DE10320894A1 - Air or fluid pumping system for driving hydraulic vehicles, has propulsion pumps, cock, container, pressure pumps, and mechanically or electrically driven piston pumps combined in piston pump engine to store energy for several applications - Google Patents

Abstract

The system comprises of propulsion pumps for use as feed pumps, a cock for changing air or fluid flow, a container for storing and delivering applied energy, pressure pumps for exerting direct pressure to air or fluid, and mechanically or electrically driven piston pumps which are all combined in a piston pump engine (1). The system can store energy for several applications.

Description

The The invention relates to combined systems equipped with pumps are. The pumps can mechanically driven by fuel engines or electrically

The usual Systems consume a lot of energy because the feed pumps, which are driven by crank-like drives on the crankshaft are wrongly arranged and because in the conventional systems the weight speed energy is not exploited.

such Systems are well known.

Around to be able to turn the pump one uses a crankshaft through one or more arms is rotatable. The arm is rotatably mounted on the crank of the crankshaft. By the pressure of the inflamed Fuel on the piston, which connects to the arm via one has mounted bolts, the crankshaft rotates and drives the Pump on.

To the For example, with two-stroke or four-stroke engines, the piston can Use force in one direction only. This gives us two points to overcome. Once after the ignition, when the piston is up and at the end of the stroke when the piston is below. As a result, we have about 30% –40% loss of power. Has the highest efficiency one if the piston moves half a stroke after ignition has moved down. At the moment we have the highest leverage because of the crank of the crankshaft is horizontally 90 ° to the piston. To the To be able to make better use of crank power, you have to use a piston pump Connect the arm to the crank of the crankshaft in a rotatable manner. How to get there we put a direct arm pressure from the motor onto the arm of the piston pumps. This means that less force is required to pump liquid or air can. This saves fuel on engines with diesel or petrol.

For example, for two-stroke engines, it works as follows:
The piston is at the top dead point. Now the fuel ignites and there is pressure on the piston. The piston moves down or horizontally in the cylinder, depending on how the cylinder is arranged. An arm is rotatably mounted on the piston via a pin. The arm is also rotatably connected to the crank of the crankshaft. The piston creates pressure on the arm. The arm presses on the crank of the crankshaft, so the crankshaft turns. Because the pump is non-rotatably connected to the crankshaft via a sleeve, belt, coupling or chain, the pump rotates. There are different types of pumps that are driven in this way. Since the pump is resisting, the crankshaft is braked and you have difficulty in overcoming the dead point after ignition because the piston can only exert the force in one direction. In this case, the highest efficiency is when the piston has reached half the stroke down and the crank of the crankshaft is 90 ° to the piston. If the piston is at the top or bottom, you have the lowest efficiency because the piston with the crank of the crankshaft is at 0 or 180 °.

It would be the same loss of power if the pumps were driven by crank-like drives. For example, like a bicycle; to start the crank you have to the 0 ° and 180 ° to the Overcome pedals.

With four-stroke:
It happens almost the same as with the two-stroke engine, only the piston turns the crankshaft twice around its axis after ignition before the next ignition takes place.

Around To reduce the loss of power, you have to increase the efficiency Change crankshaft.

And This is how you can achieve this: you do not have to exceed the liquid or air pressure Apply a pump that is firmly coupled to the crankshaft, but via one Piston located in a cylinder. At the end of the cylinder have to two ventilators must be attached (inlet and outlet). The inlet opens on suction and closes yourself under pressure. The spout opens presses and closes on the piston. The Wentiele can also be through a camshaft conclude and open, or control electronically. The pump piston is with one arm over the Bolt rotatably connected. The arm is with the crank of the crankshaft rotatably connected. The second arm must also be used with this crank Crankshaft have a rotatable connection, but so that they are do not interfere with each other when turning the crank. The second Arm has a rotatable connection with the piston of the engine. By the resulting connection almost occurs when the fuel is ignited a direct pressure on the liquid or the air over the piston of the resulting piston pump and you have a much higher efficiency. Than conventional ones Pumping systems.

In the case of four-stroke engines, the inlet and outlet valves have to be controlled via the camshaft or electronically so that after the fuel is ignited, the inlet valves of the pistons pump one cycle remains closed and the next three bars remain open. The discharge valve of the piston pump opens for one cycle after ignition and must remain closed for the next three cycles, which creates a flowing pressure of the liquid or air.

you can also produce more cylinder engines of this type.

