US510932A - Electric elevator - Google Patents

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US510932A
US510932A US510932DA US510932A US 510932 A US510932 A US 510932A US 510932D A US510932D A US 510932DA US 510932 A US510932 A US 510932A
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armature
motor
solenoid
switch
circuit
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02PCONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
    • H02P1/00Arrangements for starting electric motors or dynamo-electric converters
    • H02P1/16Arrangements for starting electric motors or dynamo-electric converters for starting dynamo-electric motors or dynamo-electric converters
    • H02P1/18Arrangements for starting electric motors or dynamo-electric converters for starting dynamo-electric motors or dynamo-electric converters for starting an individual dc motor
    • H02P1/20Arrangements for starting electric motors or dynamo-electric converters for starting dynamo-electric motors or dynamo-electric converters for starting an individual dc motor by progressive reduction of resistance in series with armature winding

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  • This invention relates chiefiy to that class of elevators, in which a platform or car is caused to ascend or descend by means of cables attached thereto, which pass over a pulley or drum at the top of the shaft andthence around a winding drum, which may be located on any floor.
  • Such elevators may be divided into two classes: first, those in which the speed of hoisting or lowering may be Varied at will by the operator in the car, this feature being essential in high speed passenger elevators, as it is necessary to slow down just before reaching a landing in order to make an accurate stop at the landing, and, second, those elevators in which the speed of the car is practically constant in both hoisting and lowering oris independent of the control of the operator on the car who simply has the power to start the car either up or down and to stop same.
  • This invention relates to the latter class.
  • the winding drums were driven by belts from a constant source of power, the arrangement being such that when the elevator is not in use the belt runs on a loose pulley.
  • M is an electric motor Which I prefer to be shunt wound and which is connected to constant potential mains, L L.
  • I have shown the motor operatively connected to the winding drum, R of an elevator by a worm G, and a gear wheel G', but the invention is equally applicable to a spur gear or to a belt connection.
  • S is the brake, which is applied by means of the weight WV, which is adjustable on the lever N.
  • This lever may be lifted and the brake released in the old fashioned way by means of a mechanical device connected with the sheave wheel E, around which the operating cable C passes, but I prefer to lift the lever N, and release the brake by means of an electro-magnet or solenoid B, which is connected in the armature circuit or preferably in shunt as shown in the diagram.
  • an electro-magnet or solenoid B which is connected in the armature circuit or preferably in shunt as shown in the diagram.
  • the solenoid As soon as the current is admitted to the coils of this solenoid it sucks in its armature, raises the lever N, and releases the brake.
  • the instant the circuit is opened at any point, by any means, the solenoid is de-energized, and the Weight IV drops and applies the brake.
  • F is a reversing switch, which is preferably actuated by a sheave wheel over which the operating cable passes.
  • Fig. l shows this switch at its central position, at which point both armature and field circuits are open.
  • a pull on the cable in one direction closes both field and armature circuits and causes rotation of the drum in one direction.
  • a pull on the cable in the other direction closes both field and armature circuits and, as the armature is a dia- IOO circuit is' reversed, produces rotation in the Opposite direction.
  • -H is a rheostat which is connected in the armature circuit.
  • the diagram shows the brush on the lowest contacts at which points all the resistance is in circuit, and there should be sufcient 'resistance to protect the armature when at rest from ya current in eX- cess of its safe carrying capacity.
  • the contact brush of this rheostat is attached to the armature ofthesolenoid A, which is connected in a direct shunt to the brushes of the motor, theresistance I-I being outside of the terminals of the shunt. Hence little or no current will flow through the solenoid until the armature commences to turn and to generate a counter-electrc-motive force.
  • the current in the solenoid will increase in proportion to theincrease of counter-electro-motive force generated by the armature and will not be affected in any way by the condition of the rheostat.
  • the solenoid therefore is controlled entirely and only by the difference of potential between the positive and negative sides vof the motor armature.
  • the brake solenoid instantly attracts the armature, raises the weight W, and releases the brake. Unless there is an excessiveloadon 'the lcar the armature will commence at once to revolve, will vaccelerate rapidly, the counterelectro-motive force generated by it will increase and the current through the solenoid A will increase correspondingly, causing it to draw up its armature with increasing power thereby moving the contact brush across the row of contacts on the rheostat, and cutting out resistance step bystep until it reaches the top where the resistance is all out, and the motor is running at full speed.
  • the ⁇ solenoid will work against gravity, preferably, so that the Weight of its armature will resist the'small pull of the' coil due to the little current which may flow through it while themotor armature is stationary; or a spring may be used to accomplish the Vsame thing.
  • h represents a dash pot or air cushion of any suitable construction, used, it necessary, to prevent the ⁇ too rapid 'movement' ⁇ of th'e solenoid armature.
  • I claime- 1 An electric motor having a mainor armature circuit and a shunt or field circuit, and a rheostat in the armature circuit, ⁇ 'in

