DE160958C - - Google Patents

Description

i .ν * l'icl | c 11 $ α ic 11 Ια ι · 11 ».

¹ Γ. . '. it' O ι *

'ViitiU'piqt dct cJaiumliiiU]

IMPERIAL A

If in a system for remote reporting of scale information (in particular of level levels) several stations located on a radial route to a common center 7.11, the following should be reported System the use of a single, common Tclcgraphcnlcation enable.

• The facility is such that each station only reports when it comes from the control center is called automatically or by hand;

the transfer of the scale information takes place in that the called station stream-1 bump into the headquarters sends like this

»5 many groups of current surges than the size to be reported ■ has decimal places; Each of these groups consists of as many individual current impulses as the number in question, '< increased by one.

In the following, for example, an embodiment will be described which is used for

iNiveaiifernincldung serves and in which the ! Central does not work automatically. -

The general circuit diagram for such an arrangement is shown in FIG.

In the control center, the line battery B, the Morse code recorder P and the button T are connected in series in the line. The button T is set up in such a way that it can be used both for giving short power circuits and can also be fixed in the depressed position.

One pole of the track battery is connected to an earth plate E. '

The stations, the number of which is assumed to be at most 10 in the description, are all placed in parallel with one of their clamps a ', on the continuous line, and with the other, b, on earth plates E. ■ ·

The procedure for remote registration at the head office is as follows:

If the officer in the control center wants to find out the level in a certain station, he first triggers the drive of the Morse code recorder P and then closes the line current as often as the number of the desired station using the button T in intervals of about 1 second, z. B. three times. The currents go through all call contacts and also through the Morse code writer P and therefore generate 3 points on the Morse code strip.

Any length of time, but at least 15 seconds after the first contact, the officer fixes the button in the depressed position. Arises on paper this creates a line that ends after 1 second; after another second the Morse Code writer begins to work again

work; a line appears and then at intervals of a little more than ι second z. B. 4 points. This means 3 m. 16 seconds after the beginning of this first row of points, a second begins with z. B. 3 points, 2 that significant. A third row of z. B. 10 points,

; which mean 9 cm. Then or at the latest I minute after fixing the button, it must be released again.

The paper strip now bears the characters specified in the following line.

These mean that Station III is a

; '.. has a water level of 3.29 m. A possible one

'Negative level is increased by 10 m indicated positively.

The whole process of such a communication lasts for the one assumed in the description Running speed of the station equipment 80 seconds, what time. However by increasing the speed of the written drives accordingly be shortened by at least half

can. ,

"I ₁ Each station (the signaling apparatus is transmitted here a float ^ its movement on.) And has in addition to the measuring apparatus a solenoid three mutually mechanically independent complexes, namely the time drive that Wählwerk and Meßlaufwerk; act on the latter by the float from moving Parts.

The two drives are driven by weights or in any other way and regulated by wind blades or the like.

The time drive (Fig. 2) belongs to the shaft \ , which makes one revolution for every message, that is in a total of 80 seconds. On this shaft sits the ratchet wheel Z, which at two points of its circumference, which are held apart by an angle corresponding to 15 seconds, held by the armature of the magnet C ₁ by any intermediate links, respectively. when the magnet receives power, it is triggered, namely at second ο and 15.

While the timer runs at all stations when a station is called up, the measuring drive (FIG. 3) works alone at the called station. It runs continuously for 48 seconds during a message; during this time the shaft belonging to it makes one revolution; by means of the jamming wheel M , the measuring drive is triggered by the magnet C ₃ .

The selector mechanism (only indicated in FIG. 5) has a single shaft w on which the ten-tooth ratchet wheel W sits / .t, which is moved one tooth further with each back and forth movement of the armature of the magnet e _{3 in any known manner} . On the whole, the shaft w makes one revolution for each message on all stations. , '.-

On the three shafts \, in and w, there are contact disks which, in a well-known, popular way, short-circuit the associated interruption points in electrical lines in certain positions. The three contact disks of the timing mechanism are _{denoted by Z to Z 3} , and their effect is indicated in the circuit diagram of FIG are laid; those times, expressed in seconds of the 80-second period of rotation of the shaft w , at which the interruption point is short-circuited by the contact disk, are indicated by reinforcing the circumferential line, and their extent is defined by the number of seconds added. So it serves z. B. Z ₂ to short-circuit the points χ and ^ / · while the timer runs through the seconds 14 to 16. ■

The effect of the four contact plates M ₁ to M ₄ of the Meßlaufwerkes (Fig. 3) is shown in Fig. 5 in that the times during which a current circuit is established, expressed in seconds of the 48 sekundlichen rotation period of the shaft, into quadrilaterals, that lie between the relevant interruption points are registered.

