DE2642832A1 - ELECTROMAGNET FOR ACTIVATING A PRESSURE ELEMENT - Google Patents

Description

Patent Attorneys Di ρ I.-I ng. Curt Wallach

Dipl.-Ing. Günther Koch

^ Dipl.-Phys. Dr Tino Haibach

Dipl.-Ing. Rainer Feldkamp

D-8000 Munich 2 Kaufingerstraße 8 Telephone (0 89) 24 02 75 Telex 5 29 513 wakai d

Date: ² ^ - September 1976

Our reference: 15 644 - Κ / Αρ

Oki Electric Industry Co., Ltd., 10 Shiba Kotohira-cho Minato-ku, Tokyo / Japan

Electromagnet for actuating a pressure element

The constantly increasing working speed of the central units electronic data processing devices requires a correspondingly increased speed for printing.

Various types of high-speed printer are known and the present invention relates to a high-speed dot printer for printing out characters by means of a dot matrix, and more particularly the invention relates to one Electromagnet to drive such a dot printer "

A conventional printing solenoid used in connection with dot printers or the like is shown in FIG Drawing shown in cross section. The reference numeral 101 denotes a yoke made of magnetically conductive material, to which a stationary core 102 is attached. 103 is a point pressure wire routed in holes 104 and 105 of the yoke o The stationary core 102 and a cap 112 leave the dot printing wire 103 pass through. An axially movable one Anchor 106 is fixed to the pressure wire 103. The excitation coil drives the anchor towards the printing paper surface, which is in the

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Drawing is not shown and in the following as "printing area" referred to as. 108 with a return plate spring is referred to, the circumferential portion of the yoke 101 over a support member 109 made of plastic material is fixed while its central portion is fixed to the anchor 106. That The carrier element 109 serves to oppose the return spring 108 To protect fatigue. A gap 110 is provided between the stationary core 102 and the armature ΙΟβ. 111 is a yoke and 112 is a cap.

By energizing the coil 107 with current, as shown in Figure 2 (I), a magnetic flux is generated, which through the Yoke 101, the yoke 111, the armature ΙΟβ and the stationary core 102 is closed in order to cause the armature 106 to move, reducing the air gap 110. Consequently the printing wire 103 is driven in the direction of the arrow and hits the printing surface and leaves a point there. As the printing speed increases, the Print wire 103 faster and faster towards the printing surface moved and he is subjected to a strong impact by this surface and he is by the return spring 108 withdrawn. The anchor therefore collides with the cap 112 and causes the second movement of the pressure wire 103 after the Pressure area and this leads to disadvantages in terms of an extended period of time before the armature 106, as shown in Figure 2 (II) comes to a standstill, or finally a point is printed twice with the point wire 103.

The invention relates to a pressure electromagnet on the inner surface of the cap in the axial direction on the Anchors directed towards, having a damping device, which consists of a stop element with a suitable mass and an elastic Element exists in order to reduce the time required to catch the armature during the return movement to a standstill.

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that is and to prevent the anchor from bouncing is subjected.

The invention is based on the object of creating a damping device that consists of a stop element and there is an elastic element between the anchor and the cap, reducing the time required to bring the armature to a standstill on its return movement.

Another object of the invention is to create a damping device between the armature and the cap, whereby the bouncing effect of the armature avoided and accordingly an undesired double pressure when actuating the armature is prevented, itself when the printing speed is increased significantly.

The invention also aims to reduce the rate of deformation of the elastic element by using a relatively large mass for this stop element, i. large compared to the mass of the armature, which increases the damping effect.

An exemplary embodiment of the invention is described below with reference to the drawing. In the drawing show:

Fig. 1 is a longitudinal section of a conventional push-type electromagnet;

Fig. 2 is a graph which under (I) the Waveform of the excitation current, in (II) the amount of displacement of the armature in a conventional one Electromagnet, and in (III) the amount of displacement of the armature in the case of a pressure electromagnet shows according to the invention;

3 shows a longitudinal section of a device designed according to the invention Pressure electromagnet;

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- * ν

Pig. 4 is a perspective view of an embodiment of a damper consisting of a Stop element and an elastic element.

