The Paris Pneumatic Clock Network

This the distribution room for the Popp network. In the glass case (vitrine) can be seen one of the distribution clocks, as illustrated above. The top of the case is labelled 'Horloge Centrale No 1', though lower down is a label saying 'Reserve' which seems contradictory; if it's the reserve clock, surely it should be called No 2? Presumably the case at the rear contains a second distributing clock. Here the valve is shown as outside the glass case.

The tank on the left is the distributing reservoir. The two dark things next to it that look a bit like coffee-urns are the pressure regulators between the high-pressure reservoir and the distributing reservoir. Note they are in duplicate for reliability, with isolating valves to disconnect a faulty regulator. In the original illustration it is possible to read 'regulateurs du pression' written on the wall just behind them.

I assume that stringent precautions were taken (presumably in the form of safety-valves) to prevent a regulator from failing and allowing the high pressure air to enter the network. This would burst the bellows in each clock and Paris would be treated to the alarming spectacle of 7,800 clocks exploding. Going popp, in fact.

Date of image currently unknown.

This shows a boiler at left, with a horizontal steam engine mounted on it. This drives by belt a countershaft hidden in a slot in the floor. This shaft drives by belt four Sauter-Lemonnier vertical double-action compressors. Four pipes can be seen leading from the compressors to the high-pressure air reservoir.

According to the diagram of the plant just below, there should have been two boiler-engine assemblies, but only one can be seen here. At the extreme left there seems to be some other sort of horizontal engine.

This is an overall diagram of the plant at the rue St-Anne distributing station.

Popp clearly took the reliability of the clock service seriously, with almost all the equipment duplicated or quadruplicated. Nonetheless on one occasion an accident at either St Anne or the later time distributing station at St-Fargeau caused all the Popp clocks to stop at 10:48am until repairs were made. (I have mislaid my reference for this event- if anyone can point me to it I will be grateful)

• A- Two combined boilers and engines
• B- Four vertical compressors
• C- Two high-pressure air reservoirs
• D- Low-pressure air reservoir
• E- Two pressure regulators
• F- Two distributing clocks
• G- Control valves for different branches of the network
• H- Pressure switch to indicate air pulse sent by ringing a bell

From Engineering 24 June 1881

This is a diagram of the pressure-regulating plant at the rue St-Anne distributing station. Note that there is a provision for connecting the high pressure air directly to the low-pressure reservoir, by means of valve f. Why you would want to do this I do not know, because as mentioned above I would have thought it would have caused all the clocks to explode.

• b = High pressure air to pressure regulators
• d = High pressure air direct to low-pressure reservoir
• D = Incoming high-pressure air
• p = Pressure regulators
• R = Low-pressure reservoir

From Engineering 24 June 1881

Each regulator consists of a lower closed chamber A and a chamber C open at the top. In chamber C a float E is connected to a tap c shown in the diagram just above. Chamber A is partly filled with mercury and the air pressure admitted at F forces the mercury up into chamber C, raising the float E and closing the controlling tap, shutting off the flow into low-pressure reservoir R.

The tube D is described as a pressure gauge showing the level of the mercury; presumably it was a glass tube. The tap at the bottom could be closed if the tube was broken to minimise the loss of expensive mercury.

From Engineering 24 June 1881

Compare this drawing with the one above. There are differences in the detail but presumably the same clock was being illustrated. Here we can see more of the internal workings, but it is still not possible to locate the balance-wheel and escapement.

There are three 3-way valves R. In an emergency two of these could be used to isolate the sliding valve, and manual air pulses given by the middle valve R.

If the automatic rewinding failed, causing the main weights to descend too far, an electrical contact rang an alarm bell.

Bottom right at Fig 6 is a section through the sliding valve.

From Engineering 24 June 1881

The air released by the distributing clocks enters at the top of the drawing. The two large valves labelled I and II are linked by spur gearing, so that turning the handle n switches from one distributing clock to the other.

