CH257262A - Installation and automatic operation for the remote control of motor vehicles. - Google Patents

Description

  

  Installation and automatic operation for the remote control of motor vehicles. The ob, iet de la. present invention is an automatically operating iicstallation for the. remote control of vehicles -a. n1 ote urs.



  This installation finds its application more particularly in self-propelled vehicles comprising a - two-way direction (1onimandes arranged, for example, in parallel on either side of the longitudinal axis of the cehicle; when this direction is present be the form of two complexes. of organs;: ssiirant also the propulsion and that these complexes:

      are animated by identical movements .., the vehicle is propelled in a straight line, forwards or backwards; when one of the (! ispositives is: stopped, the other, by continuing = we provide propulsion, produces around the reaction center of the first a rotating movement which ensures the re change in the direction of the vehicle.



  The present invention relates to. an automatic installation for the: remote control of motor vehicles, in which a single relay acting on a selector mechanism causes, by its more or less long closing times, commands allowing the man # uvrc # of. vehicle.



       According to. In the invention, the selector mechanism always causes a change of direction when it is operated for a short time, on the other hand a change in the direction of travel of the vehicle each time it is operated for a long time.



  An embodiment of the installation according to the. The present invention is shown, by way of example and schematically, in the accompanying drawing.



  The embodiment described and shown as a whole relates to the case of a land vehicle.



  This vehicle, which is not shown in the drawing, comprises a gasoline engine, a clutch, a gearbox with four forward speeds and a reverse speed controlled by players and shown schematically; this vehicle also comprises various components shown schematically in the drawing, such as:

    accumulator battery, starter motor also forming a charge dynamo (called dynastart), a double contact charging circuit breaker, an ignition coil, an accelerator (throttle control) represented by its throttle valve, two lateral propulsion devices also ensuring changes of direction, each having a clutch and a brake, the electromagnetic control of these clutches and brakes being the only one shown in the diagram.



  As can be seen in the appended drawing, the accumulator battery 5, the negative pole of which is grounded, supplies the conductor 6 via its positive pole, one branch of which leads to the switch 7 which may be remotely controlled by a device represented by its box 7 '; this conductor 6 is thus connected to conductor 8 which energizes relay 9, the output of relay 9 returns to the negative pole of the battery via conductor 10 and earth;

   the conductor 8, via a bypass 8 ', supplies the same relay 9 in parallel via the switch 10' which is open when the relay is energized.



  The relay 9 makes it possible to connect the conductors 11 and 11 'which supply, on the one hand, the conductor 12 and, on the other hand, the conductor 13 which can be cut off by the switch 13'; the conductor 12 supplies the internal coil 14 of the electro 15, the output 15 'of which is connected to the negative of the battery; , the conductor 13 supplies the external coil 14 'of the electro 15, the output of this coil 14' being connected to the output 15 ';

   a branch 1.2 'of the conductor 12, capable of being cut off by the switch 16, supplies the coil 16' of the electro 17; the output 17 'of the coil 16' is connected to the negative of the battery by the mass;

   branch 6 'of conductor 6, controlled by switch 18, energizes relay 19, the output 19' of which is connected to the negative of the battery. The relay 19 controls the switch 20 which establishes contact between the conductor 6 'and the conductor 21 which powers the dynastart 21', the output of which is connected to the negative of the battery by the conductor 21 ".

   The charging current of the. dynastart passes through the conductor 22 which feeds the fine wire coil 22 ', the output of which is connected by the conductor 23 to the conductor 6; the charging current also passes through the conductor 24 which supplies the coarse wire winding 24 ', the output of which is connected to the conductor 23 by the switch 23'. The windings 22 'and 24' energize the circuit breaker which controls the switches 19 "and 23 '.

   A branch 102 starting from the conductor 6 'and controlled by the switch 103 supplies the second coil 102' of the relay 19, the output 19 'of which is controlled by the switch <B> 19 "; </B> this branch 102 is also connected to conductor 104 which is supplied in the form of a pulse by switches described below.



  A branch 25 of the conductor 6 is linked, by the switch 18, to the conductor 25 'which supplies the fine wire spool 26 of the electro 27. the output 26' of the fine wire spool 26 is connected to the negative of battery 5; a branch 28 of the conductor 25 'is connected, by means of the switch 28', to the conductor 28 "which supplies the external coil 29 of the electro 27, the output 29 'of the coil 29 is connected to the negative of battery 5;

   a bypass 30 of the conductor 6 supplies, via the switch 18, the conductor 30 'which supplies the internal coil 31 of the electro 32, the output 30 "of the coil 31 is connected to the negative of the battery; a -dérivation 33 of the conductor 30 'feeds, via the switch 33', the conductor 33 "which supplies the coil, exté, rieuTe 34 of the electro 32, the output 34 'of the coil 34 is connected to the negative of battery 5;

   a branch 35 of the conductor 11 'to. 143 'passes through the thermally deformable blade 105, through switch 35', through resistors 36 and 36 ', the output 36 "of which is connected to the negative of the battery;

      the switch 35 ', controlled by the thermally deformable blade 105, makes it possible, depending on the temperature imposed on this blade, to take the current through resistors 36 and 36' in series or directly through resistor 36 'without passing by resistance 36;

   the conductor 6 supplies a bypass 106 which is controlled by the switch 107 and which supplies, by the conductor 106 'and the switch 108 with thermally deformable blade 109, the low voltage circuit 110 of the device of 'ignition, whose output 110' is connected to the negative of the battery;

      a branch 41 of the conductor 6 can supply the conductor 42 when the switch 42 'is closed, the conductor 42 supplies the coil 43' of the electro 43 whose output 43 "is connected to the negative of the battery; vation 111, starting from the conductor 6, can supply, by the brush 112, the ring segment 112 'of the rotary switch 113 which can alternately supply the circuits 25' and 30 'by the brushes 114 -and 115;

   the brushes 111 and 1.15 are set at exactly 90, opposite the brush 112; a bypass <B> 116 </B> of the controller 6 feeds the brushes 117 and 11.8 which unite alternately in contact with the conductor bar 119 of the rotary switch 120 to alternately feed the l, rilai; 121 and 122: the brushes 117, 118, 121 and 122 are wedged at 90 from each other;

   the driver: eur 1:23, which starts from the brush 122, supplies 1i @, terminals <I> a </I> and <I> b </I> which are part of the automatic centrifugal device 124 controlling the circuits of excitation of the electros producing Ie, niana @ works of gear changes at the tilovc # ri of the inverters l25, 126 e + 127 which move successively bridge a-ri <I>, </I> c - c ',