Even more effective four-stroke engines can be made like this:
You create a housing in which you can install a plate. The plate must be rotatably mounted in the housing so that it can rock back and forth. At the ends of the plate that rock, you have to be able to attach three rotatably mounted arms so that two are directed upwards and one downwards. The downward arm must be rotatable between the two upward arms. A piston is rotatably arranged on each arm via a bolt. The pistons are each in a cylinder. The cylinders are firmly screwed to the housing. These must be attached so that the pistons in the cylinder do not tilt when the plate is rocked. The two cylinders in which the piston has a connection to the arms that point downwards must be equipped as a piston pump. Therefore, inlet and outlet valves must be installed, through which one can control the flow of air or liquid. The other four cylinders must be built over the other four arms with the pistons. So that they cannot tilt when the plate is rocked

About the four cylinders must be a cylinder head with camshaft and Wentielen be constructed.

Around To start and control the engine, you need a crankshaft install, so that a connection between the plate and the crank of the crankshaft takes place with an arm that at Turning the crankshaft seesaws the plate. Between the crank and Camshaft must be connected via gear, toothed belt or be a chain.

This engine works as follows:
There are two cylinders with pistons on both sides above the plate. The pistons have a connection with one side each via an arm which is rotatably mounted on the side of the plate and on the piston. When the fuel in the cylinder is ignited, when the piston is up and both valve bodies are closed, the piston presses on the arm. The arm presses on the rocking side of the plate. The side of the plate presses, by rocking, on the arm which is directed downwards and the arm in turn presses on the piston of the piston pump. The piston presses on the liquid or air in the cylinder of the piston pump.

The Piston, the second piston pump, is over the arm that with the other Side, the plate is pulled up and draws air or liquid over the inlet valve in the cylinder, the second piston pump. Through the resulting The seesaw, the plate, becomes the second upward arm, the attached to the same side of the plate, pulled down. The arm also pulls the plunger down as it rotates with it connected is. The piston pulls fuel mixture through the inlet valve (with diesel air) in the cylinder in which it is located. In this The inlet valve and the outlet must be open closed. The two arms on the other side of the plate are rotatably mounted, press their pistons up. Diagonal to the cylinder where the ignition took place has to the Wentiele be closed. Opposite the cylinder in which the ignition has taken place the outlet valve is on and the inlet valve is closed. By the correct process, the ignition of the Fuel and the correct control of the cylinder head parts, from the camshaft, we constantly rock the plate. By the rocking of the plate, the piston pumps continuously pump air and Liquid.

If the outlet of the resulting piston pump with a closed Container over one Hose or pipe connects, you can build up pressure in the container. The container can be made cylindrical and inside a well sealed, movable Install the piston to create two chambers. In one of the chambers a compression spring is installed. The liquid or air pressure must be connected to the chambers without compression spring. When printing in The chamber without the spring creates pressure on the movable one Piston of the container. The piston pushes the compression spring together, so you can store an applied energy. To be able to use the stored energy again one in the container Create a spout with a spout valve without a compression spring and install an inlet valve in the inlet of the same chamber. To be able to use the energy used, you have to use the spout of the container connect to the inlet of a drive pump and the outlet of the The drive pump must be connected to an expansion tank.

The expansion tank must be connected to the piston pump. When the piston pump is in operation, a flowing circuit is created. You could move any objects. One can also as Expansion tank use the second chamber of the tank (The chamber in which the compression spring is installed.) The spring and springless chambers must be equipped so that when the piston moves in the tank, the volume of the two chambers is equalized. If you move an object with a drive pump over one or more wheels, you can save the force velocity when the flow of air or liquid changes with a tap.

The Hahn must be equipped so that during normal operation from the Two-chamber container out of the chamber (without spring) through the outlet via the tap into the inlet the drive pump flows and from the outlet of the drive pump into the Inlet of the two-chamber container flows into the chamber (with spring). When the tap is switched, the flow must change so that the liquid from the two-chamber container out of the chamber (with spring) through the inlet via the tap into the inlet the drive pump flows and from the outlet of the drive pump into the Two-chamber container outlet into the chamber (without spring). Through these processes one can control the speed of force save and use again.

