DE1067929B - - Google Patents

Description

GERMAN

The invention relates to an arc lamp with an automatically regulating coal feed, in particular for motion picture projectors, in which the positive carbon depends on the scanned by beams Position of their burning end is advanced.

It is known to arrange a heat-sensitive switch so that it is of the heat rays of the Arc or a coal end is hit when this coal ^ ends by a certain distance is burned out. The switch then closes a circuit that causes the coal to be pushed in. In this way, the arc can be kept relatively exactly in the same place, what a Constant illumination when throwing a picture, for example when showing a film, is essential is.

It is also known to feed in the coals depending on the voltage of the arc, because of this Voltage increases as the arc increases, i. H. when the coal ends move away from each other. A precise control must respond to even small voltage differences. This regulation does not guarantee a constant position of the arc, but only a constant length. Particularly when the coals are at an angle to each other, very annoying positional errors can arise.

Combining both methods does not seem possible at first because the feed movements are due to the radiation-dependent control bring certain changes in the arc length with it which the voltage-dependent control responds, even if it is not necessary, so that an override and mutual interference would arise.

These disadvantages are avoided according to the invention in that one of the tension of the Arc-dependent control device is provided for the advance of the negative carbon, which in Dependence on a switch, that of a relay of the control device influencing the positive carbon is actuated only as long as the negative carbon is fed forward as the positive carbon occupies their position in focus, but during one through the control device for the positive Coal caused, accelerated tracking of the positive coal remains switched off.

In a particularly expedient embodiment of the invention, means can be provided which the Protect control devices from overvoltages, the time between tightening and dropping reduce the relays used in the control devices and the feed devices Arc lamp with automatically regulating coal feed

Applicant:

Eugen Bauer G. m. B. H., Stuttgart-Untertürkheim, at the island power plant 10

Dipl.-rng. Dr. Kurt Müller, Stuttgart, and Josef Schleifer, Krumbach (Schwab.), have been named as inventors

ao give a simple, cheap, but versatile design.

An embodiment of the invention is shown in the drawing. It shows 1 shows a horizontal section through a lamp house with the mirror removed,

FIG. 2 shows a partial section according to II-II of FIG. 1, FIG. 3 shows a circuit diagram of the control devices of Lamp.

In the lamp house 1 of an arc lamp there are a holder 2 for a positive carbon 3 and a holder 4 for a negative carbon 5 attached.

The holder 2 consists of a housing 6, on the upper side of which cooled guide pieces 7 are attached are. They grip the positive carbon 3 and hold it between them with a certain pressure fixed, so that the fuel flow fed to the guide pieces 7 on a path not shown without disturbing contact resistance can pass over to the positive carbon.

A carrier 8 is attached to the housing 6. It contains bearings and drive elements for three rollers 9, 10 and 11, which rest on three different sides of the coal 3, and their axes to the axis of the Coal stand crooked. If the rollers rotate, they therefore also rotate the positive carbon 3 and at the same time push them through the guide pieces 7 in the direction of the arc.

The rollers 9 to 11 are driven via a bevel gear 12 which engages in a bevel gear 13. The latter sits on a shaft 14 mounted vertically in the housing 6. At its lower end there is a shaft 14 (not shown) Attached bevel gear that engages in a bevel gear 15. The shaft 16 of this bevel gear is in one Bearing block 17 stored on the floor of the lamp house.

909 640 / 21J

The holder 4 of the negative carbon also has a housing 18. A support part 19 is attached to this, on which a carriage 20 is slidably guided with the aid of guides (not shown). The negative carbon 5 is held on this slide with the aid of pliers 21.

In the support part 19 there is a feed spindle 22 which cooperates with the carriage 20 and advances it when it is rotated. The rear end of the feed screw carries a bevel gear 23 which engages in a bevel gear 24 mounted in the housing 18. On the shaft sits a ^two: tes bevel gear 25 which meshes with a bevel gear 26 in engagement. The "shaft 27 of this bevel gear is mounted with the help of a bearing block 28 on the floor of the lamp house.

The shafts 27 and 16 are connected at their end facing the operator side by a pin 29 (FIG. 2) to a curve piece 30 . The curve piece is surrounded by a drum-shaped drive member 31. Between these parts there are three balls 32 which serve as driving elements and which are pressed by springs 33 into spaces between the cam disk 30 and the drive element 31. They lie against a cylindrical inner surface of the drive member 31 and a curved surface of the cam piece 30. If the drive member 31 is therefore driven clockwise, it takes the cam piece 30 with it via the balls 32; this therefore represents the output member of a one-way clutch consisting of the parts mentioned. If the drive member rotates counterclockwise, the balls roll back against the pressure of the spring 33 as soon as the cam piece 30 opposes a rotational resistance that exceeds the spring force; the output member is then not taken along.