            (1-d ', e-e'. Ff 'and g-g', lr, -lr, ',% ---%'; the ,,; plots a'-cl-f are linked together by the conductor 128; the -gi pads are connected to each other by the conductor 129; the pads: c-c'-h are connected by the branch 13 @@ of the conductor 6;

   the pads c'-e-h 'are connected: to each other and to the conductor 104; 1st pad b 'is connected to circuit 131 which controls the. first gear; the pad f 'is connected or circuit 132 which controls the second speed; plot i. ' is connected to circuit 133 which coinniande la. third gear; pad g 'is]' (1W1 to circuit 134 which controls the fourth speed;

   reverse gear is driven # by circuit 135 which is connected directly to brush 12l. of the rotary switch 120.



  The mechanical drive 136 of the centrifugal device 124 is secured by the transmission 1.37 of the. gearbox 138; this mechanical drive takes place through the intermediary of a clutch. torque limiter <B> 139 </B> which, when disengaged, sets roundness 140 to. Earth; this establishes a current flow in coil 141 of relay 142, the input of which is connected by conductor 143 to conductor 6;

   this conductenr 143 is also connected to the second l) ohine 1.4.1 of relay 142, the output 145 of this coil 144 being put to earth by the two switches 146 and 147 which are in parallel with the conductor 145 ; switch 146 @ is closed when electro 32 is not energized, and switch 147 is likewise closed when electro 27 is not energized;

    when the relay 142 is energized, the switch 148 connects the branch 143 of the conductor 6 with the conductor 13; switch 149 links lead 104 'of lead 104 to lead 143 of lead 6 when lead 142 is energized;

   switch 150, when relay 142 is energized, connects the. derivation 143 from conductor 6 to conductor 151 including the. derivation <B> 1.52 </B> leads to the input of the coil 153 of the electro 43, the derivation 154 is connected, by the switch 147 when the electro 27 is energized, to the conductor 155 which supplies in parallel with the conductor 42 the input of the coil 43 'of the electro 43;

   the derivation 33 is extended by the. branch 1.56 which can be connected, by switch 155, to conductor 156 'which can in turn. be connected, by the switch 157, to the conductor 158 which supplies the conductor 13 in parallel with the conductors 11-1l 'and 143-143'.



  -The switch 147 also makes it possible to connect the branch 156 to the branch 154 and, consequently, to the branches 151 and 152; the conductor 151 is extended by the bypass 58 which supplies the input of the internal coil 58 'of the electro 59, the output of this coil 58' being connected at 61 'to the negative of the battery 5;

   the conductor 6, passing through the switch 56, can supply the conductor 57 which itself passes through the switch 60 to supply, through the conductor 57 ', the coil 61 of the electro 59, the output of this bo bine being connected to the negative of the battery 5 at 61 '; the switch 56 is controlled by the relay 53, and the switch 60 is controlled by the movable core 90 of the electro 59.



  Routes 131-132-133-134 and 135 each correspond to. a relay coil, as shown at 161 and 162, the output of each of these coils being connected to a common conductor 163 which supplies the relay 53 whose output 53 'passes through the switch 164 before reaching the negative of the battery through the conductor 165;

   conductor 163 comprises a bypass 66 which passes through resistor 160 and switch 66 'before being connected, by conductor 61', to the negative of the battery; a branch 166 of the conductor 6 supplies the coil 167 of the relay 168, the output of which is connected to earth by the conductor 165; the conductor 104 passes through the switch 169 to feed, through the conductor 170, the second coil 171 of the relay 168, the output of which is also connected to the. mass by conductor 165;

   a return lever 172, pivoting at 173, allows the movable core 90 of the electro 59 to mechanically actuate the relay 168 and the switches. 169 and 16.4; a return lever 174, pivoting at 175, is actuated, on the one hand, by the movable core 90 of the electro 59 and, on the other hand, by the antagonist spring 176; the switch 66 'is attached, on the one hand, to the lever 174 by the link 89, on the other hand, to the return spring 88.



  The movable core 177 of the electro .43 is connected, via the lever 178, the connecting rod 179 and the lever 180, to the throttle valve 181 which is always returned to the closed position by the spring 182; the. movable core 183 of the electro 15 is attached to the lever 184 which pivots in 185 to counterbalance the action of the antagonist spring 86, the head 187 of the electro 17 serves as a temporary stop for the lever 184;

   the rule 188 which is provided with pins and actuated by the lever 184 to which it is connected by the connecting rod 189, is used to actuate the switch 18 and, by the ratchet wheels 113 'and 120', the rotating switches 113 and 120;

   the switches 33 'and 28' are respectively actuated by the mobile cores. 190 and 191 of the appliances 32 and 27, to which the switches 146, on the one hand, 147 and 159, on the other hand, are also attached by fasteners in insulating material.

           Operation: The switch 7 of the remote control 7 'having been closed, the current flows from the positive pole of the battery 5 through the conductor 6, the switch 7, the conductor 8, the coil 9 "of the relay 9 and conductor 10, to return by ground to the negative pole of the battery;

   the bypass 8 'also passes the current through the switch 10' and the second coil 9 'of the relay 9 which is cut when this relay is closed, by the opening of the switch 10'; the excitation produced by the coils 9 'and 9 "causes the opening of the contact 10' and the closing of the contact 10";

   coil 9 "keeping the relay closed as long as switch 7 is closed; closing switch 10" allows current to flow from conductor 6 to conductors 11, 11 ', 12 and 13 to energize the coils appliances 15 and 17;

   if the switch 7 is closed for a very short time, the movable core 183 of the electro 15 only crosses half of its travel because it is retained by a temporary stop formed by the head 187 of the electro 17 which limits the movement of the lever 184 when the latter is attracted by the core 183 of the electric 15;

   under these conditions, the rod 188 which is driven by the lever 184 and the rod 189 engages only on the pawl wheel 113 'of the rotary switch 113, so that when the switch 7 opens, only this rotary switch 113 operates as a result of the reinsertion of the rod 188 under the effect of the spring 186; , the function which has just been described is designated, for the intelligence of the following, short contact.