The Drive pump can be equipped so that at higher pressure in the system the volume of flow is at the same rotation can enlarge. So you can manufacture stepless or automatic drives.

For example:

you creates an oval shape casing and a round, thick disc that fits into the inner end of the oval case and the same strength as from the inside of the case is. The disc must be supported on both sides in the middle around the pane Grooves are created. Approximately to the center of the radius of the disc. In the bottom of the grooves of the Disk drills one or more holes for the compression springs, which are easy fit into the hole. The holes have to be so deep that the springs disappear into them when they are pressed together can. Deposits are made for the Grooves needed which are as wide as the disc and so large that they can disappear into the grooves. Then you need a plate that fits into the oval housing and the same thickness as the disc has. This plate must have a cutout that they semicircular and the pane fits into the cutout. The inside of the oval case must be so big that if you put the disc and the plate in, that the plate has so much space that you can move it from pane to pane End of the oval case can push away.

The Sides of the case and the plate need be so tight that no liquid or air can go through, but the plate still needs to be light in the housing can move back and forth.

The You have to over plate can control the springs mechanically or hydraulically.

The The disc must be mounted so that between the walls of the housing and the disc has no liquid or flow through air but the disc can still turn slightly about its axis.

you need an inlet and outlet in the housing, which are created there where the rounding of the disc is no longer in contact with the walls of the housing.

If you let liquid or air flow through the assembled pump, the following happens:
The solvent flows through the inlet into the pump. There is pressure on the inserts, since no flow can take place between the walls of the housing and the pane and the liquid or air flows through the space between the plate and the pane. The disk rotates on its own axis due to the pressure on the inserts. As soon as the inserts touch the walls of the housing, behind the outlet, they disappear into the grooves and as soon as the contact between the disc and the walls of the housing ends, they emerge again from the grooves, due to the pressure of the springs.

Because if we have several deposits in the disc, we achieve an alternating one Extending the insoles, and so we again achieve a constant turning the disk around its own axis. If you use a One could connect via the Wave different objects drive.

pump This can also be done via drive a shaft and fluid or pump air with the pump. This means that the pump can be or use a drive pump. If you have one with the pump Object drives and then reaches the flow through the pump changed you slow down the object and the pump starts liquid or to promote air. Could slow down superfluous, applied Gain and store energy and use it again. As before described. These drives can from inline skaters to complex machines.

With the inline skater, you have to create a cavity between the shoes and the inline skaters create, but so that there is a firm connection to the shoe and inline skater. With higher weight pressure on the shoe, the cavity between the shoe and the inline skater must be able to shrink or disappear completely and, conversely, the cavity must be able to enlarge with less weight. The cavity must be well sealed and equipped with an inlet and outlet valve. The outlet from the cavity is connected to the inlet of the pump that drives the wheel. In this case, the inline skater could only be driven with air. In order to be able to drive the inline skater with liquid, a compensation space would have to be created, which is connected to the outlet of the pump and the created cavity between the shoe and the inline skater. By shifting the weight from left to right or vice versa, the wheel or wheels are driven by the pump. This is how we achieve faster and more comfortable driving.

The same principle could to apply to scooters. You have to equip the scooter so that by the occurrence on the running board of a liquid pressure pump or convey air to the drive pump can and the drive pump drives the wheel or wheels.

you could equip the scooter as a step roller, i.e. you create on that Roller two movable running boards, each a pressure pump drive.

The Pressure pumps must be connected to each other in such a way that when alternating pressure on the pressure pumps a constant Flow pressure on the drive pump is present, so can alternate Shifting body weight simple and comfortable driving. What you do with Kick scooter could use you can also use it on a bike.

You could also drive the inline skaters, scooters and bicycles with a piston pump:
Various crank drive pumps can also be used on bicycles. The weight speed storage energy system could also be used for the bicycle.

This System is also good for Scooters and anything for all Vehicles with air or liquid drives are equipped.

