DE13885C - Innovations in pneumatic clocks - Google Patents

Description

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CHES

PATENT OFFICE.

PATENT LETTERING

CLASS 83: Clocks.

Innovations in pneumatic clocks.

Patented in the German Empire on May 5, 1880.

The present clock system is based on the use of compressed or diluted Air as a means of transmission and realizes this principle through apparatuses in which the air is kept under pressure and after every minute by a central clock in small Quantities sent according to all clocks connected to the pipe network will.

The central clock therefore only has the role of a controller in this system and is not more, as was the case with the previously known systems, used the air to be pressed into the pipelines. The present system is thus made up of two particular main parts, namely, consist the same for compressing the transmission medium from a suitable reservoir and for the purpose of distributing the compressed air from a network. The distribution itself is through a switching device influenced by the central clock every minute.

The air reservoir and pressure regulator are illustrated in FIG. The reservoir A is fed with compressed air by means of the pipeline B from a high pressure reservoir. This air takes the following route: It passes through pipe C into pipe D and first hits the three-way valve E, which is closed towards D , but connects pipes J ⁷ and B with one another. On the other hand, the air passes through pipe D to the three-way valve G, which is fully open, so that the air in the pipes H and J and. can enter pipe K through the three-way valve Z, which is also fully open. This tube is closed at the bottom; however, pipe F branches off from pipe K , which communicates through tap E with pipe B , which the latter conveys the air into reservoir A. In the pipe branches H and J , the taps H ¹ and J ^{1 are} switched on, which are closed as soon as the pressure in the reservoir A exceeds the normal level (0.7 atmospheres).

For this purpose, the reservoir A is connected to the two pressure gauges M ¹ M ¹ through tube α and the three-way valve b . These manometers connected to one another form the pressure regulator. Each manometer consists of a lower tank into which the pipe coming from reservoir A opens; The pressure gauge tube extends from this boiler.

The lower boiler is connected to an upper one, in which there is a float, which is the key of the cock H ¹ BEZW. J ^{1 is influenced by} means of a rod and lever in such a way that when the pressure in the reservoir A and thus also in the pressure gauges M ¹ M ¹ falls, the mercury in the pressure gauge tube and in the upper boiler sinks and the floats switch the taps JjT ^{1 and} . J ^{1 can be opened} to a certain extent, and thus some strongly compressed air can get into the reservoir A. As the air pressure in reservoir A increases, so does the mercury in the pressure gauges; the swimmers take part in this movement and accordingly close taps H ¹ and J ¹ . The reservoir A is also equipped with a manometer c, a tube N for the direct introduction of strongly compressed air. And two tubes P for the

Discharge the air to the valve boxes of the pipe network.

The apparatus illustrated in FIG. 2 is used to operate the clocks. The same consists of several leather lenses, which are united at the edges by copper rings. The bellows formed in this way is closed at both ends by a copper washer, one of which connects the apparatus to the supply pipe, while the other to it is intended to act on the clockwork.

3 and 4 show a small pneumatic clock in view and outline.

The compressed air coming from the main line reaches the cylinder d, in which it acts on a piston which can also serve as a guide for the bellows shown in FIG.

The piston rod of this piston is connected to a lever e which carries a pawl / which acts on the ratchet wheel g with 60 teeth. The axis of α bears the minute hand. D by the entry of compressed air into the cylinder or located in the same through. Bellows the ratchet wheel is turned one tooth and the pointer associated with the same one minute proceeds further. The pawl h prevents the ratchet wheel g from reversing. The pawls f and h are pressed against the ratchet wheel g by small counterweights f ¹ and / z ^1.

Through the Zahnradübersetzimg ijk I the hour hand is driven in a known manner by the ratchet wheel g.

If the bellows, Fig. 2, are used instead of a piston, the upper plate is released of the bellows act against a rod, which exactly as described above, the Circuit causes.

