DE2827758A1 - Serial printer type head - has variable thickness type fingers with set spacing from hammer to avoid ribbon damage - Google Patents

Abstract

The serial printer employing type element fingers simplifies the control of hammer impact force to match the length of the imprint character. This avoids damage to ribbon and to document if the same force is applied when printing such characters as M or a comma. Instead of complex electronic control varying the impact force for each character, the type fingers are made of different thickness to maintain a constant spacing between the impact surface of the type finger and the hammer. The printing hammer (2) operates then with a constant force against the type elements (3) of the printing head. The imprint force controlling factor is included in the elements (3) by leaving the impacted side at a constant distance from the printing plane.

Description

Type-finger-afflicted type carrier for

Mail merge " The invention relates to a type finger affected Type carrier for serial printing units, which actuated a print hammer on the 'ìypanfingers Type elements and its printed characters on a recording medium Generate dyps imprint.

Type carrier for serial printing units in badminton and disk design are known from DT-OS 19 05 226, 20 26 004, 21 59 261. These type carriers are arranged on a print carriage movable along the print line, and by motors the type to be printed is set.

After the type has been set, in start-stop operation working printing units stopping the printing carriage at the corresponding printing point. At the same time, the print hammer is activated. This meets the guy arm the type to be printed on, whereby the 'l'ype against an ink ribbon and a recording medium is pressed and an imprint is produced on the recording medium.

Once the impression has been made flat, the print hammer returns to its starting position back, the print carriage is moved to the next printing point, and a re-setting of the type carrier for the new type to be printed. With these known printing units is independent of the types to be printed with the same Impact force of the print hammer generates the print image on the recording medium. As a result, it happens that the small-area characters puncture the recording medium and it cannot be ruled out that the type to be printed may be severed of the record carrier. In order to eliminate these disadvantages, were already known solutions from the DT-OS 25 29 310 and 25 45 311 to achieve a uniform print image gives the pressure hammer a variable pressure hammer impact force convey. In the DT-OS 25 29 310, the print hammer impact force is set by the hammer intensity information section of the memory for each selected type. The memory has two Information sections. The first information section is used to control the setting of the type wheel before printing the type to be selected, during the second information section of the memory is used to determine the hammer strike intensity during printing of the the selected type. Those contained in the two parts of the store Information is section-wise, controlled by a SELECTION signal, from the memory had read. After the position of the sign to be printed on the first half of the memory has been read, the hammer intensity character is read. This Hammer intensity sign is transmitted via a data line in connection with the £ DSCHLAG control signal, generated in the timing unit, via the hammer drive to the print hammer electromagnet The control of the printing hammer for type disc printing units known from D2-OS 25 45 311 realizes a more or less strong impact of the hammer on the selected one Type as a function of the amplitude of that supplied by the light-sensitive detector and signal determined by the selected type. Due to the identification features, contained in the type bars of the type disc, it is possible to use the The signal supplied by the detector shows the force of the print hammer on the surface of the print To adapt the character. The identifier, an opening in the ypensteg or the different widths of the type webs can be recorded detected as additional information and as a control signal to control the velocity of the print hammer used. A disadvantage of these arrangements for generating a variable print hammer impact force is the fact that the the variable print hammer impact force characterizing intensity levels in the encryption of the printed characters or as Identification features must be included on the type bars of the type disk.

Both options shown require a considerable electronic Additional effort regarding the control of the print hammer. Besides this higher tax expense will also depending on the number of intensity levels of the print hammer for the encryption the information requires several storage locations per print character. Another The disadvantage is that due to the permanently assigned memory locations accordingly of the type elements of the type carrier an interchangeability of the type carrier for one others with a different print mark assignment cannot be made without additional changes to the Logic is given, since the intensity allocation recorded in the memory does not match corresponds to the print character assignment of another alphabet.