  By the operation of the rotary switch 113, a succession of short contacts produces the following functions: 10 Disabling of the left actuating device controlled by electro 32. 20 Putting this device back into service. <B> 30 </B> Disabling the right actuator controlled by the electro 27.

    40 Putting this device back into service, etc. This alternation - and this succession. Many functions result from the ratchet wheel 113 'causing the turn switch 113 to turn a quarter of a clockwise turn each time the rod 188 performs half its action. return journey, that is to say when it takes the place indicated in the drawing.



  In the position of the drawing, we see that the current passing through the conductor 6, the conductor 111, the brush. 112 and .le '-ment of ba gue 112' can not reach either of the bays 114 and 115; <at, the. following function, the rotary switch 13 having described an iliiart of turn in the direction of clockwise, the current passes through the conductor 6, 1i # conductor 111, the brush 112, the:

  e - ment (the ring 112 'and <B> the </B> brush 114 to supply the conductor 25' as well as the branch 28 <-t, by the switch 28 ', the branch 28 ", c (# which causes the two coils 26 and 29 of the electro 27 to be energized; this electro, on closing, causes the disengagement of the right actuator.

   At the next function (still in short contact), the rotating coin-mutator 113 performs a new quarter: of a clockwise turn, the current flows through conductor 6, conductor 111 and brush 112 and cannot reach the ring segment 112 ', so that neither. neither of the brushes 11.1 and 115 fie receives current; which cancels the effect of the. previous function;

   in the next function, the rotary switch 113 - having described a new quarter of a turn in the direction of the clock; iigtiilles of a watch, the current passes through the conductors 6, 1_11, the brush 112, Ir @ ring segment 112 ', brush 115, conductor 30', conductor 33, switch:;

      3 'and the conductor 33 ", as well as by the conductor 30", which makes it possible to supply the hobina-e, 31 and 34 of the electro 32 which, by closing as a result of the excitation of these bo- 1) ines. disables the device to -au- At the next quarter turn, the rotary switch 113 is in the conditions shown in the drawing and described in the first place; which cancels out the effect of the previous func- tion.

      It should be noted that each time one of the appliances 27 and 32 is energized and, e closes, the switches 28 'and 33' are open. by the tapered end of the movable cores 191:

  and 190, so that the coils 29 and 34 are cut and only the coils. interior 26 and 31 of each of these appliances remain energized, they therefore constitute economizing maintenance circuits, while the coils 29 and 34 constitute operating circuits. The maximum duration of each short contact is set automatically to ensure the necessary excitation time for the appliances, to. from the moment when relay 9 a.

   It should be noted that this is only during the time that elapses between the end of a short contact and the function it causes and the end of the contact. short time and of the function that it causes that is established <B> IL- </B> operating time of one of the electrodes 27 or 32 as well as the non-excitation time designated above by the term .. of return to service.



       5i switch 7 is closed for a slightly longer time, which we will call, for the sake of the following, <: long contact>., The operation is established as follows:

   Current from the battery passes through lead 6, switch 7, lead 8, coil 9 "and returns to the battery through lead 10; current also flows through bypass 8 ', switch 10', winding 9 'and returns to the battery via conductor 10; relay 9 having operated, the circuit of winding 9' is cut as before and the relay remains stuck by the action of the winding 9 <B> "</B>, the current then passes through conductor 6, conductor 11, the switch closed 10", conductors 13 and 1? supplying coils 14, 14 'and 16' of the appliances 1.5 and 17.

    



  The core 183 being attracted drives the lever 184 which, by pivoting around the point 185, strikes the head <B> 187 </B> of the electro 17, this head, by sinking, opens the switch 16, which cuts off the circuit between the conductor 1.2 'and the coil 16';

   however, as a result of an afterglow effect, the temporary stopper. constituted by the. head 187 of the electro 17, continues to resist for a short space of time, which prevents, while the remanence lasts, the mobile core 183 to travel its entire path;

      the resumption effect having ceased and the switch 7 still being closed, the core 183 reaches the end of its travel, causing, by its tapered end, the opening of the switch 13 ', which cuts off the conductor 13 and removes the excita.- Lion of coil 14 ', the core 183 can.

   this while remaining stuck by the effect of the coil 14 which continues to be excited by the conductor 12 as long as this conductor remains supplied; at this moment. rule 188 a. crossed its entire course having been driven by the. link 189 and lever 184;

   in this movement, the slide 188, by pins, switches the switch 18 and the ratchet wheel 120 'of the rotary switch 120, which describes a quarter turn in. clockwise.



  Each long contact produces as a consequence of the above a reversal between the forward control circuits and the reverse control circuits as well as other operating steps which will be described later.



       It should be noted that during its return stroke to the drawing position, the strip 188 only allows the switch 18 to open under the pressure of its spring (not shown); as a result of an avoidance movement not shown, the position of the rotary switch 113 is not changed, as is that of the switch 120, the ratchet of which escapes in this direction.



  The inversion of. forward and reverse circuits by turn switch 120 occurs as follows: In the position of the drawing, it is seen that the current flowing through conductor 6, conductor 116 and brush 118 cannot reach the conductor bar 119 of the rotary switch 120;

   on the other hand, this current reaching the brush 117, crosses the. conductor bar 119, the brush 121, to supply, via the conductor 135, the relay 161 of the air control command; at the output of this relay,; the current flows through conductor 163, through the coil of relay 53, through conductor 53 ', switch 164 and if the latter is closed, through conductor 165 which is connected to negative pole of the battery by the. mass.