With larger clocks, the operation is analogous to that described above. However, it could happen here that the minute hand would be adjusted by hand by an unauthorized person; in order to make this impossible, the arrangement illustrated in FIG. 5 is made. It consists of a vertical lever m which proceeds from lever e and forms a body with it. This lever has a nose η at its upper end which, in the rest position of the lever e , engages exactly in an incision in the pawl h and absolutely prevents the switching wheel g from turning by means of the minute hand. If the lever e is lifted by the compressed air, the nose η allows a movement of the pawl / 2.

Furthermore, a pin t is attached to the housing plate, against which the arm of the pawl f , which carries the counterweight f ^{1, abuts;} This pin also prevents unauthorized adjustment of the minute hand. The slide for distributing the compressed air is relieved and shown in two sections in FIGS. The compressed air passes from the reservoir through the pipe P at the mouth R into the valve body Q. The valve body Q is also connected to the pipe network through the channel S, but through the channel T with the atmosphere.
. If the slide U is in its normal position, as shown in FIG. 7, the channel S communicates with the atmosphere through channel T , and only atmospheric pressure prevails in the pipe network. At certain moments the central clock acts on the slide rod by means of the double lever "X" and rod V, opens the channel S and closes the channel T, but always leaving the channel R open. The compressed air then enters the pipe S and acts on all of them , clocks switched on in the pipe network.

The slide U is now moved back to its initial position, the channels 5 and T are connected to one another in this way and the compressed air escapes from the pipe network into the open.

In order to reduce the friction of the slide, it is relieved in the following way.

The back of the slide is bored out cylindrically, and a piston U ^{2 is} mounted in this cylinder U ^x , the rod Y of which carries a roller Y ¹ which runs on a cross member Z fastened in the walls of the valve body.

In this way a large part of the slide friction is converted into rolling friction. In reality, the slide is only pressed onto the slide surface with a pressure which corresponds to the difference between it and the cylinder cross-section U ; in the present case the pressure is reduced to the fifth part.

Instead of this slide control you can also use a valve control with which by means of several pipes the various pipe networks are connected.

In Figs. 12, 13 and 14 there are two different ones Illustrates arrangements of this system. These two modifications are the same in terms of the particular construction of the valve and distribution apparatus, they differ only in the external control mechanism. The most essential organ of this apparatus is a rod, which at its lower end carries a valve that supports the purpose has to connect the distribution chamber to the compressed air reservoir; the upper Part of this rod is provided with valves, through which the openings to let out the compressed air to be opened and closed to the outside.

Fig. 12 is an external view of one of the apparatus in which the closing of the pressure valve by means of bellows, as described above, and which bellows by compressed Air driven and controlled by the central clock. Fig. 13 is a vertical section of the second system, in which the closing of the pressure valve by the central clock takes place directly.

The compressed air enters the apparatus through tube A. This tube communicates with the air reservoir through tap B and tube C. The cock B is, as can be seen from the drawing, rotated by a helical gear C ¹ , which in turn is set ^{in rotation by a spindle C 2} and a hand wheel C ³ when the system is to be put into or out of operation. From the pipeline C , the air reaches the chamber D, which serves as a reservoir and carries the seat E of the valve F. Every minute this valve is moved by the rod G to which the counterweights H are attached, the lowering of which causes the valve F to open quickly. The rod G is connected at its upper end to a lever J , which leads to the central clock.

In the normal state, the rod G is raised by the watch and the valve F is kept closed by latching the lever J. At the appropriate moment, ie after every minute, the lever J is disengaged, the valve F is suddenly opened and the reservoir D is connected to the chamber K , from which the pipes L extend, which lead to the various pipe networks.

The compressed air enters these pipe networks and acts on the clocks which go into the networks are switched on and must escape outside after a few seconds.

