DE180618C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

■ - M 180618 CLASS 74 a. GROUP

CONRAD EMMERMANN in Gescher i.W.

of church bells.

Patented in the German Empire on August 3, 1904.

The movement of inevitably moved back and forth within certain limits Bodies, e.g. B. from hammers, produced by electromagnets, is already known. In addition, solenoids are used in house telegraphy, which attract iron cores and let go again after interruption of the current, whereby a hammer is moved back and forth within certain narrow limits will. Similar devices have also been made for heavier hammers in which the solenoids are side by side in pairs are stored. The iron cores connected by yokes, which are drawn into the solenoid openings also only allow the hammer to move back and forth within certain narrow limits, e.g. B. up to, a deflection angle of at most 90 °. This disadvantage includes the use of such drive devices for vibrating bodies Angle of deflection of about 180 ° is completely sufficient. . '.

The thought, the pulling force of the solenoids and the iron cores for the movement of To use church bells with larger oscillation ranges is the following Invention peculiar to itself, which differs from the aforementioned known devices first differs in that the iron cores through the solenoids both after be completely passed through on one side as well as on the other; through this it is achieved that a one-sided loading of the vibrating bell is completely avoided will. A one-sided burden would z. B. occur in the known devices, when the yokes of the iron cores come to rest on one side of the solenoids while the opposite pair of iron cores would be lifted from the vibrating bell; the Bell would then be loaded on one side and significantly prevented from vibrating upwards will. This is associated with the further disadvantage of church bells that while the Bell is inhibited from swinging further upwards, which is also with the bell in clapper of the bell swinging in the same direction with inadmissibly great force against it the bells strikes. This disadvantage makes use of the known Driving devices for ringing bells impossible. By the invention below has it only become possible to drive church bells with larger oscillation ranges, without the bells unilateral loads of any kind and disadvantageous Experience influences.

■ It is also essential in the following invention that several solenoids one above the other are arranged and can thus be switched on one after the other, so that, with relatively large distances of the iron cores, they can be tightened with little effort is achieved. It is known that church bells can be tightened by tightening two Pages are brought into smooth motion. This tightening has so far taken place from

(2nd edition, issued on August 26th igog.)

Hand by pulling ropes attached to a lever arm or pulling wheel on either side of the Bell were attached, alternating in one direction and in the other were drawn.

To replace this two-sided tightening of the bell by hand with electromagnets, forms the idea of the following invention. For this purpose the iron cores or

ίο Electromagnets suspended directly from the pull ropes and attracted by fixed coils.

As can be seen from FIG. 1, the iron cores 2 attached to the cables 1 move and 3 in coils 4, 5 and 6, 7. When the main switch 28 is closed, it becomes the switch 8 closed (see. Fig. 1 and 5), the current flows from switch 8 to the solenoid 5 and back to the power source. The solenoid 5 pulls the iron core when there is a current short 2 and with it the bell. The switch 8 is after tightening the Bell opened again. At the moment when this switch 8 is opened, that is When the bell has been tightened for the first time, the circuit for coil 6 is closed by switch 9 (Figs. 1 and 5). The solenoid 6 pulls the iron core 3 and thus the The bell rings harder on the other side.

The bell and thus also the guide pulley 10 connected to the ropes 1 begins to swing back and forth. Current connection pieces and brushes are arranged on both sides of the guide roller 10, one of which which are located on one side to excite the coils 4 and 5, while those on the other side are intended for the excitation of the coils 6 and 7 are. With the guide roller 10 are attached to both sides of the guide roller 10 contact arms 11 firmly connected, which also carry out the pendulum movement of the bell. Oscillating brushes 12, 13, 14 and 15 are insulated on these contact arms 11 attached, which grind on the contact tracks 16, 17, 18 and 19.

3, 4 and 6 show how these brushes, which are rotatably arranged around fixed bolts 20 brought into connection with the contact arms 11, work with the contact tracks. The helical springs 29 (FIGS. 4 and 6) attached to the contact arms 11 on the one hand and to the brushes 12, 13, 14 and 15 on the other hand hold the brushes in a perpendicular position to the planes of the contact tracks 16, I7, 18 and 19 6, the brushes 12, 13, 14 and 15 are set in their position relative to the contact tracks 16, 17, 18 and 19 in such a way that the contact tracks are touched when the brushes are moved in the indicated arrow direction, ie to the right . This is illustrated in FIG. 6, in which the brush 12 touches the contact track 16 in the position indicated by dotted lines. The brush 12 is thus set shifted by the distance χ relative to the contact track 16. This also applies to the brushes 13,

14 and 15, as well as for the associated contact tracks 17, 18 and 19. The brushes carry an insulating piece 22 on the one hand and on the other hand an electrically conductive piece 21. In the case of the movement to the right indicated above, so becomes a current is not closed because the insulating pieces 22 touch the contact tracks. Are the brushes in the dotted position (Fig. 6) arrived, which for example can correspond to a reversal point of the bell, and now the opposite takes place Moving the brush to the left becomes the conductive part 21 of the brush

15 touch the contact track 19; it takes place a current circuit, and the solenoid 5 is, as shown in Fig. 5, traversed by the current.

This causes the bell to tighten again, which continues accordingly the other side swings out. Before the circuit is opened, the brushes slide via the ones attached to the contact tracks and provided with series resistors Sliders, which reduce the amperage and thus burn the contact surfaces when opening the circuit is avoided.

The same process is repeated for the contact device on the other side for the solenoid 6, since each pair of magnets 4 and 5 BEZW. 6 and 7 an identical contact device Has. The bell therefore continues to ring out.

The arrangement of several tail pieces has the purpose of exciting the coils Establish a current connection at different amplitudes of oscillation. At the largest Oscillation amplitude first glides brush 12 over the contact piece .16 and thereby excites the Coil 4. After the brush 12 has interrupted the circuit for the coil 4, takes place the activation of the coil 5 by the brushes 13, 14 and 15.

If the bells are to be made to ring from a further distance, then with the vibrating roller 10 is connected to a wire coil 24, which is between two electromagnets 25 and 26 swings. The induction current generated in this way is transmitted to a galvanometer 27 mounted at a distance, which makes the bell oscillation recognizable.

The iron cores 2 and 3 can also be replaced by electromagnets. Takes the bell vibrates too much, so

the current can be interrupted by the switch 28 for a short time.

Claims (2)

Patent-to sayings: i. Double-acting electromagnetic drive device for ringing Church bells, characterized in that the guided to the over a roller (10) Pull ropes (i, 1) suspended iron cores (2, 3) through several coils (4, 5, 6, 7) arranged one above the other to the top and are passed through freely below, so that the bell is free and unencumbered Receives vibration, the coils (4, 5, 6, 7) by means of two contact arms with grinding brushes (12, 13, 14, 15), which over corresponding arranged current connection pieces (i6, 17, 18, 19) slide, always only excited and cause the bell to tighten when both on the one Side as well as on the other side has arrived at any reversal point of its oscillation. 2. embodiment of the device according to claim 1, characterized in that that the circuit device consists of concentrically arranged and stepwise elongated sliding surfaces (16, 17, 18, 19) consists, over which pendulum brushes (12, 13, 14, 15) grind the one side (22) insulated and on the other side with a power connector (21) are provided and arranged in groups in such a way that one group (16, 17, i8, 19) when the bell vibrates in one direction the associated coils (4, 5) and the other group (16 ', 17', 18 ', 19 ') the. for the opposite direction of vibration the bell turns on certain coils (6, 7) when the bell vibrates in the other direction. 1 sheet of drawings. Berlin. Printed in the ReichsdruckereI.