The air goes into chamber c and then splits up into five pipes each controlled by a valve a. Each pipe then splits in two again, with each of the ten pipes controlled by a valve f. This would appear to make the a valves redundant.

Each outlet pipe carried a small valve g (only two are shown here) which allowed air into small-bore pipes, which were connected to pressure gauges and the mercury switch H which rang a bell to indicate each air pulse.

From Engineering 24 June 1881

The Popular Science Monthly tells us:

"A leather or rubber flap, seen in the cylinder, receives the impulse as it comes from the pipe and moves a piston, which acts upon a lever-arm arranged by simple connections to move the minute-hand one space forward. The ordinary clock-gearing (not shown in the figure) secures the proper motion for the hour-hand. This part of the apparatus can be inclosed in any case—as plain or as ornamental as desired. The cases are made in all the designs and sizes of ordinary clocks, and appear precisely like them, except that the minute-hands jump suddenly over one space at the end of each minute, and remain stationary during the minute, instead of moving gradually over the space."

I also find this description faulty. There is no 'flap'; what we have is a bellows in a can, made of soft rubber sections joined by brass rings, which pushes the 60-tooth wheel round by means of a pawl which is weighted to keep it in contact with the wheel. At the left a second weighted pawl prevents the wheel from slipping backwards. Probably the biggest design problem here is the danger of the inertia of the wheel causing it to advance by more than one tooth. There does not seem to be any sort of positive locking to prevent this.

It is interesting that the mechanism uses weights to keep the pawls engaged rather than springs, which would have been more compact. The answer is probably that compactness is of no advantage in a big thing like a public clock, and that weights would be more reliable than springs which might break. Both weights are adjustable in position.

The Observatoire can be seen in the lower middle of the map. The Rue St Fargeau is coloured red.

At the Paris Observatoire a high-standard astronomical regulator clock was kept running on correct mean time by astronomical transit observations, being corrected daily. Pulses of electricity were sent every second to secondary clocks around the city, the wires being run through ducts in the sewers. Two loops starting and ending at the Observatoire carried thirteen clocks between them, the farthest being at a distance of seven and a half kilometres, or nearly four and a half miles from the observatory. The clocks were of a high standard, so they could keep good time even if the synchronising pulses failed. (The pulses synchronised the clocks but did not drive them, they were weight-driven in the conventional way) The secondary clocks were furnished with second-hands, and were placed so that they could be easily seen from the street, usually in prominent positions. They further distributed time by sending electric signals once an hour to synchronise various public clocks. The system came into operation in 1878.

The secondary regulator at the Hotel de Ville sent synchronising pulses once an hour to the twenty mairies of Paris, over the telegraph circuits connecting them. (A mairie is roughly equivalent to a borough town hall in London) The nearest to St Fargeau is the mairie of the 20th arrondisment, just to the east of the Pere Lachaise cemetery. This is still some 700 metres away, and I am left wondering how the time covered that last step. Given the short distance, carrying a good pocket watch between the mairie and the distribution centre would have been practical.

The company of Collin & Wagner was prominent in making turret clocks for churches, etc. The clock sown here is what in England would be called a master clock, distributing time to slave clocks. The French refer to these rather more delicately as an Horloge mère (mother clock) horloges filles. (daughter clocks) The cylinder on top is an air pump which impulses the daughter clocks, powering them from its own weight drive rather than controlling externally supplied compressed air. There is also a pair of electrical contacts at the front, visible just above the windimg square.

The brass plate on the front carries this inscription: "Ce mécanisme fait mouvoir les aiguilles des Grands et Petits Cadrans du Casino par le système de transmission à Air comprimé de Collin Sucr de Wagner, 118 rue Montmartre à Paris".

On the pump body is written: "Moteur Air comprimé Collin Breveté S.G.D.G." [G0097]
A brevet is a French patent.

As far as the Museum staff can discover at present, this system was purely a local one suitable for operation in one building, and there is so far no suggestion that there was a public network competing with Popp's.