DE286634C - - Google Patents

Description

KA-ISE RUCHE S

PATENT OFFICE.

- / ■

PATENT LETTERING

-'M 286634 ,, CLASS 74c, GROUP

ROBERT MENGEL in BERLIN. '■ Electric. Signal receiver for alternating current. Patented in the German Empire on February 1, 1914.

The invention relates to a signal device

■ - tion / the means-movable scale or one Pointer shows the signals received from an encoder. The invention is intended to Display commands given to ships for setting up guns, searchlights, etc., at all serve for the transmission of commands of any kind.

The object of the invention has the advantage over other known devices * in the »extremely simple construction.

On the .Drawing Fig. Ι illustrates

in side view the 'arrangement of the anchor -i and the climbing wheel cap (for a better overview a piece is cut out of the bearing bracket and the cap),

■ Fig. 2 in the plan the arrangement of the magnets, - ^{1 of} the lower ^: bearing plate and the armature omitting the cap and ■ armature axis,

'' • Fig. 3 the Steigradkappe seen from below, Fig. 4 the Steigradkappe ■ in 'section C-Z) of Figure 3; and

¹ Fig. 5 the climbing gear cap in section according to AB ' of Fig. 1 and the engagement position of the spear pawls.

^; On a base plate G (Fig. 1 and 2) ^: the angularly bent steel magnets /, K, O, P are arranged. ^l to the upright legs of the soft iron cores are a, b, c, d and β mounted the coils on the same, f, g and h pushed. Of these, e with f and g with h are connected to one another in such a way that they create different poles at the free ends of the iron cores when a current flows through them.

The forward lines I ₁ and / ₂ and the common return line l _z are for. each pair of coils created separate circuits. ^: Both pairs of electromagnets have a common, equally armed soft iron armature E, arranged between the coil cores, whose vertical axis i at k is guided in a ball bearing and with its lower bearing pin engages in a slot in the bearing plate L (Fig. 2), so that ^{1 is} the armature can swing freely as a pendulum in the vertical direction and also around its axis i in the horizontal direction.

The length of the slot in the plate L is

dimensioned so that between armature E and the coil cores, when the armature is attracted by a pair of magnets, there remains a margin for the armature to move horizontally. A pawl carrier H is attached to the upper end of the axis i; on this the pawls r and p (Fig. 5) are rotatably arranged around the pin u , which are constantly pulled by the springs s and t to the stop pin υ , in which position they engage the climbing wheels when the armature is in the appropriate position. The concentric to the armature axis arranged cap F (Fig. 1 and 4) carries on its lower cylindrical edge two oppositely toothed, through the 'intermediate

■ ring 0 separate ■ climbing wheels m and n, the teeth of which lie exactly one above the other and, in contrast to known climbing wheel arrangements, are directed inwards. The signals can now be attached to the upper face of the cap or a pointer, which slides over a fixed scale, can be attached to the axis w. The cylindrical mantle of the

The outside of the cap F is provided with a number of grooves corresponding to the teeth of the climbing gear, in which a leaf spring χ (Fig. 5) engages with the pressure piece y and thus prevents the cap F from rotating unintentionally.

The receiver works as follows:

Let the upright legs of the steel magnets K and / (FIGS. 1 and 2) be north poles; so the free ends of the coil cores b and α will also become north poles due to the magnetic effect. If a current now flows through the suitably connected coils f and e in the direction that a north pole is generated at the free end of the coil core b , the free end of the iron core a receives a south pole. The magnetization of the core b takes place through the coil, thus in the same sense as through the associated steel magnet K, so the magnetism of this core must be strengthened. In the case of the coil core a , the magnetization by the coil e is opposite to that of the associated steel magnet /; here the magnetism in the iron core is completely or partially canceled, the magnetic effect of the pole at the free end of the core is destroyed or reduced. The armature E is now pulled by the pair of electromagnets K and / in its increased magnetic field, presses itself with the lower bearing pin against the left boundary of the bearing slot of the plate L and remains in this position. At the same time, the upper end of axis i tilts to the right. This brings the pawl j> into engagement position. As a result of the process described above, the arm of the armature E opposite the more strongly magnetized coil core b is attracted more strongly than that opposite the almost demagnetized iron core α and rests against the iron core b . If a current flows through the coils f and e in the opposite direction, the process is reversed and the coil core a attracts the arm of the armature opposite it. In this way, the armature will alternately strike the coil cores b and α with each current change. The pawl carrier H , which moves in the same direction, will therefore rotate the steering wheel cap by one tooth further in the opposite direction of the clock by means of the pawl φ with every second current change.

Adjustment of the cap when the pawl slides back over the tooth back is prevented by the leaf spring χ and the pressure piece y . If the alternating current flows through the coils h and g , the armature E is attracted to the right and the upper end of the axis i tilts with the pawl carrier H to the left. As a result, the pawl r comes into engagement position. The steering wheel cap is now turned clockwise. The latter position is shown in Fig. 1 and 5 in dotted lines.

Continuous excitation of one or the other pair of electromagnets can now cause the cap F to rotate continuously to the right or left. However, the cap can also be rotated through specific sections by means of short current pulses. In order to achieve the latter, it is necessary to match the duration of the current connection precisely with the lengths of the sections, i.e. the number of helical gear teeth. This is made possible by arranging a time switch known per se.

Claims (2)

Patent Claims: 1. Electrical signal receiver for alternating current, characterized in that a soft iron armature arranged jointly for two opposing pairs of electromagnets is guided by means of a ball bearing in such a way that it is attracted by one or the other electromagnet pair excited by alternating current into the corresponding end position and in this back and forth oscillating movement is set around its longitudinal axis, one or the other of two locking pawls (r, p) arranged on the upper axis extension and acting in opposite directions, depending on the excitation of one or the other pair of magnets, concentrically surrounding the armature longitudinal axis in its central position and sets the signaling gear cap in rotation in one direction or the other. 2. Electrical signal receiver according to claim 1, characterized in that on the lower edge of a cylindrical jacket of the Steigradkappe two through one Separate intermediate piece with opposing and inwardly directed teeth provided ring gears are arranged. 1 sheet of drawings.