DE71300C - Electrically operated elevator with a control device influenced by the elevator - Google Patents

Description

IMPERIAL A

PATENT OFFICE.

PATENT LETTERING

CLASS 21: Electrical apparatus and machines.

RUDOLF EICKEMEYER in YONKERS (Westchester, New York State, V. St. Α.).

Patented in the German Empire on January 13, 1891.

Up to now, steam or hydraulic motors have mostly been used to operate elevators used, whose movements from the inside of the elevator always mean one there reachable hand line were controlled by a passenger.

The main requirements of a good elevator are speed of movement, a safe initiation of the upward as well as the downward movement and also safe stopping. To increase the safety in the company, it is considered to be best to use the winch drums for the cables carrying the elevator to be coupled to the drive machine in such a way that that for raising and lowering the elevator, the drive machine is in opposite directions Directions must be operated.

Elevator systems with electrical operation have already been used on various occasions, however, as far as has become known, these seem to have met the above-mentioned requirements so far not to have sufficed to the same extent as those furnished with the earlier resources.

The present invention relates to an elevator device with electrical operation, which also has cables and two-way rotatable drums for winding of the cable come into use, with an electric driving machine with the same Security for your individual parts by means of something accessible from inside the elevator Hand line can be set in motion, stopped and reversed just as safely as any other elevator with direct hydraulic or steam engine operation.

In the drawings further illustrating the present invention, FIG. 1 is a Side view of the lifting device, in which the type of arrangement of the attached elevator is shown schematically, Fig. 2 is a corresponding basic outline of this lifting device, 3 shows a side view of the electric driving machine together with the devices for driving it the cable drum, partially drawn in section to illustrate the transmission. Fig. 4 is a plan view of Fig. 3, but showing part of the cable drum and the Base plate is shown broken off. Fig. 5 is a sectional view of the braking device of the machine, Fig. 6 is a front view of the safety device, which here in enlarged Scale and shown separately from the machine, Fig. 7 is a front view of the switching and reversing device, also shown separately and on an enlarged scale. Fig. 8 is a vertical cross section and FIG. 9 is a horizontal cross section of the same device. Fig. 10 is a schematic Representation of the circuits and their connections. Fig. 1 1 is a Aufrifs one Modified embodiment and illustrates devices to the pole ends of the Circuit immediately and very far away from each other, Fig. 12 one of FIG. 11 corresponding Side view, partly in section, and FIG. 13 a corresponding vertical one Cut, seen from the opposite side.

(2nd edition, issued on February 21, igoo.S

Fig. 14 is a schematic diagram and illustrates that in the modified embodiment Current circuit arrangement in use.

The cable drum B and its drive device rest on a base plate A with a suitable pad; the rope C carrying the elevator D is wound up and down on B , depending on whether the elevator is to be raised or lowered. The axis b of the cable drum B rests in bearings on the base plate A and carries a worm wheel E, which meshes with the worm F on the shaft of the driving machine M and thus transfers the movement to the drum (Fig. 1 to 3).

The electric driving machine is one with secondary winding and within certain Self-regulating boundaries. The arrangement of the individual parts is so arranged that first of all in the rest position, both the field and the armature are switched off; during commissioning the machine in one direction or the other is only excited by the magnetic field the current is allowed to enter the excitation winding; then also in the Armature circuit gradually let in the current until finally the full current of the circuit has its effect on the machine. But now the resistance in the armature is at standstill so small that the armature coils could easily be burned if the machine were to run for whatever reason, for example as a result of being overloaded with the elevator or getting stuck the same, should not get going. Because of this is a safety device provided, through which an external resistance is included in the armature circuit for so long becomes like the current that the armature would otherwise receive is stronger than allowable. When the driving machine gets going and the counter electromotive force in the armature increases, that external resistance becomes automatic reduced or completely canceled. To bring the driving machine to a standstill, the resistance, which has meanwhile been automatically removed from the armature circuit, will initially open mechanically switched on again, the current gradually first out of the armature and last removed from the excitation circuit.

In the schematic representation of Fig. 10, the arrangement of the switching, reversing and safety device, as well as the various connections in the generator and driving machine circuit is illustrated. The electric power generator G is connected on the one hand by the line 1 to the arcuate Stromschlufsplatten 2 and 3 of the switchboard and on the other hand by the line 4 with the plates 5, 6, 7 and 8; One pole end of the line of the exciter circuit of the driving machine M is connected to the plates 2 and 3, the latter always being directly connected to one pole end of the line of the power generator, while the other pole end of the line of the exciter circuit of the machine M is connected to the plates 11 and 12 is connected.

