could in fact continue to function even in the case of a space for accommodating the electromagnets for the spring 43 to break. The stem 35 available.

pel would, albeit with less certainty. In the arrangement shown in FIGS. 7 and 8

Visible to the elimination of the punched-out paper, the spring of the elastic organ also works if, after the card has been pierced, it continues to act as a tension spring, but the mechanical parts drive this punched-out paper into the die, as if they are pivoted by the organ. One end of the line from point 73 to point 77 (FIG. 4) is ₄₀ a spring 100 is placed in a lever-like part. 102 mounted recess 101 is suspended. That

The elastic member can be in various forms, the other end of the spring 100 is in a recess are executed. For example, the stop 103 of a part 104 can be hung that can be pivoted on 46 in Fig. 2 can be omitted if a spring of an axis 105 is mounted, around which the lever 43 provides, the turns of which can oscillate after a certain 45 102. One with the part 104 firmly compressed touch each other and the axis 106 bound by the bond is under the action of the spring movable armature of the electromagnet developed 100 on the upper edge of a part 102 attached Transfer force directly to the stamp. In the hole 107 at, making the approach of the hangers The spring 43 can also make sense to act 101 and 103 under the action of the spring 100 take appropriate form. 50 is limited. The part 104 is with the movable

In the arrangement shown in Fig. 2 contains borrowed armature 108 of an electromagnet 127 by means the elastic organ is a compression spring. In the following a pull rod or bracket 109 connected to the 5 to 8, the elastic members work as articulated at their ends on axles 110 and 111 Tension springs. is stored.

5 shows a punch 80 with a 55. If the electromagnet 127 is excited, it is supported Collar 81, which on a fixed guide plate 82 of the punch 112 against the card 113 to be punched, the rests. A return spring 83 is retained between the lever 102 and the part Collar 81 of the punch and a fixed upper guide 104 pivot further about the axis 105. The axis rugs rail 84 clamped. A lever 86, which by 106 leaves the top of the hole 107 while an axis 87 can swing, the spring 100 is supported with a 60 end by the movement of the part 104 on the head 85 of the stamp. Two pull tabs are stretched, at which they are in the recess 103 with or connecting rods 88 a and 88 & (Fig. 6) are geum on the lever 86 of the upper edge 115 of the part 102 in contact an axis 89 pivotably mounted. The tabs introduce and limit the extension of the spring 100. 88 a and 88 & are in their lower part with long The force developed by the electromagnet 127 is holes 93 and 94 are provided, into which one with the loaded 65 is now directly transferred to the stamp 112, movable anchor 91 of the designed as a plunger core type in order to effect the punching. The punching up Electromagnet 92 firmly connected axis 90 a drawing carrier enables the relaxation of the engages. A tension spring 95 is on the one hand on the lever spring 100, which quickly pushes the punch 112 into the hole 86, on the other hand, allows the die 117 to protrude on the movable armature 91. If the electric hangs on it and seeks the parts 86 and 91 to 70 magnet 127 de-energized, the spring 116 leads the

Plunger 112 and the movable armature 108 of the electromagnet back into the rest position.

The arrangements shown in FIGS. 5 to 8 show schematically drives of compact design, those with remarkable operational reliability with actuating currents of relatively low power can work with very high perforation speeds.

Claims (3)

Patent claims: 1. Punch drive for devices for punching or notching recording media, in which the punch through the closing movement of the movable armature of an electromagnet is operated, characterized in that the electromagnet during the first part of the Closing movement of its armature developed energy via an elastic intermediate member on the Stamp is transmitted, the change in shape of the elastic intermediate member limiting anao beats are arranged in such a way that the starting resistance of the material to be punched against the punch movement the change in shape of the pontic initiated and then the force delivered during the further armature movement to the actual Punch is transferred to the stamp via a stop, whereupon the intermediate link is relaxes and transfers an additional movement to the stamp, which the punched out waste part drives through the punching die. 2. Apparatus according to claim 1, characterized in that the elastic intermediate member from consists of a compression spring. 3. Apparatus according to claim 1 and 2, characterized in that the compression the stop that delimits the intermediate member by the spring coils themselves is formed when these butt against each other. Considered publications:
German Patent Nos. 764 086, 814 468;
U.S. Patent Nos. 1,767,725, 2,405,396. 1 sheet of drawings & 009 570/218 8.60