  When the slide 188, under the impulse of a long contact, performs a new complete stroke, it drives the ratchet 120 'in its first movement; which causes switch 12.0 to describe a quarter turn clockwise;

   the current then passes through the conductor 6, the conductor 116 and is interrupted on the brush 117 which is no longer in contact with the conducting bar 119. while passing through the brush <B> 118 </B> which is in contact with the bar 119, it can, by crossing this bar, reach the brush 122, travel the conductor 123 and from there reach the pads a and b;

   initially, the bridge 125 is always located between the pads b and b ', the current therefore passes from the pad <I> b </I> to the pad <I> b' </I> through the bridge 125, feeds the conductor 131 which corresponds to the first forward speed because it supplies the relay 162 controlling this first speed; .on leaving relay 162, the current passes through conductor 163, supplies the coil of relay 53, then passes through conductor 53 '- and from there, finds, as before, switch 164 and, if the latter - Ci is closed, the conductor 165 which is connected to the negative of the battery.



  As has been said above, during the same movement of the strip 188, the switch 18 closes and if the vehicle is running, remains closed until the vehicle is stopped, the device centrifuge 124 is at rest; moreover, switch 18 also remains closed until switch 7 is open, if its closing lasts longer than the stopping of the centrifuge.



  The closing of the switch 18 therefore allows the current leaving the battery and not passing through the conductor 6 and, the conductor 25 to supply the conductor 25 'and, through the conductor 30, to supply the conductor 30'. ;

    these two conductors, as we have already seen in the. description of short contact operation. .powering respectively the., electros <B> 27 </B> and 32, which remain closed by I (-urs economiser circuits as long as the vehicle has not stopped completely.



  It should be noted that, by their functions deny, the; appliances 2 7 and; 32 causing the disengagement of the right and left actuating devices respectively, release, by rL @ bniyage, the motor of the machine from the actuating devices.



  If the engine is stopped, closing switch 18 automatically produces the ii ('@ stopping the engine as follows: Lc, current from the battery through eoridirector 6 passes through one of the conductive blades (the switch 18 and supplies the con- fluators 6 'and 102, it crosses, on the one hand, the switch 103 and the winding 102' of the cell; 19 and, on the other hand, passes directly through the winding 102 " of relay 19.

   At the exit of these windings, the current passes through the switch 19 "and follows the conductor 1.'l 'which is connected by the ground to the ne pole @; al, if of the, battery; by the excitation of bo- I@inagel.02 'and 102 ", the: relay 19 closes, (-r @ which causes the opening of switch 103 <B> 11 </B> the closing of switch 20, the stream:

   stops passing through conductor 102 <@ 1 to feed winding 102 ', but, on the other hand, it still passes through conductor 6' and through winding 102 ", which keeps ic: 19 closed : the current still flowing through conductor 6 'crosses switch _'0, 1c conductor 21 and supplies dynastart 21.' from where it emerges through the conductor 21 "which is connected to the negative of the battery;

   as long as the dynastart is trained in the coming way. (being described, the current cannot pass l) to the conductor 22, the winding, of the circuit breaker nr 22 'and the conductor 23 which is connected to the conductor 6 of the positive pole of the battery, but as soon as the engine starts, its acceleration is sufficient to drive the.

       dy- riaslart so that the latter launches i - .. n current in the conductor 22, winding it, at: of the circuit breaker 22 'and the conductor 23 to reach the conductor 6 of the positive pole (the. battery; the circuit breaker 22 "being energized by this fact, closes the switch 23 'and opens the switch 19", the current produced by the.

         dynastart continues to pass through conductor 22, winding <I> 22 'and </I> conductor 23, to reach conductor 6 of the. battery, but also passes through the conductor 24, the winding 24 ', the switch 23' and the conductor 23 to reach the conductor 6 in the same way, thus ensuring a normal charge of the battery.



  The opening of the switch 1.9 "interrupting the circuit of the conductor 19 'suppresses the flow of current in the windings 102' and 102", the relay 19 being de-energized opens by closing. The switch 103 and by opening the switch 20; this condition is maintained as long as circuit breaker 22 "is energized by the dynastart.



  By the way, we have seen during the. description of the operation of the rotary switch 120, that the forward circuit 123 and the reverse -circuit 135 both energize the coil of the relay 53 as well; the closing of the relay 53 causes the closing of the switch 56 the current then passes from the positive pole of the battery through the conductor 6, the switch 56, the conductor 57, the switch 60, the conductor <B> 57 ', </B> to feed the. coil 61 of electro 59, the output 61 'of which is connected to the negative of the battery.



       Simultaneously, and as we have seen above, the electrons 27 and 32 are excited, so that a current passing through the conductor 30 ', the conductor 156, through the switch 147, through the conductor 154 and by the conductor 58, feeds the coil 58 ', the output of which is also connected to the conductor 61' and from there to the negative of the battery; the two coils 58 'and 61 of the electro 59 are therefore excited and the movable core 90 of this electro drives the mechanism 192 which operates by means not described the automatic change of forward speeds:

   the core 90 drives, through the intermediary of the lever 174 which is always returned by the spring 176 and which pivots around the point 175, the device 192; the link 89 is connected by one end to this lever 174 and by the other end to the switch 66 'which is always biased on closing by the spring 88, so that when the core 90 is attracted by the excitation of the coils 58 'and 61 of the electro 59, it leaves, on the one hand, the switch 66' to close, while,

      on the other hand, by .its tapered end, it opens the switch 60; the opening of the switch 60 cuts the current on the main circuit of the conductors 6, 57. and 57 'which feed the coil 61, so that the core 90 of the electro 59 is not kept in place. bonding only through the current flowing, as described above, through the conductor 58 to supply the coil 58 'which constitutes the economizer circuit;

   the closing of the switch 66 'establishes a new bypass on the current flowing through the conductor 163 to supply the coil of the relay 53, this bypass is constituted by the conductor 66, 1a. resistor 160, switch 66 'and conductor 61' which is connected to the negative of the battery.

   It results from the commissioning of the circuit of this derivation that the coil of the relay 53 is relieved of a part of the current which it receives as soon as its function is accomplished and that this relay remains glued with a neck. rant reduced, but, in addition, .when, the excitation of the coil 58 'having ended, the movable core 90 of the electro 59 returns to the position it occupies in the drawing,

   this bypass controlled by switch 66 'allows current to be maintained on the type 161 and type 162 relays which operate the speed control almost until the end of the return path of the movable core 90 and while the winding of the remake 53 a. been cut in one of the ways described later.



