DE169105C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

In the previously known machines for casting and setting movable letters, which are put into action with the help of register strips, in particular for those at those, in the course of the work for the purpose of making a letter, the matrices be withdrawn from their guide pieces to be immobile during the casting process to be pressed against the mold while its guide pieces are still free to move to continue, it was previously not possible to use the same matrix to write the usual script and also a second font, for example bold, barred or crooked horizontal font, and thus create a mixed sentence.

The present invention relates to a device with the help of which, without the number of Perforations (or combinations of perforations) of the register strip to increase or the number of dies and as a result to increase the number of the same supporting arms, it is possible, in addition to the common script (Kurrent script) to set a second type of font, a so-called distinctive or barren script. This second type of font can be whatever the shape and thickness of each letter as far as is concerned, be completely independent of the first font. As is well known, this could by the previously known machines used to generate different fonts, for example on the Linotype, cannot be achieved because with these machines the thickness (width) of the types through the thickness of the matrices supporting the hollow shape of the type images was limited. It so the two fonts always had to have the same width, a condition which, if fulfilled, had a detrimental effect on the beauty of the sentence.

The device of the new type is shown in the accompanying drawings. In this is:

Fig. Ι a side view of the overall arrangement of the device,

FIG. 2 is a plan view of the arrangement shown in FIG. 1, in conjunction with some parts of the casting and setting machine for movable letters. She shows by name the carriage of the arms carrying the die and the square mandrel which the Takes up the die during casting,

Fig. 3 is a plan view of the part of the device, which the transition from a Font after another allows.

Fig. 4 shows part of the parts shown in Fig. 3 in a different working position.

Fig. 5 is a plan view of the portion of the device which is used for each font Font of different letters, small letters, large letters or punctuations, brings forth

Fig. 6 is a side view of part of the arrangement shown in Fig. 5,

7 is a view of an inclined surface arranged under the carriage.

Fig. 8 shows a plan view of the arrangement of the coupling between the square The mandrel and the shaft that sets it in rotation.

Fig. 9 is a front view of the entire device.

Fig. 10 shows certain parts of Fig. 9 in the position they assume as soon as one of the electromagnets has been energized.

11 is a side view of some of the

Fig. 10 visible parts,

Fig. 12 is a plan view of the same,
13 is a diagrammatic representation of a die showing six casting mold bottoms,

14 shows a section through the axis of the square hole of the die.

Fig. 15 shows part of a register strip in the event that the distinctive script begins and ends within a line.

Fig. 16 shows the part of the register strip in the case that the distinguishing writing begins and ends with the line.

FIG. 17 shows a schematic representation of the current flow, insofar as it comes into consideration in the operation of the present device. The dies 11 (Figs. 1, 2 and 9) are carried in a known manner by arms 12 of a carriage 13 which receives a reciprocating movement. These matrices are pushed out of the slide under the influence of the perforations in the register strip and, whenever they are to be used for the production of a casting, reach the square mandrel 14 (FIGS. 1 and 2) due to the square hole 15 (Fig. 14). These matrices (FIGS. 13 and 14) have six different characters on one half of their circumference, for example a, A, i, in the current script on the upper quadrant and the same characters in the distinctive script (italic script) on the lower quadrant . This arrangement makes it possible to obtain six different characters using only a single combination of perforations for each die, if one of the six partial rotations which are suitable for this purpose is communicated each time to this die prior to casting using suitable means to bring the desired casting mold bottom onto the casting mold.
The device, which brings about the correct position of the die before casting, is driven by the register strip by means of three electromagnets 16, 17 and 18 (FIGS. 1, 9 and 10) which are arranged in a frame. The armature 20 of the electromagnet 16 sets, as soon as it is attracted by the electromagnet, a lever system 21, 22 in action such that the lever system in question is pushed upwards (FIGS. 9 and 10). At this moment, a projection 23 of the arm 22 lies under the influence of the spring 24 on the upper side of the housing 19, so that when the excitation of the magnet ceases and the armature falls back into its rest position, the arm 22 is in its upper position remains. The electromagnets 17 and 18 each influence a similar lever system, which can be seen from FIG. 2 and which consists of the levers 25 and 26 with the stops 27 and 28.

