DE4337589C2 - DC solenoid - Google Patents

Description

The invention relates to a DC solenoid according to the Features of the preamble of claim 1.

Such DC solenoids are such. B. from DE-OS 14 64 419 known. The DC solenoid described there has a turnstile mechanism in order to cause permanent closing or opening of main contacts after a brief energization of the excitation coil. For this purpose, the direct current lifting magnet has an armature which can be moved axially within a central opening of the direct current lifting magnet and which moves a bushing with lugs attached to the end face of this bushing with curved cam surfaces in the direction of cam surfaces of an opposite locking part. As is evident from the local Fig. 5 to 9 and direction belonging to the functional description of the Verriegelungsein which fixedly connected to the contact arrangement lock chamber from said receptacle in two different axial positions is brought. The cam engagement of the surfaces 39 and 40 leads to a rotation of the locking chamber Ver by 90 °, the stop latching once behind a cut-out part of the locking part and coming to rest once in a slot. If the stop is in the slot, the locking part, together with the contact arrangement, can move further to the left, the contacts being open. In the position of the locking chamber rotated by 90 °, on the other hand, the stop comes to a stop behind a cut-out part of the locking part, thereby preventing the locking chamber from escaping to the left. In this position the contacts are closed without the need for further energization of the excitation coil. The anchor is used in these known DC solenoids only to push the so-called locking chamber in two un different locking positions. The problem with such a DC solenoid is the fact that the armature is not mechanically held in two different positions, but only serves to push the so-called locking chamber into two different locking positions.

Starting from such a DC solenoid is the Object of the present invention is to provide a direct current Specify solenoids that allow the armature to be de-energized and without the use of a permanent magnet in both the first as well as to fix in the second position.

This task is accomplished with a DC solenoid Features of claim 1 solved.

Further developments of the invention are the subject of the dependent claims che.

The invention is therefore essentially based on DC solenoids to provide a device that it allows the anchor alternately in a first position and in a second position axially displaced to the first position to keep splined by a spring force of a compression spring, the anchor from the first or second position by Be Flow of the coil in the second or first position movable is.  

The spline is advantageously in accordance with Art a so-called turnstile mechanism like this as such is known, trained. For this, the facility shows preferably one in the area of the lower opening of the coil body-arranged pole core and a toothed ring on the fixed and non-rotatably arranged over the pole core is and towards the upper opening of the bobbin has pointing teeth. In addition, an interior serration provided in the area of the upper opening inner half of the bobbin with short and long guides or Guide teeth is arranged, these guides or Guide teeth arranged opposite the teeth of the toothed ring are. Finally, an anchor tooth ring is axially fixed standing and rotatable in the circumferential direction with the anchor connected with teeth to engage the short or long guides or guide teeth of the internal toothing nung.

When the armature moves axially by energizing the coil the anchor moves towards the bottom opening of the Ultimately, the coil body and the teeth of the armature abut the teeth of the gear ring. The teeth of the anchor tooth ring and the toothed ring are so coordinated that the corresponding teeth of the armature toothed ring rotating to closest long or short guide tooth of the inside toothing can be rotated. Then the Current flow to the coil is interrupted with this arrangement by the spring force of the compression spring the anchor back in Direction of the internal teeth pressed, the teeth, each after whether these teeth previously in a long or short Have been on the adjacent long or short guide to be stopped and therefore  rotating into a predetermined by the inclination of the guide Move direction.

Such an arrangement has the advantage that both in the first as well as in the second position, d. H. in the Locking as well as in the unlocking position, no Current flow through the coil is necessary. Beyond that there is no Permanent magnet for fixing the armature in the stroke end location required. The coil must be in the invention DC solenoids only during the switchover phases, d. H. the feed in the direction of the pole core.

The arrangement according to the invention therefore offers the following advantages le. There is only one voltage for the different stroke distances needed without polarity reversal and it is a simple timing element sufficient. In addition, the fiction is distinguished moderate DC solenoid by a temperature stable Ver endure because the arrangement is not temperature sensitive Permanent magnets required. Otherwise, the invention appropriate arrangement less expensive than a direct current stroke gnet with permanent magnet and a specially elaborate ge designed control electronics for a voltage reversal.