  The long contact only ends when the vehicle is stopped. In the event that stopping the vehicle takes less time than long contact, the vehicle does not restart in the opposite direction until the end of long contact;

   in the case where, on the contrary, the stopping of the vehicle requires a longer time than the long contact, the slowing down period is automatically prolonged until the complete stop by the fact that the excitation of the appliances 27 and 32 having produced the attraction of the nuclei 190 and 191, as he has. been described above, a circuit passes from conductor 6 to conductor 30 ', conductor 156, switch 159, conductor 156', switch 157, conductor 158, conductor 143 ', conductor 12, coil 14 and output 15' going to the.

   battery, this circuit ensuring a parallel supply of the coil 14 which replaces the supply by the conductors 11 and 11 'until the centrifugal device 124 returning to its rest position has caused the opening of the 'switch 157. Assuming therefore that the long contact has ended prematurely, it is only when the switch 157 is opened by the rest position taken by the centrifugal device 124 that the coil 14 is.

         de-excited by the. cut which is established between the conductors 156 ′ and 158, that the core 183 is released and by opening the switch 18 de-energizes the electrodes <B> 9-7 </B> and 32 which, in releasing the cores 190 and 191, allow the clutches of the actuators to close.



  At the end of the long contact, the opening of relay 7 interrupts the flow of current in conductor 8 and in winding 9 <B> "</B> of relay 10, this relay 10 then resumes the position of the drawing where the current coming from conductor 6 is cut between conductors 11 and 11 ', which prevents them from supplying conductors 13 and 12 and the electro 15:

    the core 183 no longer being attracted is returned, by the spring 186, by means of the, the lever 184 pivoting around the point 185; this lever 184 pushes back the slide 188 which jumps over the ratchet wheel 113 ′, avoids the ratchet wheel 120 ′, and lets the switch 18 open; while switch 18 opened, rotary switches 120 and 113 remained stationary.



  It is easy to see from what precedes, that after a long contact, the current passes through the conductor 6, the conductor 116 and one of the brushes 117 or 118 and continues to supply the forward speed circuits which correspond to brushes 118 and 122 or the corresponding rear speed circuits, lux brushes 117 and 121;

   if the reverse gear circuits are supplied, all the circuits (the forward gears are isolated since the driver 135, as can be seen in the drawing, directly supplies the reverse gear relay 161 without passing through the terminals from automatic control a to i.



  This means that even if the centrifugal automatic control reaches in reverse a speed high enough to operate the reverse gear, second or third gear forward it will not result in any gearshift command since the circuitry of these gear controls are not excited.



  If, on the other hand, the forward circuits are supplied at the end of a long contact via the brushes 118, 122, next to the conductor 123, the automatic forward gear changes occur. automatically decrease according to the speeds acquired by the machine, using the centrifugal device 124, as follows:

    As stated above, when stationary, the <B> 1215 </B> bridge is always brought back between the studs; <I> b </I> and <I> b ', </I> so that the first speed introduced by the passage of the current from the connector 6 to the conductor 116, to the brush 118, to the. conductive blade <B> 1.19, </B> to brush 122, to collector <B> 123, </B> to terminal b, to bridge 125, to terminal b ', to conductor 131, to relay 162, to conductor 163 , to, relay 53, to conductor 53 ', to switch 164, to conductor 165 and:

   to the negative of the battery.



  He is at. note that switch 164 is always closed at the time of a speed command because whenever the bridge 125, for example, passes from pin aa 'to pin bb' when stopping the machine , it establishes by passing a contact between the pads c and c ', this impulse contact passes the current from the conductor 6 to the conductor 130, pad c, bridge 125, pad c', conductor 104, switch 169,

   conductor 171_ï, inrush winding <B> 171. </B> of relay 168, conductor 165 connected to the negative of the. drums. The relay 168 closes by opening the breaker 169, but by closing the switch 164, so that while the current is cut between the conductors 104 and 170 which supply the winding 171, it is kept on the winding 167 which is supplied by conductors 6 -and 166;

       this winding 167, the output of which connects to the negative of the battery through the conductor 165 directly, is insufficient to cause the closing of relay 168, but is sufficient to keep <B> this </B> relay closed, so that also as long as this relay has been closed without the core 90 having mechanically unlocked the relay 168 by the elbow lever 172 pivoting at 173, the relay 168 remains closed.



  We saw earlier that the first speed had been introduced by the supply of the coil of the relay 53, which caused the closing of the switch 56, the current then passing through the conductor 6 , the conductor 57, the switch 60, the conductor 57 'to reach the negative of the battery by the conductor 61'. As described above, the closing of the switch 66 'allows the current to pass through the bypass 66, which allows the excitation of the relay 162 to be maintained for an additional instant during the return movement. of the core 90.

   In its forward movement, this core 90 struck an elbow lever 172 which, while pivoting at 173, opened the relay 168; also as stated above ,, this relay 168 remains open despite the energization of the coil 167, so that this opening causes the opening of the switch 164 which cuts the circuit of the relay 53, passing through the conductor 53 ' -and the driver 165; the relay 53 being de-energized, the switch 56 opens almost at the same time that the switch 60 is opened which has received its opening pulse by the tapered end of the core 90;

    this core 90, which is constantly returned by the spring 176, therefore resumes the position of the drawing by introducing the first speed by the operation of the mechanical device 192 which acts in a manner of which the detail is not described in the present invention ., on the gearbox players.



  This device 192 also produces the disengaging of the engine at the moment when the core 90 was attracted by the electro 59 and it closes the clutch again immediately after the gear has been introduced, that is to say at the end. of the opening stroke of the core 90.



       It should be noted that the throttle is not maneuvered during gear changes for this type of automatic control, because this is not necessary due to the enormous inertia of the vehicle mechanism; in addition, throughout the forward or reverse gear and with the exception of one or two cases described below, the throttle generally remains fully open.