Each of the overrunning clutches of the shafts 16, 27 is assigned a switching element 34, 35 which is each connected to a shaft 36, 37 . The shafts 36, 37 penetrate the front wall 38 of the lamp house and at their outer end carry hangers 39, 40.

Each of the switching members is mounted on the associated VVelIe 36, 37 concentric with the associated one-way clutch and has three shift pins 41, which engage on the springs 33 opposite side of the balls 32 in the spaces between the drive member 31 and the cam piece 30th

If one of the handles 39 or 40 is rotated in the direction of the clockwise, the switching pins 41 lie against lugs 42 of the cam piece 30 and thereby take this drive element along with its shaft 16 or 27 with it. If the handles are rotated counterclockwise, the switching pins 41 lie against the balls 32 and, via these and the correspondingly compressed springs 33, in turn take the associated shafts with them. With the help of the handles 39, 40 the coals can be pushed back and forth as desired.

The drive members 31 are connected to one another via bevel gears 43, 44 and a shaft 45 which is mounted on the floor of the lamp house with the aid of bearing blocks 46, 47. The shaft carries a third bevel gear 48, in which a bevel gear 49 of a shaft 50 engages. The shaft is also supported by bearing blocks 51, 52 on the floor of the lamp house and at its rear end carries a bevel gear 53 which is in engagement with a bevel gear 54 . This sits on the shaft 56 of a motor 57 with the interposition of a friction clutch 55.

To the Schaltglicd 35 around a ring gear 58 is placed. This is assigned a bolt 59 (FIG. 2) which can be rotated about an axis 60 of a bearing block 61 fastened in the base of the lamphouse. In its rest position, it is held away from the ring gear 58 with the aid of a spring 62. A pull rod 63 , which is connected to the armature 64 of an electromagnet 65 , is articulated on the free leg of the bolt 59 designed as an angle lever.

ίο The end of the pull rod 63 that protrudes from the electromagnet and is opposite the bolt 59 carries a stop screw 66, the position of which determines the rest position of the bolt 59 . If the electromagnet 65 is excited, it pulls the armature into the position shown; the bolt 59 thereby engages in the ring gear 58 and holds the switching element 35 firmly. Thus, the shaft 27 and the \ ^T orschuh the negative coal detained.

On the opposite side of the bevel gear 54

A fan wheel 67 is placed on the shaft 56 of the motor 57. It sucks in air supplied axially through a pipe 68 and blows it partly over the floor of the lamp house, in the vicinity of which the above-described gear parts are mounted. A part of the lifter wheel 67 is surrounded by a housing 69 from which a tube 70 extends. It is divided into a tube 71, which is led up to the housing 6 of the positive carbon holder, and a tube 72, which leads to the holder 4 of the negative carbon. The pipe 71 opens between the guide pieces 7 and a heat protection plate 73 located in front of them. The cooling air supplied through the pipe is blown out in the direction of the carbon 3.

The tube 72 continues through the housing 18 of the carbon holder 4 and divides into two tube pieces 74, 75 with nozzles 76, 77 which blow the air supplied in the direction of the arc.

This arc forms between the negative and positive carbon after the lamp is ignited. The rays emanating from him - the rays 78 are shown in the drawing, which emanate from the point of attachment of the arc at the burning end of the positive carbon - are from a lens 79 on the. Side of the lamp house caught.

Thrown from a mirror 80 onto a second mirror 81 and from there through a filter 82 and a slit diaphragm 83 onto a photoresistor 84 . This photoresistor is mounted on the outside of the lamp house along with a number of relays that sit in housings 85. The relays and the photoresistor are surrounded by a hood 86 . Air inlet openings 87 are provided near one end of this hood; the tube 68 extends from the opposite end of the hood. The fan wheel 67 thus sucks in air through the hood 86 and thereby cools the relay and the photoresistor. These relays are described in more detail below in connection with the circuitry of the system.

The photoresistor 84 is shown again in FIG. 3; the slit diaphragm 83, the lens 79 and the coals 3 and 5 are also shown there .

The photoresistor is in a circuit from an AC power source 88. A relay 89 is connected upstream of it. The coil 90 of the relay is in series with the photoresistor; parallel to it is a capacitor 91. The capacitor is tuned so that it compensates for the inductance of the coil 90 when the soft iron core of the coil is retracted. A belongs to the relay

Changeover switch 92, which alternately connects one of two contacts 93, 94 to a contact 95.

The negative carbon 5 is connected via a line 96 to the negative pole 97 of a power source, the positive carbon 3 via a line 98 to the positive pole 99 of the power source. The positive one A relay 100 is connected directly upstream of coal. A switch 102 is assigned to its coil 101, the a contact 103 connected to line 98 and a contact connected to contact 95 104 and is open when the relay is not energized.