Description

QNo Model.)
P. A. PERRETs ELECTRIC ELEVVATUR. No. 510,932. Patented Deo.19,1893.
.wf/" 'p W for; X F j W il l UNITED STATES PATENT OFFICE.
FRANK A. PERRET, OF BROOKLYN, NEW YORK, ASSIGNOR TO THE ELEKTRON MANUFACTURING COMPANY, OF NEV YORK.
ELECTRIC ELEVATOR.
SPECIFICATION forming part of Letters Patent No. 510,932, dated December 19, 1893.
Application filed November 12,1892. Serial No. 451,745. (No model.)
To all whom it may concern.-
Be it known that I, FRANK A. PERRET, a citizen of the United States, residing at Brooklyn, in the countyof Kings and State of New York, have invented certain new and useful Improvements in Electric Elevators, of which the following is a full, clear, and exact description.
This invention relates chiefiy to that class of elevators, in which a platform or car is caused to ascend or descend by means of cables attached thereto, which pass over a pulley or drum at the top of the shaft andthence around a winding drum, which may be located on any floor. Such elevators may be divided into two classes: first, those in which the speed of hoisting or lowering may be Varied at will by the operator in the car, this feature being essential in high speed passenger elevators, as it is necessary to slow down just before reaching a landing in order to make an accurate stop at the landing, and, second, those elevators in which the speed of the car is practically constant in both hoisting and lowering oris independent of the control of the operator on the car who simply has the power to start the car either up or down and to stop same. This invention relates to the latter class. Until recently in nearly all elevators of this class the winding drums were driven by belts from a constant source of power, the arrangement being such that when the elevator is not in use the belt runs on a loose pulley. Then the operator desired to go up he pulls the rope passing through the car in one direction which shifts the belt to a tight pulley; pulling the rope back shifts it back to the loose pulley and stops the car; pulling itin the opposite direction shifts another belt onto the tight pulley which moves the carin the opposite direction. Electric motors have been used in many cases as the sources of power and connected thus by belts to the elevators, in which case the motor is usually allowed to run constantly, which is wasteful of current, or the attendant has to go to a line switch and shut off the current to stop it, which is inconvenient. In order to avoid these objections, motors have been coupled direct to the elevator machine and switching devices have been connected to the usual operating cord by means of which the motor is stopped, started and reversed.
The invention herein described is concerned with the starting devices for the electric motor, and, although the description refers to it in connection with an electric elevator, it is Well adapted as a motor starter wherever motors are used, especially for railway motors. In the accompanying drawings: Figure l vrepresents a general view of the apparatus as applied to an elevator, and Fig. 2 gram of the circuits.
Referring to the drawings by letter, M is an electric motor Which I prefer to be shunt wound and which is connected to constant potential mains, L L. I have shown the motor operatively connected to the winding drum, R of an elevator by a worm G, and a gear wheel G', but the invention is equally applicable to a spur gear or to a belt connection. S is the brake, which is applied by means of the weight WV, which is adjustable on the lever N. This lever may be lifted and the brake released in the old fashioned way by means of a mechanical device connected with the sheave wheel E, around which the operating cable C passes, but I prefer to lift the lever N, and release the brake by means of an electro-magnet or solenoid B, which is connected in the armature circuit or preferably in shunt as shown in the diagram. As soon as the current is admitted to the coils of this solenoid it sucks in its armature, raises the lever N, and releases the brake. The instant the circuit is opened at any point, by any means, the solenoid is de-energized, and the Weight IV drops and applies the brake. F is a reversing switch, which is preferably actuated by a sheave wheel over which the operating cable passes. I prefer that the movable portion of this switch should be mounted upon the sheave wheel while the two sets of clips O and P, with which it makes contact, are stationary. Fig. l shows this switch at its central position, at which point both armature and field circuits are open. A pull on the cable in one direction closes both field and armature circuits and causes rotation of the drum in one direction. A pull on the cable in the other direction closes both field and armature circuits and, as the armature is a dia- IOO circuit is' reversed, produces rotation in the Opposite direction. Each set of the clips of this switch. consists of six contact points, three being arranged on each side of ablock of insulating material, and there will be four metallic blades f pivoted to a block of insulating material f carried bythe sheave. Two of these blades are supposed to be directly behind the two shown in Fig. 1. The two blades standing to the right are adapted to make contact with the six clips O, one blade connecting three clips and the other blade the other three clips. The same arrangement occurs on the left handside.