The invention is described in detail below with reference to FIG. The reference symbol 101 again represents a yoke made of ferromagnetic !!! Material is on the yoke a stationary core 102 attached. 103 is a printing wire. A hole is provided in the yoke 101 and the stationary core 102 to allow the dot pressure wire 105 to pass therethrough. A hole I05 is provided in a cap 112. On the An axially movable armature 106 is disposed on pressure wire 10J. To drive the armature in the direction of the not shown An excitation winding 107 serves the pressure surface. A return plate spring 108 is fixed with its peripheral portion to the yoke 101 by means of a support element I09, e.g. is made of plastic material. The middle section of the disc spring is fixed on the armature I06. The carrier element I09 prevents a fatigue of the spring I08. There is an air gap between the stationary core 102 and the armature 106. on a yoke 111 is formed on the yoke 101. Numeral 112 denotes a cap. A stop element has a relatively large mass compared to the mass of the armature I06 and the stop element 113 is in the return stroke of the Anchor and is on the inner surface of the cap 112 by means of an elastic element 114, for example made of rubber or by means of a spring mounted, whereby a damping device is formed will. A hole II5 is provided in the stop element 113.

By energizing coil I07 with one shown in Figure 2 (I) Excitation current supplies the resulting magnetic flux in a closed circuit via the yoke 101, the yoke 111, the Anchor I06 and the stationary core 102, so that the anchor in the

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The meaning of a reduction in the air gap 110 is offset. As a result, the printing wire 103 is driven in the direction of the arrow and hits the printing surface, not shown, in order to produce a dot imprint on it. After completion of the dot expression, the dot pressure wire 103 is bounced back by the pressure surface and at the same time by the return spring 108 withdrawn. As a result, the anchor 106, which is fixed on the pressure wire 103, hits the stop element 113 move on and due to the relatively large mass of the stop element compared to the mass of the armature 106 Stop element 113 and armature 106 move in the same direction, but at a relatively low speed, whereby a deformation of the elastic element 114 occurs. Part of the energy of this deformation is called thermal energy consumed, while the remainder as kinetic energy presses back the armature 106 and the stop element 113 and these parts therefore move back at a relatively slow rate. In this way, the armature 106 transmits its kinetic Energy on the stop element 113 and it is driven back by this at a speed that is very is much smaller than the initial speed when hitting the stop element 113 *, which causes the vibration of the armature is weakened and a standstill can be achieved very quickly, as can be seen from FIG. 2 (III). It will therefore it is possible to reduce the time required to stand still and to double printouts by the bouncing effect of the print wire 103 to avoid.

In the embodiment described above, the mass of the stop element 113 should of course in view of the elasticity of the resilient member 114 in addition to the considerations regarding the mass of the anchor lo6. In the above embodiment, the elastic member 114 can vibrate freely, but it is also possible

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to limit the stroke, for example in such a way that the stop element only within a certain distance of the cap 112 is movable. It is also possible by the restoring spring 108 to support the armature To arrange holes 105 and 115 in the cap 112 and the stopper 113 and to shorten the length of the pressure wire I03.

The stop element 115 is preferably made of non-ferromagnetic Material, e.g. made of brass, and is preferably designed as a disc.

The elastic member 114 may, for example, consist of a cylindrical Rubber piece, or also from a spiral spring, or two disc springs and it can be on the stop element 113 be mounted in that one end of the element engages in a corresponding groove in the stop element 113.

The invention is not restricted to the exemplary embodiment described above and numerous modifications can be made without departing from the scope of the invention.

As can be seen from the above description, the pressure electromagnet according to the invention is characterized by the presence of a damping device consisting of a stop element of suitable mass and an elastic element consists, which carries the stop element between the armature and the cap and is thus able to control the movement of the armature quick to intercept and repeated touches of the point term wire with the printing surface to avoid which could result from the bouncing of the printing wire.

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Claims (3)

Patent claims: 1. Pressure electromagnet for actuating a pressure element, for example a printing wire by exciting a drive coil, characterized in that a damping device (113 * 114) is provided is composed of a stop element (113) for stopping the armature and returning the same and an elastic element (114) which carries the stop element. 2. Pressure electromagnet according to claim 1, characterized in that the elastic element (114) is the stop element (113) carries, on the inner surface of a cap (112) on the axially rearward side of the Anchor is set. 3. Pressure electromagnet according to claim I _3, characterized in that the stop element (113) consists of non-ferromagnetic material and has a relatively large mass compared to the mass of the armature. 7098 13/0780