In the middle of all the curved plates of the switchboard there is a shaft / on which three brushes or slide springs (Figs. 7, 8, and g), insulated from one another, are attached. In the position illustrated by FIGS. 7 and 10, these brushes rest on an insulating base of slate, glass, etc. The shaft / can be moved from the hand lever or hand rope by means of levers and cogwheels in such a way that the one sitting at its end carries the brushes Arm turns right or left. The plates 7 and 8 are through the plate 5 in the circuit with one of the poles of the generator, while the plates 11 and 12 with one pole of the field coil of the machine M and the other pole of the field coil with the other pole of the generator Circuit.

The shorter one in the brush is chosen with regard to its size so that it electrically connects the plates 8 and 12 of the inner circle of power supply plates with one another when the brushes are rotated from their vertical position in one direction, while when they are rotated in the opposite direction the same brush m the Stromschlufsplatten 7 and 1 1 connects with each other. In both cases the current goes in the same direction from the generator through the field coil of the driving machine and excites the field.

The electric current must be fed to the armature very gradually and therefore accordingly decrease. For this purpose a number of resistance coils are provided, which are used by the operator of the machine are switched off and on, namely the plates and brushes of the switch are like this arranged that the same resistance coils are used, regardless of whether the current from the Generators in one or the other opposite direction through the anchor the driving machine goes.

The terminals of the resistance coils are, as shown in Fig. 10 at r, connected to the insulated plates η of the change-over switch, each of which is connected by a wire to a correspondingly arranged plate n 'in the manner indicated by the dotted lines . The length of the brushes m ' and m " is set up in such a way that, on the one hand, the brush m' has a pair of opposing plates in the middle row and, on the other hand, the brush m" each

electrically connect the opposing plates of the outer row to one another.

After the type of connection of the poles of the generator with the plates of the changeover switch has already been described above, the mode of operation of the device m ' and m ", when it is rotated in one direction or another, will now be explained:

If the brushes are first rotated to the right into the position indicated by the line x-jy, FIG. 7, the electrical circuit of the armature of the machine is closed at the moment when the brushes come into contact with the arcuate plates. The current is, as can be seen from FIG. 10, from the line 1 to the plate 2, through the brush m " to the first plate at n, through the resistance coils r over to the plate n", through the coil 13 of the automatic control device and through their resistance coils r ' to the one brush ο of the machine, through its armature and the other brush 0' and from there through the plates 9 and 10 and the brush m ' to the plate 6, the. go with this electrically connected plate 5 and from this through the line 4, whereby the circuit of the generator is closed.

If the brushes are rotated further in the same direction, one resistance coil r after the other is switched off until they are all switched off when the brushes have reached the position indicated by the line χ -y and only the resistance coils r 'in remain switched on in the armature circuit. If the brushes are now turned back to their original position, the resistance coils r are gradually switched back into the circuit. When the brushes have finally reached their insulating backing, the circuit is interrupted. If the brushes are now turned to the left so that the plates n 'are touched, the circuit is closed again; on the other hand, the current now flows through the armature in a direction opposite to that described above and, coming from the line 1, takes its course from the plate 3 through the brush m ' to the plate g, after the brush o', through the armature and the brush 0, through the resistor and regulator coils r ' respectively. 13 to the plate ' n " and through the brush m" to the plate 5 and from there to the other pole of the generator.

The automatic safety device is shown separately from the machine in FIG. 6 and essentially consists of a correspondingly shaped wire spool 13 into which an arcuate iron core, as indicated in FIG. 6 by dotted lines, protrudes loosely. The same is fastened with its one end to one arm of an angle lever 14, which in turn sits on a shaft mounted in a corresponding frame at s, FIG. 9. At one approach of the angle lever 14 sits a brush or slide spring 15 which is in contact with a row of plates 16 forming the terminals of the resistance coils r '. The short arm 17 of the angle lever 14 carries a small roller which rests movably in a curved guide 18 seated on the shaft.

In the arrangement shown in FIGS. 1 to 4, a horizontally displaceable rod ig is moved either from the hand line, as in FIGS. 1 and 2, or by a hand lever, as in FIGS. 3 and 4. The rod is provided with stops g ' and g " which limit the movement of the rod, and at 20 with an arcuate notch which serves to activate the braking device. The drawing shows the rod in its central position From this position you can move the rod by pulling the hand rope or hand lever in its horizontal longitudinal direction to the right or left as far as the stops g ' or g " allow. By this right or left movement of the rod 19, the brake pad 21, which is weighted down, is lifted from the brake wheel 22 located on the shaft of the driving machine M , so that the armature can now rotate.