One end of a series resistor 105 is also connected to line 98, the other end of which connected to the contact 93 and via a control resistor 106 to the armature 107 of the electric motor 57 is. The armature, on the other hand, is connected to line 96 via a resistor 108. A second series resistor 109 is also with one end to the line 98 and with its other end connected to a line 110 connected to the contact 94. Between this and the resistance 108, the field winding 111 of the motor 57 is switched on. Between contact 104 and the line 110, an indicator lamp 112 and a resistor 113 connected downstream of it are placed.

The parts of the circuit described so far (control device I) are primarily used for Control of the advance of the positive coal. The elements regulating the advance of the negative carbon (Control device II) are connected on the one hand to line 110 and on the other hand to a tap 114. Its voltage is dependent on the operating time or temperature due to the following circuit dependent on the lamp: A line 115 connects the lines 98 and via two resistors 116, 117 96. The size of the resistor 116 increases with increasing temperature, the size of the resistor 117. on the other hand, is decreasing. Of these resistors, two taps 118, 119 are in the potentiometer circuit led away and connected via a resistor 120. This is in turn in potentiometer circuit the tap 114 is adjustably attached. (How it works is given below.)

The line 110 first leads to a protective relay 121. Its coil 122 is on the one hand on the Line 110, on the other hand at tap 114; An adjustable resistor 123 is connected in parallel with the coil. A switch 124, which is closed in the idle state and to which the line 110 is assigned, is assigned to the coil with a terminal 125 of a main relay 126 connects. A second terminal 127 of the main relay is connected to tap 114. The two connections have a non-linear resistance 128 the ends of a resistor 129 connected. At the end of this resistance drawn on the right one side of the coil 131 of the main relay is connected through a rectifier 130; whose the other side is connected to a tap 132 of the resistor. Is parallel to the coil 131 a compensation capacitor 133.

A switch 135 is located between the tap 132 and a second tap 134 of the resistor 129 which belongs to an auxiliary relay 136. One end of its coil 137 is connected to the tap 114, the other end via a switch 138 belonging to the main relay 126 to the connection 125. The switches 135 and 138 are open in the rest position. Auxiliary relay 136 also includes one Switch 139, which is closed in the rest position and ■

the line 98 connects to the electromagnet 65, which on the other hand via a resistor 140 to line 96 is connected, __ ..

As long as the lamp is switched off, the coil 101 of the relay 100 carries no current, so that the switch 102 is open and the control devices are de-energized. It stays that way even during the ignition process. The voltage between poles 97 and 99, which are usually terminals of a rectifier ίο , is higher during the ignition process than when the lamp is lit; this overvoltage is therefore kept away from the control devices with the aid of the switch 102.

Has the arc formed, thus causing the current flowing through the coil 101, relatively strong Lichtbogenstroin the buckle "of the switch 102nd

As long as the plus carbon 3 is in the correct position, no rays fall on the photoresistor 84. The relay 89 is therefore de-energized and the changeover switch 92 assumes the position shown. The field winding III of the motor 57 therefore receives current via the contact 94. The lamp 112 is short- circuited and does not light up. Since the armature 107 of the motor is constantly connected to the line 98 via the series resistor 105 , the motor 57 starts up after the switch 102 is closed, namely at a relatively low speed.

The shaft 56 of the motor rotates the shafts 50 and 45, the latter rotates via the bevel gears 43 and 44 Drive members 31 of the overrunning clutches on shafts 27 and 16. Shaft 16 is thereby taken along and drives the rollers 9 to 11; the positive coal is therefore continuously advanced. the The speed of this movement is such that it does not quite compensate for the burn-up of the coal. the One-way clutch on shaft 27 is blocked because magnet 65 is closed by switch 139 constantly receives electricity. The negative coal, whose burn-up is much lower than that of the positive Coal, therefore, stops. The air sucked in by the fan wheel 67 cools the air in the housing part 85 housed relays 89, 100, 121, 126, 136. The conveyed air cools the bearings of the gear shafts and is blown out at the points described above.

When the positive carbon 3 has burned back a bit, rays fall on the photoresistor 84 and make it conductive. A voltage therefore occurs at the coil 90 of the relay 89; the relay picks up and sets the changeover switch 92 so that it connects the contacts 95 and 93 . With the tightening of the armature, the capacitor 91 reaches its maximum compensation effect; the photoresistor 84 is therefore relieved of reactive current, and only a lower voltage is applied to the coil 90. The series resistor 105 has been short-circuited by the changeover switch 92. The armature 107 of the motor 57 therefore receives a higher voltage. The lamp 112 illuminates indicating that the Reg ¹ device is operating. The field winding of the motor only receives current via the series resistor 109 (the resistor 113 is relatively large compared to this). The field of the motor is weakened and the motor runs faster. He> 5 therefore pushes the positive coal in a short time prior to such an extent that fall on the photoresist 84 any more rays. Once the resistance of which increases only slightly, the opposite of the coil 90, by the above described process ό diminished voltage comparable even smaller, and the relay 89

