DE109509C - - Google Patents

Description

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IMPERIAL

PATENT OFFICE.

The object of the invention relates to an explosion engine, in which the suddenly acting force of the explosion acts on a small piston, which the work force transfers to a larger piston. Both pistons move in floating in the water Cylinders, so that the buoyancy comes into effect when the piston is rising, whereupon a body submerged under water and filled with air strives up again with it a pressure which is equal to the weight of the amount of water it displaces.

The object of the invention is illustrated on the drawings, and is:

Fig. Ι a section through the cylinder,
Fig. 2 shows a plan of the same,
3 shows a plan of the bottom of the gas cylinder provided with inlet and outlet openings,

Fig. 4 is a cross section of the same,
Fig. 5 shows the outline of the small basin,
6 shows the bottom of the same in cross section, FIG. 7 shows a cross section of the slide and
Fig. 8 is a section through the cylinder with the arrangement of an exhaust for the cylinder D. In a container A resting on masonry or the like (see Fig. 1), which is separated into two parts by a partition B , there are two cylinders C (I and II), which are guided by rollers on the rails attached to the container and are provided with diagonal traverses α to which the bearings c receiving the journals of the forked connecting rods b are attached.

So that the liquid is at the same level in both parts of the container A , an opening O is made in the partition B. The cylinders C are open at the top and have a bottom at the bottom to which the working cylinders D are attached. These are in turn surrounded by containers E , which are firmly connected to the bottom of container A. The working cylinders D have inflow and outflow openings m and n in their bottoms, which can be opened and closed by a slide G that is movable on the bottoms F of the container E. In addition, the bottoms F of the container E have openings to which the pipelines, such as the supply line for the gasometer, water drain and exhaust pipe, can be attached. The slides G are moved back and forth on the inner surface of the container E by eccentrics H wedged on the crankshaft and a linkage provided with an angle lever J and a release device. The slide G have a mortise d into which a pin e attached to the slide of the working cylinder D engages and, as a result of the eccentric movement, forces the slide K of the working cylinder to follow the movement. In addition, a spring / attached to the bottom of the working cylinder D is attached to the slide K on the right-hand side, through which the engagement of the pin e in the pin hole d and thus also the compression of the spring is canceled during the upward movement of the cylinder D. , the slide K is pushed to the left by the effort of the spring to expand, thus closing the inflow and outflow openings

causes. A contact between the bottom of the basin E and that of the cylinder D is established through the pin e at the same time through a piece of copper wire ο located inside the same.

During the downward movement of the cylinder D and the cylinder C firmly connected to it, the bevel of the pin e comes to the left edge of the mortise d, whereby the slide K is pushed slightly to the right and the contact is thereby canceled. If the slide K is now firmly seated on the sealing rings k of the slide G , the corresponding openings of the slide exactly coincide and the slide is pushed to the right by the eccentric movement until the openings in both bases are completely free, so that through the Feed line gas can flow in and the burned gas can flow out through the exhaust lines. The slide then retracts, the inflow and outflow openings are then closed, and the pin touches both contacts, with sparks jumping between the platinum tips ρ and q , so that the gas contained in the cylinder D explodes, as does the one in the moving piston cylinder D L, which is guided by a piston rod M in a stuffing box of the bottom of the cylinder C, and the piston ΛΓ fixedly connected with the piston rod of the cylinder C is lifted. As a result of the upward movement of the piston N in connection with the piston L, which the latter forces the water located above it in the cylinder D to exit through the openings P above, air spaces are created in the cylinders D and C, whereby the entire body of the cylinder specifically becomes lighter and there is a lift.

The piston rod N respectively. the pistons L and N will continue to move upwards until the piston N hits against the diagonal crossbars α of the cylinder C. Here, the above-toothed piston rod M is held or held by a lever g which is always pushed to the left by the counterweight f and engages under a tooth of the piston rod M. a lowering of the same as a result of its own weight and the piston L and N that are firmly connected to it prevented. The locking of the piston rod lasts until the counterbalanced lever h hits the bracket i attached to the top of the container A when the cylinder C goes up, whereby the lever h is moved downwards and the rod g to the right, so that the locking the piston rod is released and the two pistons N and L can sink down until the latter arrives at the reinforcement attached to the bottom of cylinder D (see cylinder II).