The carriage 13 (Fig. 2 and 9) receives a back on the prismatic slide rod 29 and reciprocation, as is already known from electrotypograph typesetting machines. Of the The carriage, which carries the arms 12 and the die 11, also has a curve thrust 30, which is equipped with a projection 31 in the shape of an inclined surface.

Assume that the carriage 13 is in the direction indicated by an arrow in FIG. 2 moved, and one of the electromagnets 16, 17, 18 had been struck in advance, so so that one of the corresponding lever arms 22, 25 or 26, as FIG. 10 indicates, in the upper position. This arm is therefore initially driven by the curve thrust 30 pushed to the left, shortly thereafter, however, as soon as the inclined surface 31 against the approach of the arm 22 meets, the latter is pushed down into the normal position, such that it is lifted again by the electromagnet during the subsequent stroke of the slide can be, d. H. that he can come into action again. Arms 25 and 26 perform the same movements insofar as they. through their associated electromagnets in the Area of the curve thrust 30 are brought.

Above the frame 19 and in the path of the arms 22, 25 and 26 lie three one above the other Lever, namely below the lever 33, in the middle of the lever 34 and above the lever 35 (Fig. Ι and 2).

The two levers 33 and 34 are respectively on their associated axes 36. 37 attached (Fig. 5). These two shafts 36 and 37 are concentric and are in the Frame 19 stored in a suitable manner. The two arms 38 are at their lower end and 39 (FIGS. 1 and 5) which are hinged to the rods 40 and 41. These Rods are at their other end with long, upright pins 42 and 43 equipped (Fig. 5, 6 and 9). These pins engage in notches made in washers 46 and 47 are arranged.

These disks can rotate around a pivot screw 48 which is mounted on the shaft 49

is attached (Fig. ι). The latter shaft is mounted in the frame 19 and ends in her upper parts in a plate 50 which carries the two disks 46 and 47 (Fig. 1 and 9).

Assume that the electromagnet 18 has lifted the arm 26 so that it can be through the Cam 30 is brought to the left and has brought the lever 33 into action, which in its path lies (Fig. 1 and 2). This assignment will then be reflected on the disk 46 transmitted through the axle 36, the arm 38, the rod 40 and the pin 42 that holds the disc rotates, which remains in its new position.

The arm 26, however, as already mentioned, is in its normal position due to the inclined surface 31 Position pushed back.

During the retreat of the slide 13, a rounding 32 of the curve thrust 30 becomes (Fig. 2, 11 and 12) the second arm 33 " of the lever 33 hit the previous movement of the lever to the right has gone; -This lever arm is pushed against the stop 51, which is the normal Determined position of the lever. As a result of this movement, the disk 46 is simultaneously in returned to its normal position (since, as already mentioned above, it was operated with the lever 33 . connected by an inevitable connection and thus their movements to Consequence).

The electromagnet 17 has the same effect onto the disc 47 through the intermediary of the lever 34.

The electromagnet 16 has another activity. As soon as the arm 22 through has been brought into his working position, the movement to the left becomes which he received by the curve thrust 30, transferred to the third lever 35, which is above him lies (Fig. 3). The end of the lever 35, which lies in the path of the arm 22, carries a Rod 52 which, on the other hand, is articulated to the end of a ratchet lever 53. This lever can rotate about a stud screw 54, which serves as an axis of rotation. The latch 55, which is located on the free end of the lever 53, engages under the action of the spring 57 into one of the eight tooth gaps of the ratchet wheel 56. The ratchet 56 is down with a square 58 connected (Fig. 1, 3 and 4) and can be on the screw bolt 54, which is screwed into the housing 19, rotate freely.

Against the square part 58 of the wheel 56 is a lever 59 from behind, the is rotatably mounted on a screw 60. The free end of the lever 59 is with a Provided pin 62, which engages in an incision 63 of a disc 64 (Fig. 3 and 4). The disk 64 can in turn rotate freely around the shaft 67 and lies on a Plate 68 which is attached to the shaft 67 (Fig. Ι and 9). The shaft 67 is in one Part of the frame 19 stored, which this serves as a storage, and can in the longitudinal direction adjusted. You can as a result of the arrangement of the screw 69 and the groove 70 does not turn. The lower part of the shaft carries a washer 71 which has two arms 72 Is provided. Feathers 73 are hooked to these, the other ends of which are in the Frame 19 place mounted screws 74; the disc 71 is on the other hand with two downwards reaching stop pins 75 equipped.