Claims (6)

falls off. The changeover switch 92 returns to the position shown. As a result of the arrangement described, the relay 89 works very sensitively and has only a small margin between the pick-up and drop-out voltage. The control device for the advance of the negative carbon works only when the switch 92 is in the position shown, since the line 110 only then carries a sufficiently high voltage. The switch 124 remains closed as long as the voltage between the poles 97 and 99 remains in a certain range around the normal operating voltage. If it becomes higher, the protective relay 121 picks up and thereby disconnects the main relay 126. This protects the sensitive and relatively expensive main relay from damage. The response voltage of the protective relay 121 can be set with the aid of the resistor 123. The relays 121, 126 do not directly measure the voltage between the lines 110 and 96, but rather between the first-mentioned line and the tap 114. When the lamp is only freshly switched on, voltages are set at the taps 118 and 119, which correspond to the proportions of the corresponding fractions of the resistors 116 and 117 in the cold state. The tap 114 has a voltage which, depending on its setting, lies between the voltages of the taps 118 and 119. As long as the resistors are cold, its voltage is not sufficient to make the relays respond. This has the advantage that the voltage fluctuations between poles 97 and 99, which usually still occur some time after the arc has been formed, have no effect on the control device. If the resistors 116 and 117 are warm, the voltage of the taps 118, 119 and 114 has increased and is in the operating range of the relay. By adjusting the tap 114, the response voltage of the relay can be compared to the arc voltage, i. H. the arc length to be maintained by the relays. The non-linear resistor 128 and the rectifier 130 serve to make the coil 131 respond only in its working range, but particularly sensitively there. If the arc voltage has risen to the intended value, the main relay 126 picks up and closes the switch 138. The auxiliary relay 136, 137 receives current and in turn closes the switch 135, which short-circuits part of the resistor 129. The voltage applied to coil 131 is thereby lowered, so that even a slight decrease in the arc voltage would cause the main relay to drop out again. When the auxiliary relay 136, 137 responds, the switch 139 is opened. The magnet 65 is de-energized as a result, and the spring 62 pivots the bolt 59 out of the ring gear 58. The shaft 27 can therefore be rotated by the shaft 45 via the associated overrunning clutch, and the negative carbon 5 is advanced. These are always only small distances; as soon as the arc voltage is lower, the main relay 126 drops out , 137 is thereby de-energized again, the switch 139 closes and the feed of the negative carbon is locked again has attracted, so as long as the positive carbon is pushed in at an accelerated rate. Voltage fluctuations in the arc which occur during the pushing in, therefore have no influence on the movement of the negative carbon. Blocking the advance of the negative carbon also has the advantage that the negative carbon never occurs can be advanced to touch the holder of the positive carbon 6, for example when the positive Coal is not replaced in time and burns back completely. In this case the relay would always remain energized. The purpose of the friction clutch 55 on the shaft 56 is to avoid mechanical damage if, by any coincidence, both coals or even parts of the coal carriers should be pushed forward immediately. Patent aνSPHOche: 1. Arc lamp with automatically regulating coal feed, especially for motion picture projectors, in which the positive carbon depends on the position of its burning end, which is scanned by rays is advanced, characterized in that one dependent on the voltage of the arc Control device (II) is provided for the advance of the negative coal (5), which depends on of a switch (92), that of a relay (89) influencing the positive carbon (3) Control device (I) is actuated only as long as the feed of the negative coal caused when the positive coal takes its place in focus, but during one through the control device (I) caused accelerated tracking of the positive carbon switched off remain. 2. Arc lamp according to claim 1, characterized in that one of the rays of the Positive carbon (3) influenced switching element (84) is followed by a relay (89) which alternately produces a circuit that accelerates the advance of the positive carbon or the control device for the negative carbon turns on. 3. Arc lamp according to claim 2, characterized in that the relay (89) with a device is provided, which the voltage applied to the coil (90) of the relay after the response of the relay decreases. 4. Arc lamp according to claim 3, characterized in that the relay (89) with alternating current is operated and that its coil, a capacitor (91) is connected in parallel, which for the Compensation of the coil inductance when the coil armature is tightened. 5. arc lamp according to one of claims 1 to 4, characterized in that with the Coals (3, 5) a relay (100) is connected in series, the switch (102) of which the control devices (I, II) for both coals after the luminous flux has been formed with a current-carrying contact (103) connects, but from this contact when the lamp is switched off and during ignition keeps separate. 6. Arc lamp according to one of claims 1 to 5, characterized in that the armature (107) and the field winding (111) of the drive motor (57) for the advance of the positive Coal (3) one resistor (105, 109) each