DE711020C - Route block setup - Google Patents

Description

Line block device The invention relates to a line block device, which, if only one lead wire and earth are used, protect against external currents offers sufficient security, for example by line contact with a Another block line or other current-carrying lines sitting on the same rod Lines can get into the block field. In addition, it is achieved that that too Blocking through and counter-blocking is impossible.

The invention relates not only to the drive of the block field, but also to the switching of the block device of a two-track line. The most essential part of the known devices is a steering wheel, which is controlled by an escapement; the latter again an electromagnet in oscillating movement is offset by the polarized anchor as soon as the winding of the same is fed by an alternating current of about 1 5 periods.

According to the invention, the pendulum movement of the escapement necessary to trigger the block field is achieved by using a drive whose direction of rotation depends on whether a direct current is superimposed on the operating alternating current or not, the direction of the direct current also playing a role at the same time. The drive is shown in principle in FIGS. Intermediate, i the poles and 2 of an AC solenoid is provided with a kurgeschlossenen winding 3 rotating armature 4, which - is composed of iron sheets stored, which, if the magnet winding 6 "7 is flowed through by alternating current, to rotate counterclockwise in the illustrated coil layer Nothing changes in the direction of rotation even if a blocking cell 5 is switched on in the circuit of the winding 3 of the rotating armature 4, the torque being reduced by a certain value.

If a direct current is superimposed on the alternating current flowing through the magnet coils 6 and 7 , a rectified magnetic field is superimposed on the alternating field in the stator iron, the direction of which in FIG. 2 runs from top to bottom. This does not change the direction of rotation.

As a result of the interaction between the magnetic field pulsing in the rotating armature and the direct current field occurring in the stator, a torque arises which is either the same (Fig. 2) or opposite (Fig. 3) to the torque occurring when using pure alternating current (Fig. I), depending on the direction of the direct current superimposed on the alternating current. By suitable dimensioning of the rotary armature and the winding can be achieved that both the same size, the difference in the latter case (Fig. 3), but oppositely directed overall as the torque at Venwendung pure alternating current (Fig. I). Since the direction of current in the rotating armature winding depends on the position of the blocking cell, there is still the possibility of obtaining the opposite torques than those shown in FIGS.

The drive is polarized in this way. In order to achieve the pendulum movement of the rotating armature, the current curve shown in FIG. 4 is necessary. It arises from the fact that a direct current is superimposed on the alternating current at certain time intervals, expediently in such a way that the superimposition times are approximately equal to the periods of time in which only the alternating current flows, and that such a period of time consists of at least three half-waves. A battery can be used as a direct current source, which is temporarily switched into the alternating current circuit with the aid of a rotary switch coupled to the inductor (E). Instead of the battery, a blocking cell can also be used, which is short-circuited by the rotary switch if it should not be effective (F).

The invention is illustrated in FIGS. 5 and 6 using two block fields that work together. The rotary switch is indicated by switch 8. Each block field drive has a double-pole changeover switch 9, I0 or 11, 12 coupled to the push rod, with the help of which, when the button is pressed, only the current of the inductor belonging to the block field can be activated, while in the rest position of the field only the current pulse of the inductor of the other ; »- ,. f block field can act. The arrows drawn to the left of the drive (FIG. 5) indicate the direction of the direct current component to which the block field drive responds. This circuit ensures that the current of the inductor in A cannot trigger the block field in B when the button in B is pressed. Fig. 5 shows the circuit in the rest position, Fig. 6 shows the state that occurs when the B button is pressed.

Fig. 7 and 8 show the circuit for blocking the route of a double-track railway. In order to prevent that a block field of the neighboring line becomes free at the wrong time when the two block lines are touched, the arrangement is made so that the effective direction of the direct current in the two end fields, e.g. B. 2o and 5o of each exhaust section is the same as indicated by arrows, as well as that in the two top panels, z. B. 4o and 3o, but the direction of the direct current in the two groups mentioned above is chosen to be opposite (see e.g. fields 2o and 40).

An example of line contact is given in FIG. 7. The strongly drawn out current over the fields 30, 50, 70, 90 arises when operating the section block in B during the train journey from 13 to C. If the two block lines between the block points A and B or B or C or even, as assumed, touch at both points, partial flows go from the point of contact through the block fields for the opposite direction of travel, i.e. 20, 40, 6o, 8o. The direction of this external flow, dashed arrows, is in all of these fields, however, the opposite of that of the regular block flow.

Since the circuit is symmetrical, an external current has an exact effect so when driving in the direction of D # -C.

In order to prevent blocking through, the arrangement is made in such a way that that the polarity of the corresponding block drives in the two neighboring ones Sections is different; the direction of the to trigger a block field Alternating current to be stored direct current is in the corresponding fields Neighboring sections the opposite.

An example of this is given in FIG.

When operating the block in B for a train journey from B to A , the thick, drawn-out circuit is created. If the community button at the same time in C, as seen from the position of the associated contacts, the current from the inductor flows into B by the burst fields of the ex-section DC, shown in phantom. From the arrows, however, it can be seen that it is opposite to the normal direction of the current, so that fields I00 to 120 cannot be actuated.

Claims (2)

PATENT CLAIMS: i. Route block device, characterized in that that the pendulum movement of the drive member necessary to trigger a block field (Inhibition) is caused by two alternating alternating currents, one of which one of which is superimposed by a direct current. 2. Distance block device according to claim i, characterized in that a pulse of at least three half-waves is necessary for each change in position of the drive member (inhibition). . 3. Route block device according to claim i. and 2, characterized in that one series of trigger pulses consists of pure alternating current, the other consists of half-wave current. 4. Line block device according to claim i to 3, characterized in that the pulsating current component is formed by switching on a valve cell in the AC circuit, such that the valve cell is short-circuited by a rotary switch in the moments in which the pure alternating current is to act . 5. Line block device according to claim i to 4, characterized in that the current necessary to dissolve a block field, which comes from the associated inductor, when the button is pressed with the aid of a double-pole changeover switch coupled with this (push rod contact) in the effective direction through the winding of the drive is conducted and that the direction of the pulsating current coming from the inductor of the corresponding field is chosen so that it has no influence on the field. 6. Route block device according to claim i to 5, characterized in that the start fields belonging to a block section have the opposite polarity than the two end fields. 7. route block device according to claim i to 6, characterized in that the polarity of the individual block fields in the adjacent sections is the opposite.