The aim of the invention is to provide a special print hammer control to avoid for type carrier, so that on a high electronic control effort can be dispensed with, no storage capacity for the individual printed characters assigned intensity levels is required and special identity features the type bars of the type carrier are not necessary for electronic evaluation.

The invention has the task of providing a type finger To create type carrier for serial printing works, the type elements of which from a print hammer can be operated with constant print hammer impact force and to achieve of a print image with a constant print intensity on the recording medium Depending on the length of the contour of the print mark, one of type fingers to Type fingers have different designs, according to the invention the task is solved in that the type finger depending on the print character contour length have different thicknesses at least in the area of the type element, that the type elements arranged on the type carrier either with their printed drawing area or have a common reference line with their print hammer impact surface and that between print hammer and print plane independent, v; Thickness of the type elements a constant distance in which the type elements having a different thickness are brought into printing position is provided. Further features of the invention Solution are that to compensate for different angles of deflection the printing characters with maximum contour length differences are height-corrected the type elements are located and that with type carriers with several Wype levels a type finger print mark of the same contour length arranged on a type element and that the type fingers are uniform over the entire area of the type elements Own thickness. Furthermore, a feature of the invention is to be seen in the fact that in the case of type carriers whose type elements have a common with their print contact surface Form reference line, printed characters with a large on type elements that are thickened Contour length are located and that a graduated decrease in thickness of the type elements is proportional for a reduction in the length of the contours or that, in the case of jl1ypentlmgern, whose type elements form a common reference line with their pressure oak surface, printed characters with a shorter contour length on thickened type elements and that a gradual decrease in thickness of the type elements is inversely proportional to an increase in contour length is provided, for the advantageous embodiment of the The solution according to the invention is furthermore provided with the feature that the print character contour lengths are grouped together and that each group of printed characters has a specific one Type element thickness is assigned.

D1 of the drawing belonging to the exemplary embodiment show: Fig. 1: a partial representation of a type carrier; FIG. 2a: a basic representation of the type elements with a common reference line on the print hammer impact surface Fig 2b: Contour length groups using the example of the Latin alphabet according to Pig. 2a Fig. 3: a graphical representation of the course of the curve according to the arrangement according to FIG. 2a, FIG. 4a: a schematic representation of the type element with a common reference line on the Printing drawing area Fig. 4b: Contour length groups using the example of the Latin alphabet according to FIG. 4a FIG. 5: a graphic representation of the curve profile according to the arrangement according to Fig. 4a Fig. 6: a basic representation of the occurring height offset Die Figures belonging to the embodiment show possibilities of training the type carrier 1 for serial printing units that allow the print hammer 2 with constant control energy works. The type elements actuated by print hammer 2 3 of the type carriers 1 formed according to this invention produce an imprint of the respective print marks 4 on the recording medium 5 of uniform intensity regardless of whether it is a print character 4 with a large or small contour length The information for the contour lengths of the respective printed characters is 4 integrated in the formation of the type elements 3 itself. The print hammer 2 is next to the application of constant control energy for the creation of an imprint any print mark 4 of a type carrier 1 at a constant distance 6 removed from printing level 7.

Achieving a uniform print intensity is important for the printed characters 4 different contour lengths, for example with the printed characters 4 tIsII 'and "," achieved by the fact that in the type carrier 1, the printing characters 4 on type elements 3 carry type fingers 8, type fingers 8 different in the area of type elements 3 are made thick. Due to the different thicknesses of the type elements 3 results according to the embodiment of the 2npentragers 1 shown in Fig. 2a with a common reference line 9 on the print hammer impact surface 10 a mutually different path a; b of the type elements 3 until the Print drawing area ii on the recording medium 5. The print hammer 2 is located according to this arrangement at a defined distance 12 from the print hammer impact surface 10. The qualitative course of the print hammer control pulse is shown in FIG the curve 14 with a control time ti to cover the distance b, the the thickest type element 3 up to the imprint on the recording medium 5 must cover, shown. After this print hammer control pulse arises the path shown in curve 16 and the characteristic for all type elements 3 and the energy curve shown in the further curve 17.