For the latter purpose, the chamber K is provided with the outflow channels L ^x . There are just as many channels L ¹ as there are pipes L , and these channels L ^{1 are} closed at the moment when the valve F is opened. When the central clock acts on the rod G by means of the lever J to cause the valve F to close, the valves M leave their seats and the pipes L opening into the chamber K are connected to the free air through the channels L ¹ set.

In the apparatus described above, the closing of the valve is effected by the clock itself, by means of the lever J, which the clock moves directly. However, in order to avoid the inconvenience which arises from this arrangement, namely the jolts which occur when the valve F is opened quickly by the weights H and which are transmitted to the clockwork by lever J , the device shown in FIG. 12 can be used. The rod G is here connected to the cross member G ¹ , which carries two counterweights H ¹ and is held at a suitable height by the nose η of the two levers N. At a certain moment the levers N are shifted by the clock by means of the rod 7V ¹ and eccentric O so that the lugs η release the traverse G ¹ and the valve F is opened under the action of the weights IT. Thus compressed air will get into all pipelines L , and the ducts leading outwards will be closed.

Another eccentric P acts on a three-way valve R, which is connected by pipe r ¹ to the chamber K and by pipe r ² to two bellows S , the rods S ^{1 of} which lift the cross member G ¹ and the closure of the valve F, as well as the Opening the outflow channels L ^x cause the cross member G ^{1 to be} supported again by the lugs η of the levers IV , which are pressed on by springs JV ^2. The tap R (shown in cross section in FIG. 14) now connects the pipe r ² with the atmosphere, and the air can also flow out of the bellows, which lower, so that they are ready to repeat the same game after a further minute .

The compressed air is distributed in the various networks by the apparatus shown in FIG. The ones from the valve body or the distribution valve. Coming compressed air passes through the pipe m into the cylinder η, from which the cocks ο proceed. These taps all end in fork tubes /, on the legs of which the conduit pipes q with shut-off cocks are connected. From these conduits branch off in turn the tubes which direct the compressed air to the individual clocks.

The device shown in FIGS. 9 and 10 serves as the control apparatus.

This apparatus consists of the closed glass vessel r, into which the glass tubes j are immersed to near the bottom; the vessel r is filled with mercury and is connected to the pipe network through tap t and pipe u; the mercury is connected to one pole of a battery by a wire which dips into the mercury as far as the bottom of the vessel r. If the air can reach the vessel r , it will drive the mercury up in the tube s ; if the voltage drops, the mercury in the tube ί will also fall. It follows from this arrangement that, when the voltage in the pipe network becomes too great, the mercury in the pipe ί will rise quite high and come into contact with the platinum contact X , whereby the electric current is closed and a bell is activated .

Claims (1)

