EP0188672A1 - Matrix printing head - Google Patents

Abstract

1. Matrix printer head having several printing needles (10) which are movable, each by means of a separate magnetic drive, forward into the printing position and back, and are secured on an element (26) of the magnetic drive which transmits the movements, where the magnetic drive element (26) within the fastening region (27) has in each case a width (28) which permits the arrangement of a passage opening (30) situated centrally in the fastening region (27) of the magnetic drive element (26), the basic cross-sectional form (31) of which opening conforms at least with a part of the circumference (32) of the utilised and soft- or hard-soldered printing needles (10), taking consideration of an appropriate production tolerance, characterised in that the straight axis (33) of the passage opening (30) extends obliquely of the surface plane (35) of the magnetic drive element (26), further in that the production tolerance of the passage opening (30) renders possible easy introduction of the printing needles (10) and their making fast in the direction and in that the printing needles (10) are soldered within the occurring gap in the passage opening (30).

Description

The invention relates to a matrix print head with a plurality of printing needles, each of which can be moved forwards and backwards in the printing position by means of a separate magnetic drive, and which are attached to an element of the magnetic drive that transmits the movements.

Such matrix printheads are manufactured in series and cell printer type. The operation is aimed at the highest possible number of prints of individual dot printing elements. Serial matrix printers already achieve a writing performance of approx. 400 characters / sec and line printers of up to 900 characters / sec. In accordance with these writing capacities, matrix character printers are subject to thermal and wear-related stress. The service life and any downtime of the matrix printers are, however, decisive features for the user; select a matrix printer.

In addition to the problems of the electrical or electronic part of a matrix printer, mechanical problems must also be taken into account. For example, the attachment of the pressure element, i.e. a printing pin is still not solved satisfactorily.

A distinction is made between the fastening of the printing needles in two well-known types.

A first type of construction likewise uses the principle of the motion-transmitting magnetic drive element, but preferably only a kinematic coupling by frictional connection between the magnetic drive element (for example a hinged armature) and a separate pressure needle to which a head is attached. During the transmission of force, the head of the printing needle lies against a flat surface of the magnetic drive element. However, this first type only follows because of the mass inequality of the pressure needle with the pressure needle head on the one hand and the mass of the hinged anchor on the other heavy the frequency of the magnetic drive. Vibration problems and control problems are therefore associated with the first type (such an example is the subject of US Pat. No. 4,478,528).

A second type avoids the problems of the first type in that the pressure needles are each attached directly and rigidly to the front end of the magnetic drive element. The print needle thus necessarily follows the control of the matrix printer electronics. This second type (an example can be seen from DE-OS 26 30 931) is difficult to master in terms of production technology. The attachment of the printing needle requires special auxiliary devices, but there is still the risk that the alignment and arrangement of the printing needles is inadequate due to the tolerance of the auxiliary devices being too great. Another disadvantage of the known fastening is the extremely important connection of the pressure needles to the magnetic drive element, which occurs under the influence of heat during soft or hard soldering. In extreme cases, the heating of the printing needles during inductive soldering can lead to the printing needle breaking after a relatively short operating time of the matrix printer. The reason for this is a structural change in the material of the pressure needles either during the heating or during the subsequent cooling.

The invention is therefore based on the object of attaching a pressure element, i.e. a push pin to improve, and to reinforce.

The object is achieved according to the invention in that the fastening consists of a magnetic drive element which has a width within the fastening area which corresponds at least to the simplicity of the thickness of the printing needles and from a center in the fastening area of the magnetic drive element. Element located passage opening, the basic cross-sectional shape of which corresponds at least to part of the circumference of the pressure needles used, taking into account a corresponding manufacturing tolerance. The minimum width of the magnetic drive element ensures the arrangement of a passage opening. The passage opening itself ensures the least possible effort to position the pressure needle during assembly. The accuracy of the position is particularly advantageous here. In addition, the printing needle is not excessively weakened in its material strength when it is necessary to heat it, since the surrounding material of the magnetic drive element ensures slow heat dissipation.

In a further development of the invention it is provided that the passage opening consists of a circular hole made by means of laser beams with a minimum diameter of 0.2 mm to a maximum of 0.4 mm. The position of the individual printing needles is fixed with high accuracy solely through this bore.

The invention now enables the pressure needles to be soldered or brazed in the passage opening.

Another improvement of the invention is that the axis of the passage opening extends obliquely to the surface plane of the magnetic drive element. This measure advantageously serves to create a smooth transition curve from attachment outside the central axis in the direction of one or more superposed printing needles to printing needle gaps in the case of longer printing needles.