If the parts are in the position shown in FIG Rotation of one tooth of the ratchet wheel 56 of the lever 59 through an edge of the square Part 58 are repelled. In this position, the edge 61 must the lever 59 force yourself to lean against this edge. This movement has the effect that the Disc 64 is notified of a rotation of a certain deflection. The new The position is shown in FIG.

This movement is achieved during the hanging of the carriage 13 as soon as the Electromagnet 16 has been excited because then the large arm of lever 35 is under mediation the rod 52 swings the lever 53 about its axis 54 and because at this moment the pawl 55 rotates the ratchet wheel 56 about one tooth.

If the carriage 13 now executes its backward stroke, the rounding 32 must of the curve thrust 30 also bring the lever 35 into its normal position by he hits his little arm against the stop 51. This movement carries over to the lever, thus brings the pawl 55 back to the initial position, so that it is in the following The tooth gap of the ratchet wheel engages and is now ready for a further effect.

This occurs the following time the solenoid 16 is energized. The order the device shows, however, that with this second movement, the square part 58 again presents one of its flat surfaces to the lever 59, which is thus located under the Effect of his spring 76 must lay on the flat part of the square and thus also the disk 64 returns to its initial position shown in FIG.

Above the disk 64 (FIGS. 1, 2 and 9) there is a special frame yj, in which two toothed racks 78 and 79 are arranged to slide up and down in special guides. These racks are each with a claw 80 BEZW at their lower end. 81 equipped, which in a groove of the disc 64

intervention. A gear 82, \ velches on the Shaft 83 is keyed on, engages these two racks, and continues Below you can see how each of these racks act on the gear can without the other rack opposed to this rotation a resistance.

The shaft 83, which can rotate in the bearings 84 and 85, carries an adjusting washer 86, while its right end carries a washer 87 in which a diametrically extending groove 88 is arranged (FIGS. 1 and 8). A corresponding rib of an intermediate disk 89 engages in this groove, which has a corresponding rib 90 on its other surface, but which is rotated by 90 ^{° with} respect to the former. This second rib engages in a diametrically extending groove of a disk 91, which here replaces the known stop disk, which serves to cause the rotation of the square dome 92 and 14 on which the matrices slide before casting. The assembly of the parts 87, 89 and 91 form a known coupling which enables the shaft 83 to transmit a rotary movement to the square shaft 92, which at the same time can move with its base 93 parallel to the axis.

If you now move one of the racks 78 and 79 vertically, you must mediate of the gear wheel 82 of the shaft 83 and thus also the square mandrel 14 a Rotary movement are communicated. This rotation has depending on the greater or lesser The amount of rotation means that the die reaches the position suitable for casting at the time of casting. By doing one can now make this amount of oscillation larger or smaller and also reverse the direction of rotation, one can use one and the same Matrix three different characters from normal script or three other letters from distinctive or restricted script obtain.

The magnitude of the vibration imparted to the shaft 83 and consequently to the die needs to be a small letter, a capital letter or a Casting digit is determined by disks 46, 47 and 50 (Figures 1, 5 and 9); the Characters follow one another in the order just mentioned on the circumference of Die, started from the horizontal diameter of the normal position (Fig. 13).

As mentioned above, there are

Above and very close to these disks are two stop pins 75 on a disk 71 are attached. The disks 46 and 47 face the heads in their normal position These pins represent two incisions 44 and 45, into which the pins, without touching the discs, can occur provided the panes are lifted. ■

With every back and forth movement of the carriage 13, a crooked extension 94 brings with it the slide is connected (Fig. 9), the double-armed lever 95 for swinging, the with the mediation of the screw 96 at the appropriate moment the shaft 49 and consequently with this lifts the disks 46 and 47 so that they meet with the pins 75. The accuracy of the deflection of these movements is regulated by the stop screw 97, which is on the Lever 95 is arranged and against a hardened, inserted in the base plate of the frame Block 98 strikes. The lever 95 · is connected to the shaft 49 through the intermediary of two small rods 99 connected, which have the purpose of any rotation of the shaft 49 prevent them and inevitably return them to their starting position bring back. A spring 100 urges through the intermediary of a pen 101 the lever 95 and the shaft 49 to return to their normal position after the inclined surface 94 has slipped past.