       The introduction of the first gear and the clutch of the engine naturally produce the starting of the vehicle and the starting of the centrifugal device 124 which is connected to the output of the vehicle's gearbox via the clutch. with cams 139 and transmission 136 and 137.

    As the speed of the vehicle increases, the centrifugal device accelerates its speed and successively produces the passage between the first and the second speed, between the second and the third speed and finally between the third and the qua third gear, as follows:

         The inverter 125 being pushed by the centrifugal positive device leaves the place which it occupied between the pads b and b ', jumps over the pads c and é while producing an impulse on the conductor 104 which causes, as described above, the closing of relay 168 and arrives on the pads aa 'which control the circuit of the second speed as follows:

   The current passes through the conductor 6, the conductor 116, the brush 118, the conductive blade 119, the brush 122, the conductor 123, the pad a, the bridge 125, the pad t ', and the conductor 128, the pad < I> f, </I> the bridge 126, the pad f ', the conductor <B> 132 </B> which supplies the relay of the 162 series of the second speed, the output of which is effected by the conductor <B> 163, </B> the coil 53, the conductor 53 ', the switch 164 which has just been closed as has been said and finds the negative of the battery through the conductor 165.



       The same effects which have been described for the introduction of the first gear are produced at this moment with the only difference close to when the core 90 is attracted by the excitation of the electro 59;

   its action on the mechanism 192 first of all disengages the engine, then the output of first gear and, consequently, the neutralization of the gearbox, then, when the core 90 having cut the relay 168 resumes the position of the drawing under the effect of the spring 166, it introduces the second gear mechanically by the mechanism 192 and then engages the motor.



  The passage from the second to the third speed takes place exactly under the same conditions as the passage from the first to the second speed, the centrifugal device causing the bridge 126 to pass rapidly at this moment on the impulse pads e-e ', which causes relay 168 to close, as seen above, by closing circuit 104;

    the bridge 126 arriving on the pads d-d ', the current can pass, as it was seen above, through the conductor 123, the pad a, the bridge 125, the pad <I> a; </I> the conductor 128, pad <I> d, </I> bridge 126, pad d ', conductor 129, pad i, bridge 127, pad z', conductor 133, third gear relay of the 161 or 162 series, the conductor 163, the coil of the relay 53, the conductor 53 ', the switch 164, the conductor 165 and the negative of the battery.



  With the same movements being produced by mechanism 192, the motor was disengaged, second gear was taken out, third gear was introduced, and the motor was engaged.



  If the speed of the vehicle continues to increase, the same operation as described above ensures the passage from the third to the-fourth speed, the centrifugal device causing the bridge 127 to pass rapidly over the blocks hh 'to reach the studs:

       9-g ", the circuit 104 is closed, as n saw it above, and the current can then flow through the conductor 123, the pad a, the bridge <B> 125. </B> the pad <I > a ', </I> plot <I> d, </I> bridge <B> 126, </B> plot <I> d', </I> plot g, bridge 127, the pin <B> <I> g ', </I> </B> the driver 134, the relay of the fourth gear of the series <B> 161 </B> or 162, the driver <B> 163 , </B> the winding of the relay 53. the conductor 53 ', the switch 164, the conductor <B> 165, </B> to reach the negative (the. Battery;

   the mechanism 192 ensures, as before, under the impulse of the core 90, the disengagement, the output of the third gear, the input of the fourth gear and the clutch.



       \ We have all just seen how the <B> </B> increase in speed takes place between the first and the. fourth speed; regardless of the number of .; speeds, the same arrangement can solve the problem, it suffices to increase the number of inverters.



  He has. It has been said above that the throttle control was not necessary when the gear change is effected, on the other hand, before the automatic control - a, - was applied. command of an inverter upshift it is. important that a prior slowing down of the throttle occurs automatically before one of the new speeds is engaged;

   in fact, as the torque is increasing due to the new reduction stage, the engine must be able to provide this additional torque which also corresponds to a drop in speed, when the new speed passes and the throttle is fully open .



  This slowing down operation prior to. a speed increase occurs as follows: As the centrifugal device approaches, for example, the inverter 125, it first presses on the 'roller 42' which is located at the end of the switch lever 42 ', which causes this switch to close, the current then passes from conductor 6 to conductor 41, switch 42', conductor 42, coil 43 'of electro 43,

   conductor 43 "and return to negative of the battery; the electro 43, under the effect of the limited excitation produced by the winding 43 ', attracts the core <B> 177 </B> by a corresponding quantity at only a fraction of its total stroke, this fraction depending moreover on the engine torque diagram; as this core 177 is connected by the lever 178, the connecting rod <B> 179 </B> and the lever 180 to the throttle adjustment 181 which is constantly brought back to its open position by the spring 182, the gases are constricted while the coil 43 'is energized.



  At this time, the engine therefore receives only one bet of its admission; if, despite this, it continues to accelerate the speed of the vehicle, the thrust of the centri fuge device continues to be exerted and the roller 42 'escapes this thrust at the precise moment when the inverter 125 begins to tilt, the throttle is then restored to their maximum at the very moment when the new gear is engaged and this additional power given to the engine corresponds to the additional torque which is necessary for it to maintain the speed of the vehicle with the new stage <B> of </ B> reduction.



  If, on the contrary, the slowing down of the throttle produced by the excitation of the coil 43 'does not allow the engine to further accelerate the speed of the vehicle, the rise of the new speed does not occur, which is expected. reliable, since the engine would not be powerful enough for this speed to remain in demand, we would then witness a succession of upshifts and downshifts as long as the resistance to forward movement of the vehicle kept a value of inter torque. medial between the motor torque of the higher speed and the motor torque of the lower speed.



  For lowering speeds, the throttle control prior to changing a gear is naturally not necessary since, when going down, the motor torque always has a predominant value over the resistive torque; moreover, for the reasons already explained above, it is not. no more necessary to control the throttle when changing gear, this condition being peculiar to the type of vehicle for which the present automatic control device has been created.