According to the anchor toothed ring can be secured against rotation or be rotatably connected to the anchor. Will the anchor the toothed ring is connected to the armature so that it cannot rotate, so it turns the anchor with the rotation of the armature toothed ring. A rotatable solution, for example by means of an ent speaking sliding, rolling bearing or the like, prevents against the fact that the armature rotates when the armature rotates tooth ring rotates. While the first solution is through features a simpler mechanical structure  the second solution has the advantage that the anchor tooth ring on is easier to turn due to the lower mass. Indeed allows the first solution to combine targeted rotary movements with longitudinal movements of the anchor or the ver tied locking bolt.

It should be noted here that the shape and number of Teeth of the anchor tooth ring the stages of the angle of rotation determine the anchor if this is both radial and is axially fixed to the armature toothed ring. About that is also due to the tooth shape of the anchor tooth ring Forced running, d. H. a right or left turn of the anchor, given.

Otherwise applies to the direct current lifting magnet according to the invention ten that the number and length of the guides or guide teeth of the internal teeth the number of stroke positions as well specifies the stroke position itself. The tooth shape determines itself also the right or left turn. Overall, are on the desired number of strokes, stroke positions, rotation levels and the direction of rotation the shape and number of three teeth, d. H. Internal toothing, anchor tooth ring and Tooth ring to match each other.

In a particularly preferred embodiment of the invention the teeth of the anchor ring are trapezoidal or triangular forms, in such a way that they are radial from the armature toothed ring Form outward-facing pins. The slopes of this pen te are the teeth of the internal toothing and the teeth NEN the toothed ring adapted to a rotational movement of the armature to allow ring gear.

In a specific embodiment of the invention, the teeth are of the armature ring gear evenly around the armature ring gear  Splits. It has been found that an arrangement of three or four teeth is sufficient.

A particularly simple and therefore inexpensive manufacture the DC solenoid according to the invention is possible if the internal teeth together with the bobbin lumpy and in particular by injection molding process is made of plastic. Furthermore, it has turned out to be useful, especially through the tooth ring a keyway attachment such. B. by longitudinal grooves, inside to secure the bobbin against rotation. About that In addition, the toothed ring can by pointing into the coil interior and preferably integrally molded on the coil former jumps must be axially secured.

An execution example Game of the invention is in the following in connection with a total of seven figures that a chronological sequence of the anchor movement and the ge represent listening positions explained. Show it:

Fig. 1 shows an embodiment of a DC Hubmagne ten in longitudinal and sectional view in a locking position with de-energized coil;

Fig. 2 is a representation of Figure 1 in a first intermediate position.

Fig. 3 is a view of Figure 1 at the maximum possible armature stroke and energized coil.

Fig. 4 is an illustration of Figure 1, in which the ker is in the unlocked position.

Fig. 5 is an illustration of Figure 1 when energized coil in a further intermediate position.

FIG. 6 shows a representation according to FIG. 5 with the coil energized with the maximum possible armature stroke; and

Fig. 7 shows a locking position as in Fig. 1 when the coil is not energized.

In the following description of the figures are the same Parts used the same reference numerals.

In Fig. 1 an embodiment of an inventive SEN DC solenoid actuator in longitudinal section is shown as sectional view. Reference number 1 denotes a housing of the direct current lifting magnet. In this housing 1 is surrounded by a coil 5 he coil body 10 is provided, in which an armature 3 is axially movably mounted. A pole core 2 is arranged in the region of a lower opening 12 of the coil former 10 , in the center of which a recess is provided for a compression spring 7 arranged axially relative to the armature 3 . This compression spring 7 serves to press the armature 3 axially upwards in the illustration of FIG. 1. The arrangement also has a toothed ring 9 , which is fixed and rotatably arranged over the pole core 2 and in the direction of an upper. Opening 11 of the bobbin 10 contains teeth 16 pointing. In addition, an internal toothing 6 is provided in the area of the upper opening 11 within the coil body 10 , which is preferably made in one piece from plastic with the coil body 10 and is equipped with short and long guides or guide teeth 13 , 14 . These guides or guide teeth 13 , 14 point in the direction of the teeth 16 of the toothed ring 9 and lie opposite them. In addition, an armature toothed ring 4 is axially fixed to the armature 3 . The armature toothed ring 4 has teeth 17 , preferably four radially outwardly directed triangular or trapezoidal pins, which can engage in the short or long guides 13 , 14 of the internal toothing 6 .

As shown in Fig. 1, despite the spring force acting on the lower end of the armature 3 of the compression spring 7, a movement of the armature 3 in the axial direction upwards is limited in that the armature toothed ring 4 on projections 20 in the upper opening 11 of the coil body 10 strikes.