The type elements 3 of a type carrier shown in FIGS. 1 and 2a 1 with a common reference line 9 on the print hammer impact surface 10 give up extreme values for the contour length contained in the yp carrier 1, for example The formation of the type elements 3 in the printed characters 4 "M" and ",", thus clarify the curves 16; 17 the route of all type elements 3 up to the imprint and the Energy ratios when imprinting the extremes between the length of the contour and according to FIG. 2b printed characters 4 divided into contour length groups 20, The impression energy of the type elements in between is reduced compared to that the printing characters 4 with the largest contour lengths, which according to this example the thickest type elements 3 are arranged. The imprint energy is therefore up to a smaller amount in each case for the printed characters 4 with the smallest contour lengths required to generate a uniform print image on the recording medium 5, although the distance 12 of the print hammer 2 to the print hammer impact surface 10 is constant remain. The imprint energy required to generate the imprint for the imprint 4 is required with a small contour length and has to cover the distance a, is thus an amount 15 less.

According to the example shown in Fig. 4a for the formation of the type carrier 1 with a common reference line 19 on the printing mark area 11 are the Pressure oak surfaces 11 of the type elements 3 at a constant distance that the Distance d corresponds to printing level 7.

The print hammer 2 is also activated with an analog print hammer control pulse applied, so that the qualitative shown in FIG Course of curve 21 of the print hammer control pulse results.

The print hammer 2 is located in the before each print hammer release constant distance 6 to printing plane 7.

To achieve a uniform print image on the recording medium 5 are the distances between the print hammer 2 and the individual print hammer impact surfaces 22; 23 of the two type elements 3 shown are different. As in the above Example is for the print hammer impact surface 23 of the thickest Type element 3.

A distance 12 is also provided for the print hammer 2.

Opposite this print hammer impact surface 23 the print hammer has 2 due to the difference in thickness between the type elements 3 and the print hammer impact surface 22 of the thin type element 3 to cover an additional distance c. After this training of the type carrier 1 for the individual type elements 3 setting course for covering the distance d or in addition to the Distance c to the imprint is shown in curve 24 in Sig, 5, where the The energy ratios existing during the printout are also derived from the one shown in this Fig.

shown curve 25 emerge. After that, achieved that.

the thickest type element 3, which has the printing character 4 with the smallest contour length carries the printing plane 7 after covering the distance d at the point in time at which the maximum energy has not yet become effective, d, h, is less by the amount 18 shown. The print mark 4 with the greatest contour length is on the other hand on the type element 3 with the lowest Thickness. When printing, the additional distance c is covered for the print hammer 2 on this type element 3, the maximum pressure energy is effective. The remaining print marks 4 are, as shown in Fig. 4a, according to their contour length in individual Contour length groups 20 divided. For each contour length group 20 there is a specific one Thickness of the type element 3 set so that between the extreme values located contour length groups 20 of the type elements 3 from the print hammer impact surface 22; 23 to the print hammer 2 each a stepped distance c Fig. 4b for the print hammer 2 results. The imprint produced on the recording medium 5 is thereby also after this embodiment of the type carrier 1 for the printed characters 4 with a small contour length as well as for those with a long contour length of uniform intensity.

The solution according to the invention requires different with regard to the thick type elements 3 for the design of the subsequently designed type carrier 1 the observation of the occurring and characteristic for each contour length group 20 Countersink angle 26.

The individual printed characters 4 must therefore correspond to the deflection angle 26 of the associated contour length group 20-height-corrected on the type elements 3 and thus be provided on the type fingers 8 of the type carrier 1.