The effect of the two contact disks W _x and W ₃ (Fig. 5) of the rolling mechanism is indicated in the same way as for that of the time mechanism. The circumference of the contact disks is to be thought of as divided into ten parts (corresponding to the ten teeth of W). The interruption point belonging to W ₂ is only open when the selector is in the rest position, the one belonging to W ₁ is only open when the selector has moved three teeth further, corresponding to the fact that station III is called up by three power surges. ! '

The arrangement of the contact washer W ₁ forms the only difference in the construction of tlerj no stations. The armature of the switching magnet e _i (Fig-. 5) connects the point u with g and the point j with / in the attracted state.

The movement of the float (FIG. 3) is received by a pulley and s thus transmitted through gears to the shaft, that this describes a change in the water level by 1 the one revolution. By means of a coupling to be described later, the shaft s takes along with it the shaft c (centimeter shaft) lying in its extension. .

The shafts d (decinic wheel) and t (meter shaft) are driven from c by toothed rivets in such a way that d every meter,. t at · io ni, which the swimmer covers, makes one revolution.

On each of these three shafts there is a contact wheel (decimal disk), which has the same shape for all three decimals. You are in Fig. 5 with "meter", "decimeter" and referred to "centimeters" and are made of a hard rubber sheet G are mounted on the two Kontaktkränzc D and K, which is supplied through slip rings electricity .. you are facing Kontakthebcl h, which are isolated from the waves that carry them. They are also supplied with electricity through slip rings and springs. They each have three narrow brushes p conductively connected, two of which on D respectively. K grind.

The wreath D. has such recesses that the associated brush only touches ten narrow slats, in which the numbers 0 to 9 are inscribed in FIG. The ring K, on the other hand, has only one recess which is located at the angle between the slats ο and 9 of D. The vertical dotted lines indicate the radius (reading mark) corresponding to the zero position. The current water level is therefore 3.29 m.

The centimeter and decimeter waves c respectively. d also carry two respectively. four contact disks c, and C ₂ and d _x to d _lt which are arranged as the latifvverke 'described above. Their mode of action is indicated in the scheme of FIG. 5 by numbers in the ellipses, so that z. B. d _x then closes the associated interruption point when the decimeter disc indicates 4 to 9.7; at the level of 3) 29 m assumed in the scheme, it would be open, as would d ₃ and C ₂ , while C ₁ , i.e. ₂ and d _{4 are} closed. V

. The third brush ρ of the three levers Λ slides over fixed, isolated Mcssinglamcllen Z ₁ to / ₅ .

You; The extent, their distribution and position can be seen from FIG. They "are connected in a peculiar circuit via the contact discs C ₁ , C ₂ and d _t to d _t with the point #.

The three contact levers / 1 are (Fig. 5) shifted by 120 ° against each other, while they are drawn in the wrong position in Fig. 3 for the sake of clarity; their shafts e are connected to one another and to the shaft in (FIG. 3) by gears in such a way that the levers move simultaneously at four times the angular velocity of m in the direction of the arrow in FIG. The; As mentioned, the shaft in makes one revolution in 48 seconds for a report, as ni Y ₃ revolutions for each of the three-digit number to be reported successively by one of the three levers / 1; Thus, the levers describe h at each location of such message 1 '/ ₃ revolutions per 16 seconds. In the idle state, the meter lever '/' rotation is in front of the zero position; while, as will be described later, it causes the meter to report, it passes the zero position twice and after 16 seconds is at the point that the centimeter lever was at the beginning.

The remaining circuits can be seen from the station circuit diagram in FIG.