Assume that the die is to be rotated to produce a punctuation or numeral will; in this case the register strip or the specific combination represents of the die represents a perforation in the seventh row. The particular combination initially has the effect, through the means already known, the die on the square arm 14 to come. Then the seventh perforation becomes the excitement of the magnet 18 bring forth.

The displacement of the disk 46, which, as already mentioned, must take place immediately upon passage of the curve thrust 30, will now have the effect that, as soon as the shaft 49 and the disks 46 and 47 are lifted against the stop pins 75, the latter face full parts of the disc 46 so that these pins are pushed back in the same time and with these the shaft 67 and the disc 64 go up. This disk 64, in whose circular groove, as already mentioned, the two claws 81 of the racks 78 and 79 engage, has two grooves 65 and 66 (Fig. 3 and 5), which are located such that one of these in each of the two end positions Grooves are located below one of these racks so that when you lift the shaft 67 and with it the disc 64, only a single rack is actually in connection with this disc and goes up with it, while the other rack has a free passage downwards into one of the grooves 65

or find 66. Furthermore, the rack which goes down will find a passage in one of the grooves in the plate 68 which is fastened on the shaft 67.
Depending on whether one or the other disk 47 or 46 is displaced by the influence of the associated electromagnet 17 or 18, the stop system which regulates the vertical displacement of the shaft 67 and the racks must assume different sizes. However, this again results in j different rotations of the shaft 83, ie the die 11, on the square mandrel 14. The thickness of the disks 46, 47 and the stroke of the shaft 49 are selected such that the displacement of the disk 46 causes the greater movement of the die and therefore corresponds to the type furthest from the horizontal diameter (punctuation or number). The displacement of the disk 47 corresponds to the second type (capital letter), while the disk 50 of the shaft 49 corresponds to the first type (small letter), provided that none of the disks 46 and 47 has been displaced. ■ ■

Depending on whether you use the current font or the special font (for example italics) wants to set, the electromagnet 16 causes a certain rotation of the disc 64, in such a way that this disc either one or the other rack when it goes up 78 resp. 79 takes away. However, this movement either rotates the square mandrel to the right or to the left.

In order to precisely record the position of the die types at the moment of casting, use the following facility:

The disk 86, which is firmly connected to the shaft 83, which the square mandrel 14 influenced, has six trapezoidal cuts on its circumference. 102, their everyone works with a die and is diametrically opposed to it. Furthermore is still a seventh incision 103 is arranged at the point of the horizontal diameter

(Fig. 9).
In the normal position of the dome, a pawl 104 engages in the cutout 103 and is pressed in by a spring 105; this has the effect that the mandrel is held exactly in the position which corresponds to the receiving or the dispensing of the die.

Before the moment of casting, that is to say shortly before the rotation of the dome, the pawl is withdrawn from the incision 103 through the intermediary of the arm 106 with which it is articulated. The further movement takes place through the shaft 107 and the lever 108, on which a cam thrust 109 attached to the slide 13 acts. When the mandrel rotates, a moment before the casting takes place, the cam thrust 109 ceases to act, and the pawl 104, under the action of the spring 105, enters that notch in the disc 86 which corresponds to the type to be cast - in such a way that the die must always take a precisely regulated position before casting.
After casting, during the return of the slide 13, the other end of the cam 109 acts on the part 108, etc. in the same manner as before so that the pawl 104 is withdrawn from the cut to allow the mandrel to rotate backward to its normal position allow; as soon as this is reached, the mandrel re-enters the cutout 103.

There is still ^{no need to:} Describe the current flow and show how it is used to produce the movements just described using the already known perforations of the register strip without increasing the number of perforations.

Fig. 17 shows the scheme of the current flow as far as the present invention comes into consideration. 1 'to 7' designate contact springs of the readout device, their details are known. 8 denotes a battery whose terminals, - and +, are connected to the system. 16, 17 and 18 are the Electromagnets that bring about the effects described above. The anchor of the electromagnet 17 carries a spring 110, which is isolated from it and which in the normal position against a contact in lays. As soon as the electromagnet 17 is energized, the spring 110 must be against one put another contact 112. This spring 110, which serves as a conductor, is by means of a Wire 113 connected to the spring contact 7 '.