If, on the other hand, any defect should arise in the pipe network, the mercury level in the pipe would fall continuously and the vessel would be completely filled with mercury until the level reached the platinum contact X ¹ and a second alarm device would be activated by the electrical current that is closed will. The tube ί is closed at the top by a head piece y , which is shown in Fig. 10 on an enlarged scale. The Platincontact X goes through the middle of this head piece and is sealed by a stuffing box. In addition, the head piece has two through-holes y ¹ y ² . The former contains the regulating valve, by means of which the opening y ^{1 can be closed} more or less, so that the entry of air into the upper part of the tube is more or less restricted, and thus the movement of the mercury in the tube s is faster or slower he follows. In this way the entry of air can be regulated in such a way that the mercury can rise and fall once a minute, the rise of the mercury corresponding to the increase in pressure in the pipelines. In the through-hole y ' ^{2 there} is arranged a spring-loaded valve z ¹ which allows the air contained in the upper part of s to escape quickly during the rise of the mercury, ie during the time when the pipe network is under pressure. The stroke of this valve is regulated by a screw z ² . Now produces a defect in the pipe network, the mercury in the tube is ί fall continuirlich because the atmospheric air always find through the channel y ¹ access, and it is the mercury level in the pipe ί and vessel, r to face the same. The general arrangement of a network of pneumatically operated clocks is schematic illustrated in FIG. 11. The air is compressed in the pumps and arrives in the compressed state in the High pressure reservoirs 2 3. Each pipeline connecting one of the pumps to the high pressure reservoir connects, is provided with three-way taps 4, of which pipes 5 to the Reservoirs 2 3 lead. The two reservoirs are connected to one another by the pipe 6 provided with taps. From a second connecting pipe 7, a pipe 8 goes to a three-way valve 9, which is connected to two other valves ι ο and 11 and from which the pipes 12 and 13 lead to the valve boxes 14-15. From these valve boxes, the pipes 16 17 go to the distributor 18 for the various pipe networks. The slides in the valve boxes 14 and 15 are controlled by the central agitators 19. The air coming from the reservoirs 2 and 3 is passed through the pipeline 21 20 to the regulator 22 and from here through the pipe 23 to the reservoir A ; two further tubes 24 and 25 connect the reservoirs 2 and 3 directly to the reservoir A by means of the tubes 26 and 27. In normal operation, the reservoir A serves solely as a distribution apparatus. The reservoirs 2 and 3 are then high pressure reservoirs. The taps 34 and 39 are then fully open to connect the two reservoirs to one another. Cock 9 of reservoir A is closed, cocks 37 and 42 of pipe 21 are open and the compressed air passes through cocks 37 and 42, pipes 21 20, cocks 22 29 30 of the pressure regulator, pipes 45 46, cock 28, Pipe 44, cock 31 (because the cocks 38 and 43 are closed) and pipe 23 after the reservoir A; the taps 35 40 36 41 and 9 are closed, the reservoir A is therefore not in direct connection with the reservoirs 2 and 3. If one of the two reservoirs 2 and 3 is to serve as a distribution reservoir, in the event that reservoir A should become defective, for example 3, this reservoir is connected through pipes 12 and 13 to valve boxes 14 15 by closing valve 35 and opening 40. In the same way, the reservoir 3 can be connected to the pressure regulator by the cock 42 closes, 37 opens, 31 and 38 closes and the cock 43 of the pipe 25 opens; It is also clear that by means of all the cocks 4, as well as the cocks 34 and 39 of the Pipe 6 the connection of the two reservoirs 2 and 3 is to be interrupted. The air then makes the following path: From reservoir 2 it passes through tap 37, the pipes 21 20, the taps 22 29 30, the Pipes 45, 46, faucet 28, pipes 27, 25, and faucet 43 into reservoir 3, and from there through pipe 7, tap 40 (pipe 35 is closed), pipe 8, tap 9 and pipes 12 and 13 after the valve boxes 14 15, the Taps ι ο and 11 are then closed. Ίη In this case, of course, the reservoir 3 is also not fitted with the pressure gauges to connect drawn pipelines. One could also connect the reservoir A with one or the other reservoir 2 and 3 by opening and closing suitable cocks in order to use the same as a high pressure reservoir, and let the other of the two reservoirs 2 and 3 function as a distribution reservoir. Patent claims: We claim all of the innovations described and illustrated, which are included in the following points can be summarized: The distribution reservoir and the pressure regulator, which by two with each other connected pressure gauges, the floats of which act on the taps, which mediate the distribution of the compressed air. The bellows, consisting of leather discs, which are connected to each other by metal rings are. The operating mechanism for the pneumatic station clocks, consisting of a Ratchet, a pawl and a pawl. The relieved valve, which relief by means of a cylindrical bore and takes place in the same matching piston on which the air pressure acts and around which Pressure on the slide is relieved. 5. The apparatus for distributing the compressed air to the various pipe networks. 6. The control apparatus, consisting of a mercury manometer in which the Liquid levels, depending on whether the air pressure is too high or too low, cause an electric current to close and thus set a bell in action. 7. The general arrangement shown schematically in FIG. For this purpose ι sheet of drawings.