1 a schematic side view in section a first embodiment of the system according to the invention of a combined single-cylinder piston pump motor,

2 in the same representation as 1 2 shows a second exemplary embodiment of the system according to the invention of a combined four-cylinder piston pump motor,

3 a schematic three-dimensional recording of a third embodiment of the system according to the invention of a combined four-cylinder piston pump rocker motor,

4 a schematic front view in section of a fourth embodiment of the system according to the invention of a combined V-four-cylinder piston pump rocker motor,

5 in the same representation as 1 a fifth embodiment of the system according to the invention of the weight speed storage energy system,

6 in a schematic rear view of a sixth embodiment of the system according to the invention of a piston pump system of a step roller according to 8th .

7 a schematic side view of a seventh embodiment of the system according to the invention of an air or liquid powered inline skater,

8th in the same representation as 7 6 shows a sixth exemplary embodiment of the system according to the invention of an air or liquid-powered step roller,

9 in the same representation as 7 an eighth embodiment of the system according to the invention of a piston pump driven bicycle,

10 in the same representation as 7 a ninth embodiment of the system according to the invention of an air or liquid-driven recumbent wheel, in which the drive pump is driven by cranks,

11 in the same representation as 7 10 shows a tenth exemplary embodiment of the system according to the invention of an air or liquid-driven motor scooter which is equipped with a single-cylinder piston pump motor, a drive pump and an energy storage system,

12 a schematic top view of an eleventh embodiment of the system according to the invention of a car drive which is equipped with a four-cylinder piston pump motor and a drive pump, in which the connection between the drive pump and the gearbox is established by means of a disengaging clutch,

13 in the same representation as 12 12 shows a twelfth exemplary embodiment of the system according to the invention of a second car drive, in which a fixed connection takes place between the drive pump and the transmission and a controllable valve is arranged between the drive pump and the piston pump motor,

14 in the same representation as 12 a thirteenth embodiment of the system according to the invention of a third car drive in which a drive pump is arranged on the front and rear axles. The car drive is like in 13 equipped with a control valve and a control valve

15 in the same representation as 12 a fourteenth embodiment of the system according to the invention of a fourth car drive, which is equipped with four drive pumps (one on each wheel) and three control valves are arranged on the lines,

16 in the same representation as 1 15 shows a fifteenth embodiment of the system according to the invention of a control valve,

17 in the same representation as 6 an embodiment of the system according to the invention of the drive of the bicycle 9 .

18 in the same representation as 6 1 shows an exemplary embodiment of the system according to the invention of a motor scooter which is equipped with a single induction piston pump motor and energy storage system,

19 in the same representation as 12 an embodiment of the system of the invention 18 .

20 in the same representation as 1 16 shows a sixteenth exemplary embodiment of the system according to the invention of a liquid-powered excavator,

21 in the same representation as 1 17 shows a seventeenth exemplary embodiment of the system according to the invention of an air or liquid-powered forklift equipped with an energy storage system,

Same or corresponding components are in the figures of the drawings provided with the same reference numerals.

In 1 is a single-cylinder piston pump motor 1 represented with an engine block 2 in which there are two cylinders 3 . 4 arranged on a line.

In the cylinder 3 is a piston 5 movably arranged, which is equipped as an engine piston.

The piston 5 has a swivel connection to the arm 7 about a bolt 9 , The other side of the arm 7 is on the crank 11 the crankshaft 12 rotatably mounted.

The crankshaft 12 is in the engine block 2 with two bearings 13a and 13b rotatably mounted.

On the crank 11 is still an arm 8th with one end pivoted. The other end of the arm 8th has a rotatable connection with the piston 6 (it must be equipped with a piston pump as a piston) via a bolt 10 ,

The piston 6 is in the cylinder 4 arranged movably.

The cylinder 4 is with an outlet valve 15 and an inlet valve 16 equipped to control the flow of air or liquid. The valves are controlled 15 and 16 through a camshaft 25 which is a tight connection with the gear 26 Has. The gear 26 is non-rotatable with the double gear 23 over the strap 27 connected.

From the outside of the engine block 2 on the crankshaft 12 is a flywheel 17 firmly arranged, with which you can turn the crankshaft 12 can turn. Over the cylinder 3 is a cylinder head 18 firmly built.

The cylinder head 18 is with outlet valve 19 and inlet valve 20 and with a camshaft 21 fitted. At one end of the camshaft 21 is a gear 22 firmly arranged. The gear 22 is with the double gear 23 over the strap 24 non-rotatably connected. The double gear 23 is with crankshaft 12 firmly connected.