The displacement of the dies and their setting on the square dome 14 (Fig. Ι and 2) are through the combination of the perforations 1 to 5 (Fig. 15 and 16) certainly. The perforation 7 gives, if it is added to any combination, cast a punctuation with the same die; the perforation 6 on the other hand, if added to a combination, the relevant capital letter. The perforation 3 gives, if it is used alone, a space, while if it is accompanied by two other holes 6 and 7, 'the beginning and the end of the Differential font (for example crooked font) should indicate as soon as the same should appear inside a line. This

Case is denoted by I in FIG. The perforation 1 indicates the end of the line if it occurs alone. If, however, it is accompanied by two perforations 6 and 7, it simultaneously indicates the beginning and the end of the distinctive script, provided that the latter begins and ends with the line (at I ^a in FIG. 16, for example).
The course of the currents is in both cases

ίο the same, so only the former case is described needs to be, in which the holes 6 and 7 accompanied by the holes 3 of the barrier writing immediately preceding Spatie and the space that immediately follows the last word of the barren script (Fig. 15).

Take into account that in the case of the type casting machines under consideration here, as soon as the one row of holes in the register strip comes into the readout device that electrical connections corresponding to the various perforations in this row do not occur at the same time take place, but one following the other, as a result of the order a rotating one that goes over the segment piece like I * (Fig. 17) Distributor. In the present case, compilation I (Flg. 15) must be on the register strip the third perforation come into operation first; this becomes a circuit brought out through the sixth perforation and in the last place through the seventh perforation.

The third register hole now has the effect of pushing the matrix for the spaces onto the square dome. The sixth opening closes a circuit in which the current coming from the positive pole of the battery passes through a contact cylinder located under the register strip, then through the relevant register hole into the contact spring 6 'and from here through 6 ^X to the electromagnet 17 comes, whose coil it flows through, to finally get to the negative pole of the battery.

The current cannot pass through wires 116 and 115 since the latter are connected to interrupted power lines that are only available during the Exclusively are closed and therefore have to fulfill tasks that are related to the present Invention have nothing to do with.

When the electromagnet 17 is excited, the armature 114 (FIGS. 1 and 9) is attracted, and the contact spring 110 lies against the contact screw 112.

Since in reality this contact spring is fastened with a fleece in the device, which is similar to the lever designated 21 in FIG. 9, it follows that it is so long is held against the contact screw 112 than the arm 25 (Fig. 2) in its raised Position remains.

A moment after the excitation of the electromagnet 17, the seventh closes Perforating a circuit in which! the one coming from the positive pole of the battery Current through the contact spring 7 ', further through 7 ^, 113,110, contact screw 112, electromagnet 16 flows back to the negative pole of the battery.

The armature of the electromagnet 16 is thus attracted and determines the deflection of the disc 64 such that, as described above, a reversal of the Font must arise.

By the action of the above-described curve thrust 30, the Arms, which are raised, pushed to the left, first 25 and then 22. Soon afterwards they will be pushed down through inclined plane 31.

This latter movement causes the contact spring 110 to move against the contact screw pushed in, in such a way that the perforation 6 for the following transverse row of the register strip and 7, if necessary, in their associated electromagnets 17 and 18 Send currents to bring the arms 25 and 26 into action, thus through the corresponding one The position of the discs 46 and 47 determines the type of type to be cast (capital letters or punctuation), namely in the font that has already been determined in the manner just described has been. The font will thus remain unchanged until the tab strip again presents a perforation in which the holes 6 and 7 are located at the same time, as can be seen from FIG. 15 after the oblique Italian script has ended can, whereupon a change of font takes place again, since the lever 59 from one edge of the square 58 slides off and hits a flat surface of the square.

As soon as there is a hole 7 in the strip without simultaneously meeting a hole 6, the current coming from the positive terminal of the battery will run through 7 ', y ^w , 113, 110 and in to go to the electromagnet 18 and from here to flow back to the negative pole of the battery. In this case, the electromagnet 18 must produce a swinging out of the disk 46 and consequently a regulation of the device which determines the matrices in such a way that the casting of a punctuation or a number must be prepared. In a similar way, if a hole 6 of the register strip of the reading device represents

is offered, without being accompanied by an associated hole 7, the current to flow through 6 ', x " and the electromagnet 17 in such a way that it acts on the disc 47 and brings about the setting for obtaining a capital letter.
. It follows that the present device makes it possible to bring the matrices of the various types in front of the mold for the purpose of obtaining a mixed set without increasing the number of longitudinal rows in the known register strips and the number of matrices present.