In the present arrangement, the rod 19 serves at the same time to set the switching device in action; however, the arrangement can also be made in such a way that this is done directly by means of the hand lever or the hand rope or in another corresponding manner. The transmission of the movement from the rod 19 to the shaft I of the switching device takes place here by means of a lever 23 rotatably mounted in the frame, one arm of which is provided with a guide slot for receiving a pin located on the rod 19, while the other lever arm on his upper end forms a toothed circular arc section 24 which is in engagement with a corresponding second tooth segment 25 on the shaft / switch.

The lever 23 and the segments 24 and 25 are arranged with respect to their Gröfsenverhältnisse and their arrangement to each other so, g That the greatest by the stops' and g "authorized longitudinal movement of the rod 19 about a _^2/5 turn of the switch shaft / equivalent, so the brushes

the switching device can move from the position indicated by the line x'-y ³ to the position indicated by x "-y" or vice versa (FIG. 7).

Assuming that the brushes of the switching device and the rod 19 are in the position shown in the drawing, the braking device is activated, the motor circuits are interrupted and the angle lever 14 is held by the arch guide 18 in such a position that the iron core is completely in the Wire coil 13 and is enclosed by this. If the rod 19 is now moved in one direction up to the one stop, the brushes of the control board will move over this up to the position x'-y ' or x "-y" . The curved guide 18 on the shaft / seated likewise moves accordingly and is shaped in such a way that it holds the angle lever 14 in its position indicated above until the switch brushes have switched off all resistances at r.

As can be seen from the drawing, the guide 18 is circular in the middle of its path and then widens towards both ends. As long as the roller on the lever arm 17 moves in the central circular part of the guide, the magnetic core is held inside the solenoid; but as soon as the roller has left the central circular part of the guide, the angle lever 14 can move freely again, the iron core can swing out of the coil s again and the brush or slide spring 15 move over the semi-cylindrical surface of the switching device, thereby increasing the resistances r ' switch off.

But now the coil 13 is in the circuit with the armature and has such a number Windings so that they always hold the iron core in its position and, if it does, the armature circuit the current flowing through it for some reason unduly strong and for the Machine should become harmful, a resistance-eliminating movement of the iron core will prevent.

When the machine M comes to a standstill by moving the rod 19 in the opposite direction, the iron core is first pushed into the wire coil 13 and the resistors r ' are thereby gradually switched into the armature circuit. Then the resistance coils r are gradually switched on and finally the armature circuit is interrupted. If the same movement of the rod is continued a little further, the field circuit is also interrupted and the braking device stops the machine until the rod 19 is moved again in one direction or the other and the processes described above are repeated.

With the facilities described above, all precautions have been taken to protect the electrical operating machine from any danger during electrical elevator operation that could arise from an unusual current if such a current should flow through the armature. When the machine is to start up, the circuit is first closed in such a way that there is a considerable resistance in series connection in the armature, which resistance is gradually reduced again as the speed of movement of the armature increases. From the first moment when the electric circuit is closed and until the maximum is reached, the field magnet coils receive the strongest current, with the result that the field magnet, when the machine is in operation, always produces the greatest development of force Lever 14 of the automatic safety device is set up in such a way that in the event of any malfunction, for example failure of the transmission actuating the switching device, the safety device falls into the position shown in Fig. 6 by virtue of the arrangement of the center of gravity the armature receives no current, a harmful effect does not occur; however, if a current were to be found in the armature winding, the core of the coil 13 would immediately be drawn into it and the necessary resistance would be switched on in order to keep the current within safe limits In this position shown in FIG g there are all resistance coils r 'connected in series in the armature circuit, and this is the correct position when the machine is started. As a result of the restriction of the movement of the angle lever 14, 17 by the circular part of the guide 18, the safety device is forcibly kept in a certain position such that when the machine M is started and stopped, the brush 15 keeps all the resistances r ' switched on; but after setting in motion the brushes mm 'm "a certain portion of their movement have made, has the leadership thus rotated so far, that the individual parts of the safety device from the mechanical impediment are exempt and the position of the brush 15 with respect to the plates 16 is now automatically determined by the main current flowing through the armature, while this in turn is dependent on the speed at which the armature rotates

The machine causes the guide 18 to move by their circular part, so that the movable nucleus assumes its safety position again and the brush 15 enters the position illustrated in FIGS. 6 and 10.

The automatic stop of the elevator D when it reaches the upper and lower end point of its path is caused by the obstacles or balls α attached to the hand rope, which hit against projections on the elevator, so that the hand rope is tightened and the rod ig in the manner described above is moved, the switching device comes into effect and the braking device brakes the shaft of the driving machine.

In the embodiment of the present invention described above, three switching brushes mm 'm " are used, the brushes m' and m" being used to switch off and reversing the armature current and the brush m to close and interrupt the field coil circuit of the driving machine. But if, for whatever reason, this brush m is removed only a little or very slowly from the edges of the plates 11 or 12, it may happen that an arc of closure arises and lasts for a while, so that the brush may not break the circuit at the right moment completely interrupted or the brush itself is more or less damaged by the closing arch.

