DE1295419B - Print mechanism with a push pin and a guide sleeve - Google Patents

Description

The invention relates to a printing mechanism consisting of a displaceable, one-piece pressure pin in a one-piece guide sleeve and from a transverse guide groove in the 'one part and a heart-shaped longitudinal guide groove in the other part a recess for inserting a locking body for the two through the longitudinal guide groove certain locking positions.

In such a printing mechanism, the pressure pin is in two end positions can be latched by the locking body, the position of the particular spring-loaded pressure pin in relation to the guide sleeve in the end positions. The depth of the in itself opposite surfaces of the two parts located grooves corresponds approximately to that Radius of the locking body. By pressing the pressure pin, which is opposite to the Spring load is exerted, the locking body passes from one to the other Locking position. This end position is then retained as soon as the pressure is applied to the Push pin is omitted. Such printing mechanisms are used in particular in ballpoint pens to fix the writing leads in the locking positions.

In such printing mechanisms, the pressure pin or the guide sleeve carries a separate part serving as a stop which is only activated after the locking body has been installed is attached. This stop serves to hold the locking body between the pressure pin and the guide sleeve of the printing mechanism to be slidably fixed and thus the pressure pin and to permanently connect the guide sleeve to one another in such a way that the axial movements of the pressure pin from one of its end positions to the other are always possible. In this printing mechanism, the longitudinal guide groove is through with two holding positions Curved edges of two rings arranged opposite one another are limited. These Rings are usually made of plastic and are both attached to the pressure pin. In order to assemble such printing mechanisms, the first ring is attached to the pressure pin attached, which is then inserted into the guide sleeve. Then the locking body let into the longitudinal guide groove of the guide sleeve, whereupon the second ring on Push pin is attached. This last operation must be carried out with great accuracy because the mutual position of the two rings for the shape of the longitudinal guide groove with two stops is decisive. Otherwise the print mechanics will not work satisfactory.

The assembly of such a printing mechanism is therefore very difficult and requires either a great deal of attention and unusual dexterity the person involved or expensive and cumbersome machines.

Furthermore, printing mechanisms are known in which the longitudinal guide groove is completely milled into the outer surface of the pressure pin with two holding positions. This longitudinal guide groove normally extends to one end of the Pressure pin. In order to be able to assemble the printing mechanics at all, the locking body must first be inserted into the transverse groove of the horizontally held guide sleeve be admitted. Then the pressure pin is inserted into the sleeve in such a way that the entrance of its longitudinal guide groove coincides with the locking body. Then it will be an insert with a central protrusion attached to the end of the push pin. This Insert closes the entrance of the groove. Its ledge will turn into one at the end of the push pin provided axial bore introduced with friction fit.

In a printing mechanism of this type, the assembly is mechanical not possible and must be done by hand, so that mass production is ruled out is. In addition, the attachment of the insert including the projection in the handle is not completely safe by removing these inserts from the pusher during operation to solve. Furthermore, this printing mechanism consists of three parts, namely the guide sleeve, the push pin and the insert. These three parts must be processed separately and be assembled. Compared with a one-piece push pin also causes the inserted into the axial bore of the pressure pin projection of the insert a Loss of material.

Finally, a printing mechanism is also known in which the guide sleeve and the pressure pin each from a single piece, for. B. made of metal. Of the Assembly of the pressure mechanism, in particular the introduction of the locking body, takes place via an insertion channel provided in the guide sleeve or in the pressure pin, which opens into a longitudinal guide groove with two holding positions. The other end of this The insertion channel opens at a free end face of the pressure pin or the guide sleeve. The introduction channel has a constriction which is designed such that the in known designs designed as a ball locking body only in one direction can be introduced into the canal. For example, this has a narrowing in the area of the entrance is slightly inclined in relation to the channel axis and in the area of the groove an inclined or even vertical flank.

However, this printing mechanism causes considerable damage during manufacture Difficulties and does not work reliably. It is not enough, just the transverse groove and the longitudinal guide groove and the introduction channel, but mainly its narrowing to be machined with a tolerance that offers sufficient operational reliability. Is namely the narrowing of the insertion channel is not strong enough, the ball falls into the Insertion channel back so that the pressure pin and the guide sleeve no longer are connected to each other. The printing mechanism is therefore out of order. Is the constriction too strong creates other difficulties. Either the ball at Assembly of the push mechanism will not be inserted or the ball will be damaged the constriction or it will itself be damaged. Becomes the narrowing of the introductory canal damaged during assembly, the life of the printing mechanics is great limited. If the ball is damaged, reliable operation is a must from the start questionable.

The invention has set itself the task of the printing mechanism with the features explained in the first paragraph so that with easier and cheaper making the assembly simple and reliable Functionality is guaranteed for a long time.