The process in the case of a message consists essentially in the fact that the time drive of all stations is triggered by the call contacts and the dialing mechanism of all stations is set. As a result, all stations except the one called by the line management are switched off for the time of a message. The measuring drive then only triggers at the called station and, by temporarily connecting points b and α via one of the three levers Ii, the relevant decimal lamellas and contact g 11 , reports the level to the control center.

When the officer pressed button T three times, three current surges went through the battery and the Morse code recorder of the control center through the line and at all stations from α through e _x , x, \ _v C ₂ and b to earth. With the three current surges, C _{2 moved} the dial three teeth further; the first current surge triggered the timer, which now runs for 15 seconds at all stations and then stops.

When the button was pressed down continuously, current flowed through <? ,, at all stations to trigger the timer again, then via \ xr and Z ₂ to y and from there at all stations except III via W ₁ to b to earth. Only at station III has W ₁ not short-circuited the magnet e _a ; the latter has therefore triggered the measuring drive, which now runs for 48 seconds. At second 16, Z ₂ interrupts the current, which therefore only lasts J second, at all stations. .

Immediately afterwards the actual report begins. The decimeter and centimeter levers are initially out of the question and are switched off at this time by Ai ₂ and M ₃ . Two seconds after the measuring drive has been triggered, the meter lever brushes the lamella / ,. As a result, a current flows from B ₁ through Af ₄ , i. ₂ , I ₁ , h, M ₁ , b through e _t to B ₁ , and the anchor of lso e ₄ is tightened. This gives the current flowing through e _{i a second route}

from B ₁ through 7, i, JC, ft, M ₁ , b through e ₄ to Β _Λ , so that the anchor remains attracted 'when ft leaves the lamella /, until / i gets to the open spot of K.

U and g are also connected for just as long. While Λ was stroking over the meter slats 3,2,1,0, each time a current supplied by the battery of the control center went from the control unit via λ, ti, g, D, H, M ₁ and b to earth, and the Morse code writer wrote four points.

The lamella was not used. The meter lever now passes the lamellae /, and / _{2 again} , but there is no current _{through e 4} because M _{x is now open.}

When the measuring drive completes the first third of its run, the Decimeter lever in the meter lever at the beginning

ao approaching situation ,, and the message of I) czimetei _> y-> Vpl) ei- ^; through ';. M, ¹ ' urtd M _x , the two other levers are switched off.

The decimal lever marks / ₃ without effect, since C _{1 is} open, and, only / ₄ has the same

Effect as before V ₁ ; Furthermore, the message takes place as with the meters. The centimeter is also reported in the last third of the 48 seconds. Here, however, there is only one solid lamella./ ₅ yor-

ties, ¹ V ^ .: ■ · · '■ _; -W- <'' ■: Vr '■■'. ■

The O measuring drive comes to a standstill at second 63 of the time drive. In the still; the rest of the 17 seconds the dialing mechanism of all stations is brought back to rest. -: \ "-. '2% closes and opens .; for this purpose, ten times its interruption point, and as a result, so many dials flow from battery B. ₂ via Zj and W ₂ through C ₁ , advancing current impulses, until the zero position of the dial is reached and the other power surges caused by W _{9 are} prevented.

At the second 80, all the timers stop and everything is ready for a new report.

The aforementioned clutch. between the float and the decimal discs has the purpose, to be explained in more detail below, to prevent the centimeter disc from taking up a position between 9.5 and 0.5 cm during a report. The shaft s (lug. 4) carries the disk S, which by the helical springs f, which are attached on the one hand to S and on the other hand to an arm of the opposite lever / 7 sitting on the centimeter shaft c , drives the latter as it rotates. ,! -'Ehic ', - ,.''f ^ dprnde twisting of both shafts against each other; is therefore possible. In the other arm of // the bolt R, which carries the pin J, is radially displaced;

slidable .. This pin protrudes into a _{cutout '(} cutout ..N _{1 of} the disc''"&', which the-.

is curved art that with a one centimeter water level corresponding to each side shift // opposite · S R latch is not moved, probably at alier 'larger displacements about a ijestimmten maximum amount. |

With a progressive change in the water level by half a centimeter of water level , before H reaches the position ο cm indicated by the dotted line , R hits a stop A, and S goes on alone. Only after a further movement of the swimmer by i.cm is R withdrawn by J and can pass A; .// suddenly snaps through the zero position. j