-H is a rheostat which is connected in the armature circuit. The diagram shows the brush on the lowest contacts at which points all the resistance is in circuit, and there should be sufcient 'resistance to protect the armature when at rest from ya current in eX- cess of its safe carrying capacity. The contact brush of this rheostat is attached to the armature ofthesolenoid A, which is connected in a direct shunt to the brushes of the motor, theresistance I-I being outside of the terminals of the shunt. Hence little or no current will flow through the solenoid until the armature commences to turn and to generate a counter-electrc-motive force. Then the current in the solenoid will increase in proportion to theincrease of counter-electro-motive force generated by the armature and will not be affected in any way by the condition of the rheostat. The solenoid therefore is controlled entirely and only by the difference of potential between the positive and negative sides vof the motor armature.
v We will now suppose the switch F to be open, as shown, and that the operator pulls the cable to start the mechanism. This closes the switch F, and the circuit is at once made through the tield magnets and armature `of the motor, the rheostat H, its solenoid A,'and the brake solenoid B. The circuits are traced as follows: Referring to Fig. 2, the dotted lines indicate the two right hand blades f thrown into contact with the two groups O of. three clips each. When the switch is in this position the current is led from the positiveV line to vclip 1, thence to clip 2, along the switch bladeto clip 3, thence by wired through the armature of the motor, wire 5, rheostat H, wi re 6, clip 7, switch blade, clip 8, wire 9 tothe'negativemain. Thelield magneticcircuitbranches at clip 3 and isled through the switch blade to clip 10, thence by wire 1l, wire12, through the ield magnet, wire13,wire 14, clip 15, andjoins the armature 'circuit at clip 7. Thebrake solenoid B is connected in wire 16 across the armature and outside of the rheostat H. The controlling solenoid A isin circuit 17 directly across the brushes of the motor. The brake solenoid instantly attracts the armature, raises the weight W, and releases the brake. Unless there is an excessiveloadon 'the lcar the armature will commence at once to revolve, will vaccelerate rapidly, the counterelectro-motive force generated by it will increase and the current through the solenoid A will increase correspondingly, causing it to draw up its armature with increasing power thereby moving the contact brush across the row of contacts on the rheostat, and cutting out resistance step bystep until it reaches the top where the resistance is all out, and the motor is running at full speed.
In case there should be an excessive load on the car or it is prevented from moving v freely, the current, which is at first admitted to ,the armature through the rheostat, will not start the motor; consequently, the solenoid A, will receive practically no current, and will not 'attract its armature with suiicient power to' move the contact brush'on the rheostat. Consequently, no resistance 'will be cut out. The operator seeing that the motor does not start, will open his switch, and will hunt up the trouble, or if it is overloaded will ask somebody to step' out.
The` solenoid will work against gravity, preferably, so that the Weight of its armature will resist the'small pull of the' coil due to the little current which may flow through it while themotor armature is stationary; or a spring may be used to accomplish the Vsame thing. h represents a dash pot or air cushion of any suitable construction, used, it necessary, to prevent the` too rapid 'movement' `of th'e solenoid armature.
We'will now suppose the mechanism vto have been put into operation as already described, and that a stop is to be made. .The operator pulls the cord until the switch reaches the centralpoint where a stop i will prevent its going farther, until thel contact brush of the rheostat has droppedv again' to the bottom and all the resistance' is inv circuit. This stop vis held against the periphery'ot the switch wheel lwhile the 'motor is running, but when the wheel is moved to the middle position-to stop 'the motor, it falls into the notch andlocks the wheel until'it'is removed therefrom by the endrof the resistance'controlling arm when it reaches the point where all-the resistance is in circuit. This prevents reversing until the resistance is put in. As soon as the circuit has 'been broken at the switch F as just described, the solenoid B is de-energized andthe brake is applied. It. will be seen that this principle of controlling the starting of the motor by the counterelectro-motive torce generated by the motor armature is', applicable to 'motors driving railway vcars or any other apparatus and isa sure protectionto the motor.
Having described my invention, I claime- 1. An electric motor having a mainor armature circuit and a shunt or field circuit, and a rheostat in the armature circuit,^'in
combination with a third ycircuit including an electro-responsivev apparatus controlling kthe rheostat, said third circuitA being a'direct ICO IIO
shunt to the'brushes of the motor, substanlocking device substantially as and for the tia'lly as described. purpose set forth. 1o
2. The combination, of an electric motor In testimony whereof I subscribe my sigand its circuit, an electric switch controlling nature in presence of two Witnesses.
5 said circuit, a locking device for said switch FRANK A. PERRET.
when in its open position, a rheost-at in Witnesses: the motor circuit and an electro responsive WM. A. ROSENBAUM,
apparatus operating the rheostat and the said JOS. J. UHL.
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20050255528A1 (en) * 2002-08-20 2005-11-17 Quest Diagnostics Investments Incorporated Hydrophilic chemiluminescent acridinium labeling reagents

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20050255528A1 (en) * 2002-08-20 2005-11-17 Quest Diagnostics Investments Incorporated Hydrophilic chemiluminescent acridinium labeling reagents

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