Another improvement is that the passage opening is formed in the form of a slot running from the front or to the side with a width which corresponds to the thickness of the pressure needles which can be inserted from the front or from the side, taking into account a corresponding manufacturing tolerance for the slot and / or the pressure needle dimension. In contrast to the axial insertion with a closed circular bore, the pressure needle can easily be inserted laterally. In this embodiment, the printing needles are fixed by filling the slot with soft or hard solder.

• Fig. 1 einen Matrixdruckkopf der vorgespannten Bauart halb Schnitt, halb Ansicht,
• Fig. 2 den Matrixdruckkopf gemäß Fig. 1 in Ansicht auf die Druckelemente mit mehreren Teilschnitten in aufeinanderfolgenden Ebenen des Querschnittes gemäß Fig. 1:
  • Schnitt I in der Schnittebene gemäß Fig. 1,
  • Schnitt II in der Schnittebene gemäß Fig. 1,
  • Schnitt III in der Schnittebene gemäß Fig. 1,
  • Schnitt IV in der Schnittebene gemäß Fig. 1.
• Fig. 3 eine Vorderansicht einer Drucknadel-Befestigung nach dem Stand der Technik,
• Fig. 4 ein Mittenschnitt gemäß dem Schnittverlauf Y - Y in Fig. 3,
• Fig. 5 eine Vorderansicht der erfindungsgemäßen Befestigung einer Drucknadel an einem Magnetantriebs-Element und
• Fig. 6 einen Schnitt VI - VI gemäß Fig. 5.

An embodiment of the invention is shown in the drawing and will be described in more detail below. Show it:

• 1 is a matrix printhead of the pretensioned type half section, half view,
• 2 shows the matrix print head according to FIG. 1 in a view of the printing elements with several partial cuts in successive planes of the cross section according to FIG. 1:
  • Section I in the sectional plane according to FIG. 1,
  • Section II in the sectional plane according to FIG. 1,
  • Section III in the sectional plane according to FIG. 1,
  • Section IV in the sectional plane according to FIG. 1.
• 3 is a front view of a printing pin attachment according to the prior art,
• 4 shows a central section according to the section Y - Y in FIG. 3,
• Fig. 5 is a front view of the attachment of a printing needle according to the invention on a magnetic drive element and
• 6 shows a section VI - VI according to FIG. 5.

FIGS. 1 and 2 serve to explain the functions of a (serial) matrix printhead as an example in order to precede the interaction of an armature assembly with other function groups within the overall matrix printhead of the description of the manufacturing process of the armature components.

The serial matrix print head shown in the drawing has an electromagnetic coil assembly 1, which consists of a magnetic flux guide plate 2, magnetic pole cores 3 fastened to it with electromagnetic coils 4 and a permanent magnet plate 5. The electromagnetic coil assembly 1 is opposite an armature assembly 6, which consists of an armature ring 7, (in the drawing) to the left and to the right according to FIG. 1 armature arms 8, the armature arms 8 each by means of relatively short spring arms 9 with the Anchor ring 7 are connected. The number of magnetic pole cores 3 of the electromagnetic coils 4, the armature arms 8 and the spring arms 9 corresponds, as usual, to the number of pressure elements 10, which in the exemplary embodiment are designed as relatively long pressure needles and are stored in a mouthpiece 11. In the present exemplary embodiment, there are 2 x 12 = 24 pressure elements within the electrically or magnetically non-conductive housing 12, which is composed of the two housing parts 12a and 12b and is held together by means of screws 13 distributed over the housing circumference.

The pressure elements 10 are guided around the pressure path (approx. 0.3 to 0.6 mm) essentially axially movable in a guide housing 14 in bearings 15. Supplements 17 are located between the housing 12 and the guide housing 14 in order to determine the exit length of the pressure elements 10 from the guide housing 14 and also to be able to change them later. The guide housing 14 serves at the same time for fastening the matrix print head on a carriage (not shown) or the like, which is moved back and forth in front of a pressure abutment. A flange 14a and at least two dowel pins 14b are provided for fastening.

Current is applied to the electromagnetic coils 4 by connection to a character generator (not shown further), which is located on a circuit board circuit, by means of plug connections 18 and 19.

An uncritical, parasitic air gap 20 is provided, the size of which, with the slightest deviations, can have a negative influence on the magnetic flux density and thus on the energy transmission and the buildup and breakdown of the electromagnetic fields or the permanent magnetic fields. The air gap 20 is not critical if the air in the gap 20 is optimally magnetized. Such an optimal magnetization of the air gap 20 is present when the air gap is dimensioned so large that on the one hand no tight tolerances for the manufacture of the anchor ring 7 or the anchor arms 8 have to be required and on the other hand the field line density is indeed large enough to accommodate the pretensioning force the spring arms 9. to keep the balance, but on the other hand is not too high to hinder a rapid degradation of the permanent magnetic field when the electromagnetic coils 4 are switched on. This practically ideal case can be realized by the fastening according to the invention as described below. An intermediate plate 24 arranged between the magnetic flux guide plate 2 and the armature ring 7 forms with its end face 24a a uniform plane 25 (FIG. 2), the armature ring 7 resting against the intermediate plate 24 in this plane 25 when housing parts 12a and 12b are connected.