This is now prevented by the somewhat modified arrangement illustrated in FIGS. 11, 12, 13 and 14. The switching device is moved here partly by hand and partly by a spring in such a way that the relevant parts of the switching device are first brought into such a position by hand that the movement necessary for the field switch is caused by the force stored in the spring will. For this purpose, instead of the plates 1 1 and 12, two plates 30, 30 attached to the frame and, instead of the brush m, the metal rod 3 1 are provided. These two plates are in the same sense as the plates 11 and 12 in the circuit with the generator, while the metal rod 31 is connected to the other pole of the generator. The prime mover circuit is included in the line as soon as the rod 31 is brought into contact with one or the other of the plates 30; but if the rod is between the two plates, the circuit is interrupted.

The further arrangement and mode of operation is as follows: The arm 32, FIG. 11, is attached to the shaft / and has two laterally protruding pins 33, 34 at its end; on a shaft 36 sits a wheel 35 provided with three teeth, the teeth of which with one or the other pin 33 respectively. 34 of the arm 32 are engaged. Furthermore, a guide with three corresponding notches is attached to the guide wheel 35, into one or the other of which the friction roller 37 of an angle lever 38 is pressed by a tension spring 39. In the position shown in Fig. 11, the roller 37 presses into the central notch and the pins 33, 34 of the arm 32 are between the teeth of the wheel 35. In this position of the parts to one another, the metal rod 31 is on an interrupted circuit and flows no power from the line through the prime mover. If the shaft / arm 32 is now moved to one side by rotating, one of the pins 33, 34 will come into contact with the central tooth of the wheel 35. If this movement is continued, the roller of the angle lever 38 will move up the side of the next notch of the guide until it has reached the highest point; then, by virtue of the tension spring, the wheel 35 will continue to rotate faster in the same direction and thereby bring the switching rod 31 into contact with one of the plates 33 or 34, so that the driving machine circuit is now closed. As already noted, the arm 32 can be moved further together with the switch brushes m 'm " ; but if the driving machine is to be brought to a standstill and the movement of the arm 32 is reversed by the shaft, the pins are again with the teeth of the wheel 30 come into engagement and the process just described is repeated in that the roller 37 rises on the guide to the highest point of the same and, with continued movement, the spring 39 comes into effect, throws the wheel 35 around and thereby pushes the rod into the position shown in FIG 11, in which the circuit is interrupted. In this way, both when closing and when interrupting the driving machine circuit, a rapid movement of the parts involved is achieved and arcing is prevented at the points concerned.

In the case of the one shown in FIGS. 11, 12, 13 and 14 The connections are arranged in such a way that the whole current does the switching 30, 31 flows through; The latter, however, is not necessary; it can rather be the arrangement described earlier can be retained, the switchover 30, 31 only could be used for the field magnet circuit.

Claims (1)

Patent claims: ι. An elevator device with electrical operation, in which an elevator (D) connected to an electric driving machine connected in a bypass circuit, with a switching device for the electric current controlled from the elevator, as well as with two separate groups of resistors frr'J that can be switched into the armature circuit , a solenoid (13) with the core partially inevitably moved by the switching device and with a braking device (21, 22) controlled from the elevator in such a way that both groups of resistors are switched on when the machine is started, first the field circuit and then the Armature circuit is closed, but then only one group of resistors can be switched off mechanically, while the other group is included in the armature circuit and protected from any external influence as long as the current that the armature would otherwise receive is greater than permissible i st, and then only gradually and automatically switches off or. regulates that, conversely, in order to bring the machine to a standstill, both groups of resistors are gradually switched on again by mechanical means and first the armature and then the excitation circuit are interrupted when the braking device is actuated. In the elevator device identified under 1., a changeover switch, in which several rows of power circuit boards are arranged in symmetrical groups, each of which has two power circuit boards opposite one another on different sides of the center of corresponding rows of common pairs of several power circuit brushes insulated from one another in pairs (mm ¹ m ² ) of a switching arm movable over the power supply plates are touched, all of the power supply plates being provided with circuit connections in such a way that the current is reversed when the brushes move from one group of power supply plates to the other.
In connection with the elevator device identified under 1., a safety device consisting of an arcuate wire coil (13) influenced by the armature circuit, in which a correspondingly designed toggle lever (14, 17), which carries the brush (15), is fastened, from the to the switch shaft (I) seated Curve guide (18) swings necessarily guided iron core in such a way, that he upon rotation of the switch shaft (I), the resistors (at 16) turns off, but selbstthätig drawn at unduly strong armature circuit of the same in the coil and the resistors (at 16) switches on again accordingly. 1 sheet of drawings.