This object is achieved in that the recess on the front Arranged at the end of the longitudinal guide groove and as one at least the dimensions of the Blocking body having receiving point is formed, on which a stop connects to one of the two parts, and after the introduction of the locking body in the longitudinal guide groove by means of the transverse guide groove from one am Stop pending, deformable locking piece is overlapped. In detail is the stop is designed as a collar of the pressure pin and the deformable locking piece is located on the guide sleeve. The deformable locking piece is designed as a tubular Profile piece formed at the front end of the guide sleeve.

The invention combines the advantages of very simple manufacture - The pressure mechanism consists exclusively of two machined parts, the pressure pin and the guide sleeve - and very quick assembly. Since the longitudinal guide groove is carved out of a workpiece, it can be manufactured with the highest degree of accuracy will. The production costs of such a printing mechanism are therefore very low and yet the printing mechanism works with full reliability. She is particular suitable for use in a ballpoint pen, with manufacturing costs and operational reliability are of decisive importance. Any locking bodies, such as balls, cylindrical rollers or the like., Can be used.

The drawing shows an exemplary embodiment of the subject matter of the invention shown. In particular, the assembly is based on this exemplary embodiment the printing mechanics shown. It shows F i g. 1 shows a longitudinal section through the rear Part of a ballpoint pen with a push mechanism, FIG. 2 a partial settlement the lateral surface of the handle according to FIG. 1, Fig. 3, 4 a view of the printing mechanism according to FIG. 1 with cut guide sleeve and partially cut pusher in two consecutive steps during assembly.

The printing mechanism selected as an exemplary embodiment is provided in a ballpoint pen with a housing 1 made of plastic, in which an axially displaceable writing cartridge 2 is arranged. This writing cartridge 2 is loaded from bottom to top by a spring that surrounds it, not shown in the drawing. This spring is supported on the one hand on a collar of the writing cartridge 2 and on the other hand on an inner shoulder surface of the housing 1. At the upper end of the housing 1, a guide sleeve 3 provided with a thread 4 and a head 5 is screwed on so that the head is at the upper edge of the housing. This guide sleeve 3 has a central, continuous, cylindrical bore 6. In the area of the front end, this bore 6 is provided with an annular, open transverse guide groove 7 of trapezoidal cross-section. Furthermore, this guide sleeve 3 is provided with a tubular profile piece which serves as a deformable locking piece 8. The two surfaces of the locking piece 8 are machined cylindrically, as shown in FIG. 3 can be seen. The F i g. 3 shows the position of the locking piece 8, designed as a profile piece, at the beginning of the assembly. The locking piece 8 , designed as a profile piece, has a smaller wall thickness than the remaining part of the guide sleeve 3, so that it is easily deformable. The inner diameter of the locking piece 8 is slightly larger than the inner diameter of the bore 6, so that a shoulder surface 19 is formed at the transition between this bore 6 and the locking piece 8, which is designed as a profile piece.

A cylindrical pressure pin 9, the front end of which has a collar serving as a stop 10 , is arranged in the bore 6 so as to be axially displaceable. The outer surface of this pressure pin 9 has a longitudinal guide groove 11 , the depth of which is uniform, but the width of which is uneven. The course of the longitudinal guide groove 11 essentially corresponds to a heart-shaped line (FIG. 2). The downwardly directed heart tip has a detachable width and opens into a receiving point 12, the depth of which is greater than the depth of the longitudinal guide groove 11 . The ball lies partly in the transverse guide groove 7 of the guide sleeve 3, partly in the longitudinal guide groove 11 of the pressure pin 9. As in FIG. 1, the locking piece 8 of the guide sleeve 3, which is designed as a profile piece, is slightly twisted inwards into the final working position. Under the action of the spring, not shown in the drawing, loading the cartridge 2 , the collar serving as a stop 10 hits the deformed locking piece B when the pressure pin 9 moves upward. The pressure pin 9 is then in its upper end position. In this upper end position, the annular zone 18 of the pressure pin 9 is level with the transverse guide groove 7. This zone 18 lies transversely through the lower part of the longitudinal guide groove 11, so that the ball does not migrate through the zone 18 in this position and therefore not into the receiving point 12 can fall. If, based on the position of FIG. 1, the pressure pin 9 is adjusted downwards, the writing cartridge 2 is adjusted downwards against the action of the spring, not shown in the drawing. Which serves as a locking body 13 ball travels along the left branch of the longitudinal guide groove 11 (F i g. 2) and enters the rear left part of the longitudinal guide groove 11. slides along an inclined surface 14 which forms the upper edge of the longitudinal guide groove 11. If now the pressure pin 9 is released, it moves together with the writing cartridge 2 under the action of the spring, not shown in the drawing, axially to the rear. The ball slides along a further inclined surface 15, which forms the lower edge of the longitudinal guide groove 11 and arrives in a pocket 16, in the bottom of which it is held by the said spring, not shown in the drawing. The pressure pin 9 is thus blocked in its second holding position, the tip of the writing cartridge 2 protruding from the housing 1 so that the ballpoint pen can now be used. To return the write cartridge 2 to the position of FIG. 1, it is sufficient to press the pressure pin 9 again. Starting from the pocket 16 , the ball slides along a third inclined surface 17, which forms the upper edge of the right part of the longitudinal guide groove 11 and reaches the upper right part of the longitudinal guide groove 11. If the pressure pin 9 is now released again, it slides as a locking body serving ball in the right part of the longitudinal guide groove 11, while the pressure pin 9 moves up again under the action of the spring. The axial movement of the pressure pin 9 only stops when the stop 10 , which is designed as a collar, strikes the locking piece 8 . The pressure pin 9 then takes again the in F i g. 1 position shown. With each new pressure on the pressure pin 9, the same cycle starts again in the same sense. The ball serving as the locking body 13 is always held in the two grooves 7 and 11, which face each other in all positions of the pressure pin.