The armature 3 is thus in the maximum extended position, which is the locking position A here by agreement. The armature 3 or a locking bolt connected to this armature 3 (whose diameter does not have to be identical to the armature diameter) protrudes through an opening 21 of a device 22 , not shown, in order to lock it. The teeth 17 of the armature toothed ring 4 are seated in this locking position A in the long guides and guide teeth 14 of the internal toothing 6 . As shown in Fig. 1 above in the cross-sectional view, it is assumed in this embodiment that the armature toothed ring 4 has four equally spaced teeth 17 and the internal toothing 6 is provided with a total of eight alternately arranged long and short guides 14 , 13 .

In the illustration of Fig. 1, a disc 8 is arranged between the top of the compression spring 7 and the lower end of the armature 3 in order to reduce the friction between the compression spring 7 and armature 3 when the armature rotates and the spring pressure is evenly applied to the lower end of the armature 3 to be able to transmit. Fig. 1 also shows an axial locking force Fa, which is shown by an arrow and determined by the compression spring 7 . A maximum permissible radial locking force F _R , which acts radially on the upper end of the armature 3 , is predetermined by the mechanical structure of the DC solenoid.

In the illustration of Fig. 1, the coil 5 is not traversed by current.

In Fig. 2, the armature 3 is already in an inter mediate position B, since starting from the locking position A in Fig. 1, current now flows through the coil 5 . The four outer teeth 17 of the armature toothed ring 4 move together with the armature 3 in the direction of the compression spring 7 and thus leave the long guide teeth 14 of the inner toothing 6 . As shown in FIG. 2, the guide teeth 17 have already been in contact with the toothing of the toothed ring 9 . However, the armature toothed ring 4 has not yet been rotated. As can be clearly seen from FIG. 2, the teeth 17 of the armature toothed ring 4 lie with part of their lower surface already on part of an inclined surface of the teeth 16 of the toothed ring 9 . If the coil is further energized in this position, 5, to slide the teeth 17 of the anchor ring gear 4 along the slopes of the teeth 16 of the Zahnrin ges 9, whereby both axial movement of the armature 3 as well as a rotating movement of the anchor tooth ring 4, lead, for example in the off by Fig. 2 to the left takes place.

In FIG. 3, when current is applied coil 5, a position C is shown with maximum possible armature stroke. Due to the axial force of the DC solenoid and the contact of the armature toothed ring 4 with the toothed ring 9 , a rotary and axial movement of the armature toothed ring 4 - in these examples to the left - has taken place. Depending on the type of attachment of the toothed ring 4 to the armature 3 , the armature 3 and thus a locking bolt possibly connected to it is also rotated. When the armature has reached this position, the coil 5 can be switched off again. At ker 3 will then move away from the pole core 2 by the restoring force of the compression spring 7 and move axially upwards.

In FIG. 4, the armature is shown in the unlocked position D3. By the axial force of the compression spring 7 and the contact of the anchor tooth ring 4 with the internal toothing 6 already another rotational and axial movement of the armature ring gear 4 has taken place to the left. The four teeth 17 of the armature toothed ring 4 are now fixed to the four short guides 4 or guide teeth of the internal toothing 6 and thus in the unlocked position D. It is then no longer necessary to energize coil 5 .

In Fig. 5 it is assumed that the coil 5 is energized again and consequently the armature 3 begins to move axially downwards to an intermediate position E. The four teeth 17 of the armature toothed ring 4 leave the four short guides 13 of the internal toothing 6 downward and touch the teeth 16 of the toothed ring 9 again next. If the coil 5 is energized further, a rotation of the armature toothed ring 4 to the left takes place again in the manner already described.

In FIG. 6 with further energized coil 5, the maximum possible armature stroke and thus the position F is illustrated. The armature toothed ring 4 has been rotated. Be the flow of the coil 5 can be switched off.

In Fig. 7, the starting position or locking position A already explained in Fig. 1 is reached again. When the coil current is switched off and with the restoring force of the compression spring 7 , the four teeth 17 of the armature toothed ring 4 are again guided into the long guides 14 of the internal toothing 6 and brought to a stop there. The locking position A and thus the starting position of Fig. 1 is therefore realized again. The whole process can be repeated again.