However, if the station reports, d, he is designed as a lever stop A by the. ' running measuring drive by means of any intermediate links ,, z. B. by .. grooved washer [//, ■ lever and cable transmission, pushed closer to c . R happens to be at this time. in;; der: position; ■ ±; '/., cm and moved. If the swimmer moves further, the shift of R caused by N is no longer _{sufficient to;} Passing A, and H must remain in his position until the end of a remote message. The centimeter disc can therefore never indicate the true period of a message between 9; $ and '0 ^ 5: cm. .;. \>. ·· 0; '.}' ■, ':'';'■''"', · '.' V '■;. · ■': .. ■■

The circuit of the contact disks C ₁ , 'c, and rf, to d _t causes now that the lamella /, respectively. /, _r only: during an approach of the decimeter: or centimeter disc lying within the first half of a meter or a decimeter, connected with the / point. During the second half, however, /., Or. /, effective.

The double arrangement of two lamellas Z ₁ and /.> With the meter disc respectively. A ₁ and I ₁ in the case of the decimeter disc is, for the reason, taken in order to avoid the faulty contacting 'in the case of positions of the meter and / or. the decimeter disc, which are already approaching the full meter or decimeter, to be held back.

To give an example, the following should be mentioned: no

The lamella / j covers most of the zero position BEZW. that position from which to the. Measurement of the scale takes place while the second lamella /., A little further on and the next section; iler .scale · includes. As shown in FIG. 5, the moment the lever / 1 comes into contact with the lamella Z _1, the relay t ' ₄ comes into action and thereby enables the current surges caused by touching the lever / 1 with the contact disks 3, 2 > 1 and, O are brought into the line

10

20th

can also be posted. Accordingly, four currents go out into the line, and, the measurement!, Results: consequently 3 m. / According to the drawing, iii Fig. 5Γ; stands the deci-S inctcrschcibc ^; .beinaiie on ■ i3; dcin: and. the ^; Centinict disk on '51 cui ;. so that -the ^; Water level in: this case is 3.29 m: If the water level increases, the contact wheels will move accordingly.

The case is assumed that the water level 3.93 / ni: was carried. Corresponding to this position, the contact piece 4 has already entered the area of the lamella Z ₁ and would immediately send a current into the line during the measurement that now follows, after the lamella Z _{1 has} also brought the relay to redeem at the same time. . So five Kon ^ · 't.iktstölje would be sent out into line ¹ , "which would be. Rcits'; corresponds to 4 meters" In order to prevent this error, the lamellae Z ₁ and Z _{2 are} switched over by appropriate contact circuits at C ₁ , C ^ and d _x to d ₄ , so that the lamellae is from one contact block to approximately in the middle between it and the second Z ₁ remains switched on, while from there, i.e. from the middle to the next block, the lamella Z _{1 is switched} off and the lamella Z _2. In the latter case, the meter size, where the measurement is 3.93, would be Z _{1 be} interrupted by contacts C ₁ , C ₂ and ^ ₁ to rf ₄ , so that a contact of the lever h with the contact block 4 would be ineffective as the line on which the transmission of these current surges would take place through the relay e ₄ ! is interrupted and the relay can no longer be switched on _{by! lamella Z 1} Lever now on its: Continuing in contact with lamella Z ₂ , so at this moment the relay e _{4 will} [function, it will connect the! Message line with the contact blocks! And the lever Zi, which now, ' lying in the area of the lamella Z ₂ , the con. ^; Touched clock block 3 can now send a current impulse into the line, so that again four current impulses arrive at the Morse-'Schreiber, which corresponds to a number of meters of 3 m. Exactly the same process also takes place with the decimeter disc. In order to designate the use of these slats ■., It should be noted that the slat Z ₁ BEZW. Z ₃ the relay only in the! Intervals of the whole meters ■ or. whole decimeters over 1, 2, 3, 4 to 5 tenths in action, while if the 5 tenths are exceeded, lamella Z ₂ takes over the further function and the relay is switched on from 5, 6, 7, 8, 9 tenths to to the full meter or Decimeter division takes over. This means that it is impossible, for example, for a water level of 3.99 hi to result in the meter 4 reporting. ; . . . ',,.