The embodiments shown in the figures relate to Design of the type elements 3 of type carriers 1, which in their scope in a Type level 27 carry the print mark 4. However, the idea of the invention allows also its use in type carriers 1, the printed characters in several type levels 27 4 wear, To achieve a uniform print intensity of the printed characters 4 Type carrier 1 formed in this way on the recording medium 5 are on the Type element 3 a type finger 8 each with printing characters 4 arranged with the same contour length, the type finger 8 is therefore above the sansen The area of its type arrangement is thickened, the curves 16; 24; 17; 25; 14; 21 for the distance covered by the type learner 3, for the ones that occur Energy ratios as well as for the print hammer control pulse correspond to those in Fig. 3 and 5 graphs shown.

The embodiment of the type elements 3 shown in FIG. 2a is technological Particularly advantageous for use with cylindrically shaped and with individual type fingers 8 afflicted type carriers 1 suitable. The print hammer face 10 of the individual type elements 3 forms a common reference line 9 (Fig. 1) and allows, thanks to this constant inner radius 13, an advantageous tool design.

In addition, when individual printing characters 4 are exchanged, only minimal ones occur Tool changes. The construction volume for the use of the drive magnet for the print hammer 2 in the interior of the cylindrical type carrier 1 remains through this constant inner radius 13 maximum.

For the other type carrier forms, both the aforementioned training 2a as well as the design of the type carrier shown in principle in FIG. 4a 1, although the one shown in FIG. 4a for the formation of type disks Embodiment of the design of the type elements 3 is particularly advantageous Integration of the intensity levels required for a uniform print image in the formation of the type elements 3 and thus in the formation of the type carrier 1 has the advantage that it is based on the otherwise customary electronic special construction levels for intensity control can be dispensed with. In addition, the trained in this way offers Type carrier 1 the possibility of a simple and uncomplicated exchange of such Type carrier 1 with each other provide for either other alphabets or are assigned special characters. With this inventive training of the type carrier 1 is therefore no encryption of the intensity level for each Print mark 4 more necessary. The electronic as well as the storage effort, the otherwise necessary for the encryption of the intensity levels for the print mark 4 is is done by setting the intensity level of voznulerein in the design the type elements 3 of the type carrier 1 completely excluded.

Claims (4)

Claims 1. Type-finger-afflicted type carrier for serial printing units, who carries pressure hammer operated 'i' type elements on individual type fingers and its Print characters have different contour lengths, characterized in that that the individual type fingers (8) depending on the contour length of the the print characters contained in the type elements (3) at least in the area of the type element (3) have different thicknesses that the on the individual 'ypenfingern (8) the type elements (3) arranged on the type carrier (1) either with their printed drawing area (11) or a common reference line with its print hammer impact surface (10) (9; 19) and that between print hammer (2) and printing plane (7) regardless of the thickness of the type elements (3) a constant distance (6) in which the one different Thick type elements (3) are brought into printing position, provided is. 2, type carrier according to claim 1, characterized in that to Compensation of different deflection angles (26) the print characters (4) with maximum Contour length differences are height-corrected on the type elements (3). 3. Type carrier according to claim 1, characterized in that with type carriers (1) with several type levels (27) on a single type finger (8) print mark (4) the same contour length are arranged on a type element (3) and that the Type elements (3) of a type finger (8) have a uniform thickness. 4. Type carrier according to claim 1 to 3, characterized in that in the case of type carriers (1), their type element (3) with their print hammer impact surface (10) form a common reference line (9) on thickened type elements (3) Print mark (4) with large contour length and that e * Ine Graduated decrease in thickness of the type elements (3) proportional to a decrease in contour length is provided. 5, type carrier according to claim 1 to 3, characterized in that in the case of type carriers (1), their type elements (3) with their printed drawing area (ii) Form a common reference line (19) on thickened type elements (3) Print characters (4) are located with a smaller contour length and that a graduated one The decrease in thickness of the type elements (3) is inversely proportional to an increase in the length of the contour is provided. 6, type carrier according to claim 1 to 5, characterized in that the printing characters (4) are summarized in contour length groups (20) and that each Contour length group (20) of the printing characters (4) a certain type element thickness assigned.