        When the speed of the vehicle decreases, the return springs of the centrifugal device tend to return this device to its rest position, the reversers are successively operated according to the slowing down of the vehicle so that the lowering of speeds takes place. as follows:

       Under the action of the return spring of the centrifugal masses, the bridge 127 passes from the pads g-g 'rapidly over the pads h-h, to reach the pads i - 2';

      on passing through the pads h-h ', a current pulse was given by conductor 6, conductor 130, pad <I> h, </I> pad <I> h', </I> the conductor 104, the switch 169, the conductor 170, the coil 171 of the relay 168, the conductor 165 and the negative of the battery, which ensured the closing of the relay. 168;

   current then flows from conductor .123 to pad a, bridge 125, plot â <I>, </I> plot <I> d, </I> plot <I> d ', </I> plot <I> i, </I> bridge 127, pin i ', conductor 133, corresponding relay of the 161 or 162 series. at third speed, conductor 163, Telais winding 53, conductor 53 ', switch 164, conductor 165 and negative of the battery;

       the energization of the coil of the relay 53 caused the closing of the switch 56, the current flows from the conductor 6 to the switch 56, conductor 57, switch 60, conductor 57 ',' coil 63 and the output of the coil being done by the conductor 61 'and the negative of the battery;

   the core 90 of the electro 59 is attracted as previously described for the upshift and, by the operation of the mechanical device 192 that this core 90 drives, the motor is disengaged, the fourth gear is output, the third gear is inserted and the engine is engaged.



  The same operations occur to go from the third to the second speed when the inverter bridge 125 leaves the d-d 'pads to quickly pass over the e-e' pads and from there reach the f-f 'pads. It is the same for the passage from the second to the first speed which occurs when the bridge of the inverter 125 leaves the pads a-a ',

      Tap on the c-c 'studs to reach the b-b' studs. It is obvious that if the machine is in third gear, for example, it can, depending on the speed that allows it to reach the rolling resistance, cause, by the centrifugal device, the descent of third in second gear. or the rise of third in fourth gear,

   in other words, in any driving condition and as soon as <B> the </B> speed corresponds, to a determined reduction speed, the change takes place automatically both in upshifting and downshifting and as the speed is always that of fully open throttle, with the natural exception of cases essential for the correct operation of the automatic device, the vehicle always reaches the highest possible speed by itself.



  If it is necessary to slow down the movement of the vehicle, it is by means of a series of short and rapid contacts that the deceleration can be effected if it is not desired to bring about a complete stop by long contact. In the case. or. a stop must be followed by a run in the opposite direction, it suffices to make a single long contact, the reversal occurring automatically. If, on the contrary, the vehicle must start again in the same direction, two long contacts must be made successively.

      Long contacts stop the vehicle without stopping the engine; in the event that the engine must be stopped, a long, prolonged contact must be made which, after a time appreciably longer than that of an ordinary long contact, operates a thermal switch which cuts off the ignition current of the engine as follows:

   During prolonged stoppage, relay 9 being closed, the current passes through conductor 6, conductor 11, switch 10 ", conductor 11 ', conductor 13, conductor 35, thermal deformation lady 105, inverter 35 ', resistor 36' and, through conductor 36 ", return to the battery;

      this resistor 36 'slowly heats the thermal deformation blades 105 and 109, the latter ensuring the passage of the ignition current in the following manner: conductor 6, conductor 106, switch 107, conductor 106', inverter 108, thermally deformable blade <B> 109, </B> winding 110 and return to the battery via the conductor 110 ', the winding 110 being the low voltage winding of the ignition device.



  When the resistor 36 'has sufficiently heated the deformable blades so that they suddenly fall back on the other inversion pad, the circuits which have just been described are established as follows:

       conductor 6, conductor 11, switch 10 ", conductor 11 ', conductor 13, conductor 35, deformable blade 105, inverter 35', resistor 36, resistor 36 ', conductor 36" and return to the battery; the resistors 36 and 36 'being in series limit the heating of the blades 105 and 109 but maintain their deformation.



  The ignition current is cut off at this time .. by switch 108 as follows: conductor 6, conductor 106, switch 107, conductor 106 'which is at this time separated from the deformable blade < B> 109 </B> by switch 108 which operated; the current therefore no longer passes through the low voltage winding 110 of the ignition device.



  When the long contact thus extended has ended, the deformable blades 105 and 109 return to the position of the drawing by natural cooling, a new long contact is then necessary to ensure the starting of the engine and the control of the circuits, as described above.



  In the event that the vehicle encounters an insurmountable obstacle which produces a sudden stop of .sa. walk there. transmission 137, 136 of the gearbox output stops abruptly, while the centrifugal masses of the automatic governor 124 continue to rotate, because the reaction torque resulting from the inertia of the centrifugal masses against the sudden braking of the, transmission 136, 137, causes the opening of the cam clutch l39 which, by opening,

   sets the conductor 140 to the negative of the. drums; the current then passes through the conductor 6, conductor 143, the coil 141 of the relay 142, the conductor 140 and the ground; the excitation of coil 141 causes the closure of relay 1.42, which. causes the following circuits to close:

      conductor 6, conductor 148, switch 148, conductor 143 ', conductors 12 and 13, the latter two therefore being supplied with power in the same way as when they were supplied with long contact by switch 10 ", operated. by relays 9, energize all the circuits already described for stopping and changing gear of the vehicle.



  Simultaneously, the relay 142 closes the switch 149, which energizes the conductor 104 ', the conductor 104 and produces the operation of the relay 168 in the same manner which has been described with regard to the long contact, but this immediately results in disengaging the motor by operating the electro 59 which is now closed as long as the closing of the relay 142 lasts, as described. below.



  The relay 142 also simultaneously closes the switch 150, which supplies the conductor 151, the conductor 58, the coil 58 ', the return of which is provided by 1ë: conductor 61' to the battery; the same conductor 151 supplies the conductor 152, the coil 153 of the electro 43 and the output 43 'of which is connected to the negative of the battery;

    the energization of the coil 153 produces the throttling by the complete attraction of the core 170; when the complete stop occurs, the switch 157 is cut by the centrifugal device 124 and at the same time the cam clutch 139 has resumed its position, which cut the earth circuit of the conductor 140; the relay 142 opens because, on the other hand, the electros 27 and 32 being still energized leave open the maintenance circuit 144 of the relay 142 which passes through the conductors 145, 145 ',: the switches 146 and 147 and returns to the battery 146 'and 147;

    as the motor has not been stopped during this operation, because the prolonged long contact necessary to cause the operation of the thermal switch takes longer than the control of the circuits during the slowing down of the device cen trifuge 124, even when this device was running @ full speed,

   the vehicle sets off on its own in the opposite direction as a result of the version produced, as already described during the description of the operation, by the rotary switch 120.