The cylinder must be used for two-stroke engines 3 be equipped so that after the ignition of the fuel in the cylinder 3 the pistons at the first stroke 5 , draws in fresh fuel mixture by moving downwards and at the second stroke, by moving upwards into the cylinder 3 freed from the rest of the burned fuel and compressed the fresh fuel.

Out 1 it can be seen that the composition of these parts achieves the following.

After ignition of the compressed fuel in the cylinder 3 there is pressure on the piston 5 , This presses over the bolt 9 on the arm 7 , The arm 7 has a rotatable connection on the crank with the other end 11 the crankshaft 12 with the arm 8th , The arm 8th presses over the pivoted bolt 10 on the piston 6 , The piston 6 presses on the air or liquid in the cylinder 4 and flows through the outlet valve 15 , As soon as the crankshaft 12 the first bar is completed.

By the swing of the flywheel 17 that with the crankshaft 12 the crankshaft rotates 12 further.

And the resulting connection of the components creates suction, through the piston 6 as it is pulled up.

The resulting suction flows through the inlet valve 16 Air or liquid in the cylinder 4 , And through the piston 5 that moves upward, the fuel mixture in the cylinder 3 compressed.

As soon as the crankshaft 12 turns again by 180 °, the second cycle is complete and there is another ignition. Such a sequence is only possible with two-stroke engines.

The cylinder head is used in four-stroke engines 18 used.

When the fuel is ignited in the cylinder 3 are the valves 19 and 20 closed. The crankshaft 12 turns the gear 23 , Through a rotatable connection over the belt 24 with the gear 22 , the gear turns too 22 , The gear 22 has a fixed connection to the camshaft 21 it also turns it.

As soon as the crankshaft 12 the outlet valve is turned by one cycle (180 °) 20 through the camshaft 21 but opened the inlet valve 19 remains closed. In this way, the burned fuel is released from the cylinder at the next stroke 3 , through the piston 5 , away.

Before the third cycle takes place, the outlet valve 19 closed and the inlet valve 20 open. This is how a fresh fuel mixture is placed in cylinders 3 sucked in and at the fourth stroke the valves have to 19 and 20 be closed so that the sucked-in mixture is pressed together.

The valves 15 and 16 are from camshaft 25 controlled.

The camshaft 25 is through the gear 26 turned. The gear 26 is from the double gear 23 due to the non-rotatable connection of the belt 27 driven. Sodas after the ignition the outlet valve 15 one cycle remains open and the next three cycles is closed and the inlet valve 16 three bars after the ignition is open and the last bar is closed. (You can also use the valves 15 and 16 electronically control.) So the energy expenditure is used more effectively because the air or liquid from the cylinder 4 is only pumped when the highest efficiency takes place.

In 2 is a four-cylinder pump engine 14 with an engine block 2 shown. In the engine block 2 are four cylinders 3a . 3b . 3c . 3d and four cylinders 4a . 4b . 4c . 4d recorded. The cylinders 3a , b, c, d are in a row across the cylinders 4a , b, c, d arranged.

The four cylinders 3a , b, c, d and four cylinders 4a , b, c, d, are as in the 1 permitted and also the same connection between the components (piston 5a , b, c, d bolts 9a , b, c, d arm 7a , b, c, d crank 11a , b, c, d arm 8a , b, c, d bolts 10a , b, c, d pistons 6a , b, c, d) takes place as in 1 , The crankshaft 12 is with four cranks 11a , b, c, d, and in order on the crankshaft 12 arranged. The crank 11a is in line with the crank 11c the crank 11b and 11d are also in line with the cranks 11a and 11c arranged. The crankshaft 12 is in engine block 2 stored five times (warehouse 13 ) between the cranks 11a , b, c, d.

The camshafts 21 and 25 are over the strap 28 , which has a non-rotatable connection with the gears 22 . 26 and 29 has driven.

The gear 29 is outside the block 2 with the crankshaft 12 firmly connected. The cylinders 3a , b, c, d and the cylinders 4a , b, c, d and the other components have the same function as in 1 ,

The This is how the resulting four-cylinder engine works.