So that the burnt and still slightly tensioned gases contained in the cylinders D do not oppose the downward movement of the pistons JV and L , a device is arranged on the cylinders D (FIG. 8) which enables the burnt gases to escape. This consists of levers respectively. Rods ss, which act on the lever h , so that the movement of the lever h is transmitted to the slide K by means of an angle lever s ¹ or the like and by means of suitable intermediate links. When the lever h hits the bracket i, the slide K will move, through the openings of which the burnt gases exit. Should water penetrate the cylinder D when the slide is moved, this will run back into the exhaust line when the cylinder is placed on the rings k. The exhaust from cylinder D could also be reached in another way, perhaps by opening an exhaust valve at the bottom of the cylinder, or by opening a pipe into the bottom F , which pipe opens under the valve at the bottom of the cylinder D is attached and pushes itself watertight through the floor F when the cylinder D rises and falls, which then leads the exhaust pipe to a suitable location.

Apparently the freshly supplied gases, which enter the cylinder D through the inlet openings η , would have to look for a way out through the exhaust m , which is open at the same time, and escape. However, since the slide G actuated by the angle lever J only closes the openings of the cylinder D with the inlet opening for a very brief moment. connects to the exhaust, the burnt gases compressed in the small space under the piston L only allow the incoming fresh gases to enter when they have been withdrawn through the exhaust; The exhaust can no longer be used as a vent for the fresh gas that is pushing in, because by then it will have long been closed again.

In order to completely exclude the possibility of the gases entering through the exhaust pipe being withdrawn again, it can be achieved by an asymmetrical arrangement of the openings m and η that the inlet and outlet pipes respectively. Outlet openings of the gases not at the same time with the associated inlet or outlet openings. Outlet pipes are connected, but that one after the other, namely first the outlet m for the burned gases is opened and only then, after this has closed, also the

Claims (3)

Inlet opening η allows the influx of fresh gases. Following the downward movement of the pistons, the air spaces above them are filled with water, so that the entire cylinder body is moved downwards by the downward driving force of the pistons and by the weight of the water that collects over the pistons, while the other part of the cylinder moves downwards The opposite process takes place. As soon as the working cylinder D arrives again on the sealing rings k attached for the inflow and outflow openings to the bottom of the basin E by means of the eccentric movable slide G, the pin e attached to the slide k engages with its beveled surface in the something that has already been caused by the eccentric The mortise d of the basin slide G is moved to the right, and the process begins anew. Because of the large and small cylinders C and D, which are movable in a water container, only a single explosion is necessary, namely for the upward movement of the pistons and the associated upward movement of the cylinders, since they move downward by themselves. The movement is transmitted from a connecting rod b, which is supported in the form of a fork on the diagonal cross-members of the cylinder C, to a crankshaft cranked at an angle of 180 °. With small machines, the force of gravity of the mass pushing downwards can be used as the driving force. It is not necessary to always use two pairs of cylinders. However, when only one pair of cylinders is used, the inconvenience arises that mechanical means must be used to help over the dead points when starting. So that the pistons are opposed to as little resistance as possible during the upward movement, they can be allowed to run out in the shape of a wedge towards the top, so that they easily cut through the water. The bearings of the crankshaft are attached to the container A and its partition B by brackets and stiffeners. Patent claims: 1. Gas engine, characterized by cylinders (C and D ) which are movable in water tanks (A and E) and are firmly connected to each other, each with two pistons (L and N), which, in the upward movement caused by an explosion, the cylinder above them ( C and D) displace the water from these, creating air spaces behind the piston, so that the whole cylinder body is lifted as a result of the buoyancy, which sinks downwards due to its own weight together with the weight of the amount of water that accumulates over the same when the piston descends. 2. A gas engine according to claim i, characterized by a spring-loaded slide (K) which is movable in the bottom of the explosion cylinder (D) and controls the inflow and outflow openings (m and n) of the explosion cylinder, and below a beveled, of a copper wire (o ) has penetrated pin (e) which engages in a corresponding opening (d) of a slide (G) moved back and forth by the machine, whereby the slide (K) from the slide (G), which controls the inflow and outflow line , is taken. 3. A gas engine according to claim 1, characterized in that after the end of the stroke of the pistons (L and N) the piston rod (M) provided with teeth is attached to the cylinder body and is always pushed to the left by a counterweight (f), under one tooth of the piston rod cross-bar (g) is determined, is completed by the stroke of the Cylinderkörpers and a stöfst with the rod (g) connected to the lever (h) against a stop (i), the (g) to move the rod to the right, whereby the piston rod (M) is released and a sinking of the same as well as the associated cylinder piston (L and N) and then the entire cylinder body can take place. For this purpose 2 sheets of drawings.