Claims (8)

Patent Claims: 1. Device for setting matrices containing different fonts in front of the mold of such setting and casting machines, which are made by means of register strips be operated, characterized in that while maintaining the number of longitudinal rows of the known The perforations (6 and 7) of that combination have been added to the register strip indicating the spaces or the end of the line in the register strip, so that at the right time electrical connections are made, with the help of which the displacement of the die is produced Transmission is controlled in such a way that one and the same die, which the different fonts divided into two groups in such a way that one group carries the lowercase and uppercase letters and the other that contains punctuation, numbers, or other characters, the mold only the notation of a group presents until the device through a repetition the same combination allows the font of the second group to come into effect. 2. Embodiment of the device according to claim 1 with a rotatable Mandrel (14), which serves as a support for the die during casting, characterized in that that this mandrel at a variable angle through the intermediary of a coupling known per se (87, 91) of the shaft (83), the gear (82) and the racks (78 and 79) is rotated, which parts their movements with each stroke of the carriage by the cam (94), lever (95) and a vertically movable drive device of variable stroke (67 to 72) of this type receive that the type belonging to a certain group of the one die present on the mandrel is at Turning exactly in front of the mold. 3. Embodiment of the device according to claim 1 and 2, characterized by two stop disks (46 and 47) lying one above the other, which with their openings (44 and 45) against two stops attached to the vertically displaceable drive device (67 to 72) (75) of the shaft (67,68) can be rotated, that the latter displacements of different angular sizes depending after the position of the discs (46 and 47). 4. embodiment of the device according to claim 1 to 3, characterized by a disc (64) with openings (65 and 66) and a circular groove equipped and can be connected to the racks (78 and 79) in such a way that it depends on the latter depending on the positions, which the openings (65 and 66) occupy with respect to the racks, lifts only one with each movement. 5. Embodiment of the device according to claim 1, characterized by Levers (33,34) and rods (40 and 41) through which the discs (46 and 47) can be rotated while the slide is hanging and back into theirs during the return of the slide Normal position are brought back, for the purpose of being pushed onto the mandrel (14) Set the die in such a way that it presents a certain type of casting position. 6. Embodiment of the device according to claim 1, characterized by the Attachment of a lever (35) which, through the intermediary of the rod (52), forms a lever (53) influenced, the pawl (55) a ratchet wheel (56) communicates a rotation that the lever (59) is transmitted by a square (58) and has the purpose of moving the disc (64) and the same to hold in its new position until the pawl (55) falls of the lever (35) is brought into its normal position, during which the .Schwigung the disc (64) is used to to connect these alternately with the racks (78 and 79) so that the die, which is in one or the other Sense is rotated, the casting point either one or the other kind of their types presents. 7. embodiment of the device according to claim i, characterized by a Device that enables the exact setting of the die and a disc (86) - which is held in place by the resilient pawl (104), which at the beginning of the setting with the mediation of attached to the slide Curve thrust (94), of the arm (io8, io6) and the shaft (107) from one The incision (103) of the disc is removed and finally by its spring (105) in the relevant incision of the disc associated with the die jumps in, while it is removed from the disc by the same parts after casting is complete and finally re-enters the incision (103) for your purpose, the to enable precise adjustment of the cathedral at the moment in which it the die receives, and the exact position of the die during casting and during its movement from Secure thorns. 8. Embodiment according to claim 1, characterized by the arrangement of a Commutator on the lever (114), with the help of which the connection of the conductor can be made such that if one of the perforations (6 or 7) alone the combination of holes in the register strip representing a type, by means of which the rotation of the die is caused, which in turn either determines a punctuation with the intermediation of (7) or a capital letter with the intermediation of (6), and that, provided both holes (6 and 7) together with a ßpatienloch or one which determines the end of the line or, provided that they alone both appear at the same time on the register strip, the coupling of a device is accomplished, which brings about the reversal of the two fonts, which are arranged in two groups on each die. For this purpose 2 sheets of drawings.