-; ■ · '■■. If, however, a circumferential contact pin pulls the magnet e _{4 by} means of a currently active lamella Z, this causes, as already discussed, that, starting from this moment, every decimal lamella up to and including, over which the relevant contact lever continues Urrjlaufe grazes, a short circuit of the points α b \ thus generates a Mcldcstrom. ,

. ■■ .. would be ζ., 'Β. If the water level is exactly 4.00 m, the jumping floating coupling only allows the dcimal disks to be set to 3 ^ 95 m or 4.005. m; In both cases, the slat 4 of the meter and the slat or the centimeter is almost exactly in the! Zero position. 'If the centimeters stand up to - | "0.5, then' - the lamellae /, and Z _{3 are} effective; e ₄ pulls its armature before the relevant contact lever passes the zero line, and the meter lamella 4 resp. the decimal lamella ο already cause a signal current; the signal will therefore be 4.00 m.

If, on the other hand, the centimeters are at 9.5, the lamellas Z ₂ and Z _{4 are} effective and the molding is 3.99 m.

A fixed slat is sufficient for the centimeters as the last decimal. ; '■■ ·. ■■

The magnets C ₁ , e ₂ and e ₃ , like the Morse code recorder of the control center, can be operated by a relay instead of switching them directly into the line current.

Instead of juxtaposing the stations, appropriate changes can be made the series connection can also be used. ■■. ·. '.

The batteries B ₁ and B ₂ and the local battery required when using a relay can be combined into one.

The magnet e ₃ can also easily take over the function of e _4. The pole of .B ₁ now at e ₄ is then connected to y .

If the lamella ο omitted any Dezimalscheibe and simultaneously the lower 'of the contact circles K refraction point (Fig. 5) accordingly by' / ₁₀ of the circumference is increased, so is the number of message collisions per decimal not by one 'is larger, but equal to the numeric values of the relevant ¹ decimal place. '

The time and the measuring drive can also use common drive iao force and a common speed regulator are connected to each other ^

Claims (2)

so that with each message the levers h of all stations run there. W ₁ and Cj with the triggering device for the measuring drive are then omitted; this is to be arranged on the Wahlwerk- \ vellc n> a new contact disc, which only produces the Veibindung between q and M _i, when the Wählwerk on which stands the station number corresponding tooth. The levers h ^x are so easy to use ίο that they are in the same position at the right time as with the original arrangement , to take. ■■■ '·.,;. . · '■''■,' ·. If only one station is to be connected to the control center, the timing mechanism and the selector, thus also the magnets C ₁ and C ₂ and the associated lines, and 'the measuring drive is z. B. by a clock located in the station in any interstices mechanically or by means of the magnet e _{; j} electrically triggered to a sequence. The center can of course also be operated automatically and the messages register in any way. Godfather NT-A ν Spruch κ; I. Apparatus for electrical remote registration of multi-digit indication scales of the measuring instrument of any of several lying on a line stations, characterized gekcnnzeich _t net, da.β on each station of the number of For this purpose ι sheet of drawings. PERMN. PRINTED | N THE COVERED The number of ten-lamellar (or nine-lamellar) contact rim disks to be reported is arranged corresponding to the number of decimal places to be reported, which are set by the measuring instrument by means of a tooth transmission of a known type according to the respective indication of the measuring instrument, the remote registration of the measured variable being carried out in such a way that contact, lever ( h), which are moved by a measuring drive that can be triggered by the control center at any time, over the contact ring disks, one after the other a number of current impulses, each of which is Ϊ one greater (or the same) than the number given for the relevant one Send the decimal disc, over which the associated lever moves, into the long-distance line. 2. Apparatus according to claim 1, characterized in that a contact disc (W ₁ ), which belongs to a dialing mechanism, which is moved in a manner known per se by current surges emitted from the control center, a circuit at each station at a different point of its Uinfanges executes, as a result of which (e.g. by preventing the triggering of the measuring drive or by interrupting the signal current circuit) the transfer of the measured variable can only take place at the station whose serial number corresponds to the number of current impulses sent by the control center.