The armature arms 8 lie in the retracted position (as shown in FIG. 1) at a slight angle to the plane 25 and rest on the associated magnetic pole cores 3. Here, the thickness of the anchor ring 7 corresponds approximately to the thickness of the anchor arms 8, including the relatively small thickness of the spring arms 9, which are connected to the anchor arms 8 and the anchor ring 7. The very short spring arm 9 receives a shortened clamping length through a gradation 7a, so that the remaining anchor ring surface 7b is available for the connection. The gradation 7a additionally provides freedom of bending for the armature arm 8. The gradation 7a may represent a continuation of the air gap 20.

However, it is possible to make the short spring arms 9 of antimagnetic material, e.g. Chromium-nickel steel, so that no magnetic field lines can run over the spring arms 9 or over the space of the gradation 7a.

A further limitation of stray fluxes or a concentration of the magnetic field lines is carried out by the magnetic flux guide plate 2, which ends opposite the side of the pressure elements 10 approximately at the level of the magnetic pole cores 3.

According to the prior art, the printing needles 10 (FIGS. 3 and 4) are attached directly and rigidly to the magnetic drive element 26 (these correspond to the armature arms 8) with their circumference 10a by means of soft or hard soldering 27. This attachment has proven to be disadvantageous as described.

According to the invention (FIGS. 5 and 6), a magnetic drive element 26 is used, which has a fastening region 27 with a width 28 which corresponds at least to the simple thickness 29 (diameter) of the printing needle 10. In the middle of the fastening area 27, a passage opening 30 is provided with a cross-sectional shape adapted to the respective basic cross-sectional shape 31 (circle, rectangle, square) of the printing needle 10 while observing a corresponding manufacturing tolerance. The cross-sectional shape 31 is present on at least part of the circumference 32, so that the pressure needle 10 is fixed. The exemplary embodiment shows a passage opening 30 made of a circular bore from a minimum of 0.2 mm to a maximum of 0.4 mm, for example one with a circular cross cut printing needle 10 of 0.36 mm in diameter can be easily inserted and a gap can be filled with hard or soft solder.

The axis 33 of the printing needle 10 or the passage opening 30 extends at an angle 34 to the surface plane 35 of the magnetic drive element 26.

An alternative embodiment of the fastening can now consist (FIG. 5) in that the passage opening 30 is formed in the form of a slot 36 which is worked in laterally (or from the front) and has a width; which corresponds to the thickness (diameter) 29 of the printing needle 10, so that the printing needle 10 can be inserted laterally (or from the front). The slot 36 is closed with soft or hard solder after the insertion of the pressure needle 10. The alternative fastening also ensures a precise position by the pressure needle 10 resting with its part of the circumference 32 on the wall of the passage opening 30.

Claims (5)

1. matrix printhead with a plurality of printing needles which can be moved forwards and backwards in the printing position by means of a separate magnetic drive and are attached to an element of the magnetic drive which transmits the movements,
characterized,
that the fastening consists of a magnetic drive element (26) which has a width (28) within the fastening region (27) which corresponds at least to the simple thickness (29) of the printing needles (10) and from a center in the fastening region (27 ) of the magnetic drive element (26) located passage opening (30), the basic cross-sectional shape (31) of which corresponds at least to part of the circumference (32) of the pressure needles (10) used, taking into account a corresponding Hertell tolerance. 2. matrix print head according to claim 1,
characterized,
that the passage opening (30) consists of a circular bore made by laser beams with a minimum diameter of 0.2 mm to a maximum of 0.4 mm. 3. matrix print head according to one or both of claims 1 and 2,
characterized,
that the printing needles (10) in the passage opening (30) are soldered or brazed. 4. matrix print head according to claims 1 to 3,
characterized,
that the axis (33) of the passage opening (30) extends obliquely to the surface plane (35) of the magnetic drive element (26). 5. matrix print head according to one or more of claims 1 to 4,
characterized,
that the passage opening (30) is formed in the form of a slot (36) running from the front or to the side with a width which corresponds to the thickness (29) of the printing needles (10) which can be inserted from the front or from the side, taking into account a corresponding manufacturing tolerance for the slot ( 36) and / or the pressure needle dimension.

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