The DC solenoid according to the invention is not limited to the embodiment shown in FIGS. 1 to 7 be. It can also be seen differently arranged toothings and other tooth shapes of the outer toothed ring 4 can be seen before. It is only essential that a so-called turnstile mechanism is realized by the corresponding toothing, in which there is a rotation with the axial movement of the armature 3 down to fix the armature 3 in the closing movement at the top in a first position and at one bring further axial movement down from this first position towards the second position. The current flow through the coil 5 is only necessary for the brief unidirectional axial movement of the armature 3 from the first to the second position. The axial movement in the opposite direction takes place through the spring force of the compression spring 7 . The armature 3 is fixed solely by a spline and the spring force of the compression spring 7 .

Claims (11)

1. DC solenoid with a coil body ( 10 ) arranged inside a housing ( 1 ) and surrounded by a coil ( 5 ), which has an upper and a lower opening ( 11 , 12 ), with at least one through the upper opening ( 11 ) projecting and axially movable to the coil body ( 10 ) armature ( 3 ), and with a device ( 2 , 4 , 6 , 9 ) with which the armature ( 3 ) by means of the spring force of a compression spring ( 7 ) and by energizing the coil ( 5 ) can be moved alternately into a first position (A) and into a second position (D) axially displaced to the first position (A), characterized in that the armature ( 3 ) is splined in each of the two different positions (A, D) is locked. 2. DC solenoid according to claim 1, characterized in that the device ( 2 , 4 , 6 , 9 ) comprises:

• - A pole core ( 2 ) arranged in the region of the lower opening ( 12 ) of the coil body ( 10 );
• - A toothed ring ( 9 ) which is arranged in a fixed and rotationally secure manner above the pole core ( 2 ) and has teeth ( 16 ) pointing in the direction of the upper opening ( 11 );
• - An internal toothing ( 6 ), which is arranged in the area of the upper opening ( 11 ) within the coil former ( 10 ) with short and sometimes long guide teeth ( 13 , 14 ) and the guide teeth ( 13 , 14 ) relative to the teeth ( 16 ) the tooth ring ( 9 ) are arranged;
• - An armature toothed ring ( 4 ) which is axially fixed and radially rotatably connected to the armature ( 3 ) and has teeth ( 17 ) for engaging in the short or long guide teeth ( 13 , 14 ) of the internal toothing ( 9 );

the axially moving the armature ( 3 ) towards the lower opening ( 12 ) of the coil body ( 10 ) by energizing the coil ( 5 ), the teeth ( 17 ) of the armature ( 3 ) rotating from the toothed ring ( 9 ) to the nearest or short guide tooth ( 14 , 13 ) of the internal toothing ( 9 ) are displaceable. 3. DC solenoid according to claim 1 or 2, characterized in that the armature ( 3 ) is tapered at its end projecting into the bobbin by ( 10 ) that this end when the coil ( 5 ) is energized by the toothed ring ( 9 ) can be moved axially in the direction of the lower opening ( 12 ) of the coil body ( 10 ), and that the compression spring ( 7 ) is arranged below the toothed ring ( 9 ) for resetting the armature ( 3 ). 4. DC solenoid according to one of claims 1 to 3, characterized in that the armature toothed ring ( 4 ) verdrehsi cher with the armature ( 3 ) is connected. 5. DC solenoid according to one of claims 1 to 3, characterized in that the armature toothed ring ( 4 ) is arranged rotatably to the armature ( 3 ). 6. DC solenoid according to one of claims 1 to 5, characterized in that the teeth ( 17 ) of the armature tooth ring ( 4 ) are trapezoidal or triangular to rotate when abutting the toothed ring ( 9 ) or the internal toothing ( 6 ) to be moved. 7. DC solenoid according to one of claims 1 to 6, characterized in that the teeth ( 17 ) of the armature tooth ring ges ( 4 ) are evenly spaced from one another and the internal teeth ( 6 ) are arranged with the same distance from each other and alternate short and long guide teeth ( 13 , 14 ) is provided. 8. DC solenoid according to one of claims 1 to 7, characterized in that the internal toothing ( 6 ) is integrally formed on the coil body ( 10 ). 9. DC solenoid according to claim 8, characterized in that the coil body ( 10 ) and the internal toothing ( 6 ) are formed from plastic. 10. DC solenoid according to one of claims 1 to 9, characterized in that the toothed ring ( 9 ) on the coil body ( 10 ), in particular via a keyway, is attached. 11. DC solenoid according to one of claims 1 to 10, characterized in that for axially securing the armature toothed ring ( 4 ) in the interior of the coil body ( 10 ) projecting projections ( 20 ) are fixed to the coil body ( 10 ).