So that the pressure mechanism works reliably, the depth of the transverse guide groove 7 and the depth of the longitudinal guide groove 11 are approximately equal to the radius of the ball serving as locking body 13. When these parts are assembled, the ball serving as locking body 13 should be without play, but also without jamming let move.

As in particular from FIG. 3, the depth of the receiving point 12 is greater than the diameter of the ball serving as the locking body 13. The assembly of the printing mechanism described can therefore be carried out very quickly and in an extremely simple manner. The locking piece 8, designed as a profile piece, consists of one piece with the guide sleeve 3 and has a cylindrical shape. The inside diameter of the guide sleeve 3 is selected such that the collar serving as a stop 10 can be inserted into the locking piece 8 without difficulty (FIG. 3).

In order to assemble the printing mechanism, the following procedure is followed: The pressure pin 9 is held horizontally with the receiving point 12 upwards, whereupon a locking body 13 designed as a ball is inserted into the receiving point. This can be done very quickly in that the pressure pin 9 is held under the exit of a manifold, a funnel or a magazine loaded with balls and the whole is designed in such a way that a ball is dispensed as soon as a pressure pin is inserted into the device. The pressure pin 9 with the ball serving as a locking body 13 located in the receiving point 12 is then inserted into the guide sleeve 3 until the collar serving as a stop 10 strikes the shoulder surface 19 (FIG. 3). Since the ball lies deep in the receiving point 12, the depth of which is greater than its diameter, the pressure pin 9 can be inserted into the bore 6 without difficulty. When the collar serving as a stop 10 strikes against the shoulder surface 19, the receiving point 12 and the ball serving as a locking body 13 lie in front of the transverse guide groove 7 To let the serving ball fall into the transverse guide groove 7. Then the pressure pin 9 is partially pulled out of the guide sleeve 3 (FIG. 4). The ball serving as a locking body 13 enters the part of the longitudinal guide groove 11 which forms the tip of the heart-shaped longitudinal guide groove. The pressure pin together with the guide sleeve is now held upright, whereupon in a single operation a suitable tool sprains the locking piece 8, which is designed as a profile piece, in such a way that it can be seen in FIG. 1 assumes final working position shown. At this moment the printing mechanism is locked, ie the guide sleeve 3 and the pressure pin 9 are attached to one another. The pressure pin 9 can only move from one of its end positions to the other. These end positions are determined by the fact that the ball serving as the locking body 13 strikes the inclined surfaces 14, 17 and the collar serving as the stop 10 strikes the lower edge of the locking piece 8. Since the receiving point 12 is on the opposite side to the longitudinal guide groove 11 with respect to the zone 18, the ball serving as the locking body 13 can never fall back there.

Claims (3)

Claims: 1. Printing mechanism from a displaceable, one-piece pressure pin in a one-piece guide sleeve and from a transverse guide groove in one part and a heart-shaped longitudinal guide groove in the other part with a recess for inserting a locking body for the two locking positions determined by the longitudinal guide groove, characterized in that, that the recess is arranged at the front end of the longitudinal guide groove (11) and is designed as a receiving point (12) having at least the dimensions of the locking body (13), to which a stop (10) on one of the two parts is connected and which after penetration of the locking body is overlapped in the longitudinal guide groove by means of the transverse guide groove (7) by a deformable locking piece (8) positioned at the stop. 2. Printing mechanics according to claim 1, characterized in that the stop as a collar (10) of the pressure pin (9) is formed and the deformable locking piece (8) on the guide sleeve (3) is located. 3 printing mechanism according to claim 2, characterized in that the deformable Locking piece as a tubular profile piece (8) at the front end of the guide sleeve (3) is trained.