  The vehicle constantly running at full throttle has a tendency to accelerate its speed indefinitely if the rolling resistance is not opposed to this acceleration, for example on declining ground;

      to overcome this drawback, a switch not shown in the -dessin, but placed at the other end of the centrifugal device and symmetrically to the switch 157, is connected in series with the switch 107, so that when the the vehicle is in fourth gear and exceeds a certain speed,

   the thrust of the centrifugal masses, by operating this switch not shown, cuts the -circuit supplied by the conductors 6, 106, 106 'and 109 to reach the winding 110, so that the ignition being cut from a certain speed,

   the vehicle is limited in its speed to the extent that the natural mechanical resistance of its components allows it.



  Another device not shown in the accompanying drawing makes it possible to reduce the excitation of the coils of the electros 27 and 32 starting from a certain speed imparted to the centrifugal device and as this speed increases.



  By the arrangement of this last device, the appliances 27 and 32 have a pulling torque inversely proportional to the speed of:

          vehicle, so that in the event of a short contact causing a change in direction of the vehicle, this change of direction is slower the higher the speed, which tends to avoid rollover -du vehicle.

      Briefly summarizing the description of the functions given above, the following automatic control movements are produced using the device described.



  A single relay, energized by a means not described, can produce short contacts, long contacts and long contacts at will.



  The automatic device makes it possible to automatically obtain, using short contacts, on the first short contact, the turn to the right or to the left, on the second contact, the return to a straight line and this by succession and according to the previous state; in the event that the vehicle has to change direction in the same direction twice in a row, the second direction change command must be made by three short contacts following each other without interruption.



       The short contacts also make it possible, by being launched successively and very quickly, to slow down the vehicle.



  Using the long contacts, it is possible to obtain automatically depending on the condition prior to the operation: the engine starts, the. cut-off of the starting current, the departure of the vehicle in the forward direction or in the reverse direction depending on the direction that the vehicle posed before the previous stop, the automatic change of gears up and down depending on the speed acquired by the vehicle vehicle, stopping the vehicle and its automatic departure in the opposite direction.



  This last function obtained by long contact is automatically performed in the event of <B> </B> impact resulting from an insurmountable obstacle encountered by the vehicle; the prolonged contacts produce, like the long contacts, the stopping of the vehicle, but in addition the automatic stopping of the engine.



  When reversing by long contact, or by the automatic operation of relay 142, it may happen that the vehicle operating in reverse and returning to its starting position cannot be stopped due to a fault. caused by an action external to the devices of

  remote control which actuate the switch 7. In this case, the path can be limited by a device, not shown in the accompanying drawing, and which consists in producing the heating of the. thermally deformable blade 105 by an independent resistor and circuit; supplied by a bypass of the conductor 135 controlling the reverse gear.



  It should be noted that the braking in a straight line as well as the braking and disengaging producing a turn are automatically adjusted according to the speed of the vehicle in order to avoid any imbalance in the lift of the latter.



  It should be observed that the essential principle of the. present invention is to obtain by means of a single electric relay capable of being controlled remotely, all the movements necessary for the movement of a vehicle, for example a vehicle propelled by tracks, and that only by the closing times of this relay.

   Accordingly, the principle of the present invention, of course, could not be changed by substituting, for example, electric motors or electros which operate the settings.

   This principle could not also be changed by replacing the electromechanical devices by hydraulic devices or functioning by pressure or depression of a cluelcorique gas, to. the. place of the electrons of my it would be the same by adopting only part of the commands specified above.

 

Claims (1)

CLAIM: Installation with automatic operation for the remote control of vehicles, with motors, in which a single relay acting on a selector mechanism produces, by its more or less long closing times, commands allowing. maneuvering the vehicle, characterized in that the selector mechanism always causes a change of direction when it is on: not operated for a short time, on the other hand a change in the direction of travel of the vehicle each time it is operated for a long time. <B> SUB-CLAIMS: </B> 1. Installation according to claim, charac- terized in that the selector mechanism causes the starting, respectively the stopping of the vehicle when it is operated for a long time. 2. Installation according to sub-claim 1, characterized in that all the electrical circuits are open as soon as a command has been completed. 3. Installation according to claim, for controlling vehicles provided with a gearbox, characterized by means controlled by the selector mechanism when the latter is operated for a long time, and designed to be able to be moved by a centrifugal governor, means which automatically adjust the gear ratio in the vehicle's gearbox according to the speed of movement of the latter. 4. Installation according to sub-claim 3, characterized in that an actuator (15) controlled by the relay (9) is mechanically combined with a stop solenoid (17), timed by remanence, which, depending on whether it is excited for a short or long time, allows the anchor of the maneuvering electro (15) to travel half a race or a whole race. 5. Installation according to. sub-claim 4, characterized in that the electro stopper (17) cuts its current. of excitation each time an organ controlled by the electric maneuver strikes it. 6. Installation according to sub-claim 5, characterized in that the mechanical coupling of the two electrons (15, 17) causes, by means of ratchet wheel controls working in opposite directions, the actuation of rotary switches (11â, 120), one of the controls being operated at. the closing of the maneuvering electro (15), the other to. sound or verture, the actuation of the switches (113, 120) however taking place only in the case where the stroke does not. not complete due to the operation of the stop solenoid (17). . 7. Installation according to sub-claim 6, characterized in that one (113) Corner Rotary Mutators is a triple contact switch and provides reversing of two circuits with alternating interrupt between each circuit closure. 8. Installation according to sub-claim 7, characterized in that the other (120) of the rotary switches is a switch with four contacts and ensures for each function the inversion of two circuits.