When the fuel is ignited in the cylinder 3a are the engine valves 19a . 20a . 19b . 20c . 19d . 24d closed and the valves 20b and 19c open. After this cycle, the ignition takes place in the cylinder 3d instead, next in 3c and then in 3b ,

The valves 19a , b, c, d and 20a , b, c, d are on the camshaft 21 controlled so that the fuel mixture in the cylinder 3a , b, c, d can be compressed, the ignition power is used, the burned fuel mixture can be removed from the cylinders and fresh air can be sucked in.

The valves 15a , b, c, d, are through the camshaft 25 after the ignition, opened for one cycle and three closed. The valves 16a , b, c, d remain open for three bars and closed for one bar.

In 3 is a four-cylinder luffing piston pump motor 32 with an engine block 2 by putting a plate 30 which is rotatably arranged and by two bearings 31a and 31b through the plate 30 can rock.

On the sides of the plate 30 the seesaws are six arms 7a , b, c, d, 8a . 8b arranged. The poor 7a . 7b and 8a are on one side of the plate 30 on a wave 33 rotatably arranged. The poor 7a and 7b are directed upwards. The arm 8a is between the poor 7a and 7b on the wave 33a directed downwards and rotatably arranged.

On the other side of the plate 30 are the arms 7c and 7d on the wave 33b Rotatable upwards and between the arms 7c and 7d is the arm 8b arranged rotatable downwards.

On the arms 7a , b, c, d are pistons 5a , b, c, d over a bolt 9a , b, c, d rotatably connected. The pistons 5a , b, c, d are in the cylinders 3a , b, c, d movably arranged. About the cylinders 3a , b, c, d is a cylinder head 18 firmly with the engine block 2 screwed. The cylinder head 18 is with two camshafts 21a . 21b equipped, through which the four inlet valves 20a , b, c, d and with four outlet valves 19a , b, c, d controls.

The camshaft 21a has a fixed connection to the gear 22a ,

The camshaft 21b is fixed with the gear 22b connected. The gears 22a and 22b have a non-rotatable connection with the gear 23 over the strap 24 , The gear 23 has a fixed connection to the crankshaft 12 that are in the engine block 2 rotatably mounted. On the crank 11 the crankshaft 12 is an arm 36 rotatably arranged with a rocking side of the plate 30 is rotatably connected. The arm 8a is with the piston 6a over the bolt 10a rotatably connected. The arm 8b is with the piston 6b over the bolt 10b rotatably connected. The piston 6a is in the piston pump cylinder 4a arranged movably. The piston 6b is in the piston pump cylinder 4b arranged movably. The piston pump cylinder 4a and 4b are with the outlet valves 15a and 15b and the inlet valves 16a and 16b and connections 37 and 36 fitted.

Out 3 it can be seen that the following has been achieved by the composition of these components.

When the fuel is ignited in the cylinder 3a are the valves 19a . 20a . 20b . 19c . 19d , and 20d closed. During this, the valves are 19b and 20c open. The piston moves due to the expansion of the ignited fuel 5a in the cylinder 3a downward. Through the previously described connection, the side of the plate that connects to the piston bounces 5a has down. The other side moves by rocking the plate 30 up (previously described connection). The pistons move 5b and 6a down and the pistons 5c . 5d and 6b up. Once the plate 30 the crankshaft 12 180 ° over the arm 35 the first bar has been completed. The cylinder becomes in time 3c the burned fuel mixture is removed in the cylinder 3b fresh sucked in and in cylinder 3d it is pressed together. By turning the crankshaft 12 , (previously described connection) the camshafts also rotate 21a and 21b , The valves 19a . 20b . 20d and 19d the valves remain closed 19b and 20c close and the valves 20a and 19c are opened. There is an ignition in the cylinder 3d instead of. The connection described above creates pressure on the other side of the plate 30 , Once the crankshaft 12 makes another turn by 180 °, the second bar ends. The pistons 5c . 5d and 6b are driven down again and the pistons 5a . 5b and 6a are driven up. Now the valves are 19b . 20b . 20c . 19c . 19d and 20a to and the valves 19a and 20d are open. Now the ignition takes place in the cylinder 3b instead of. And the pressure on the sides of the plate 30 has changed again.

At the end of this cycle, the crankshaft has turned 180 ° again. The pistons 5a . 5b and 6a are down and the pistons 5c . 5d and 6b above. The valves 20a . 19a . 20c . 19c . 19d and 20b are closed and the valves 19b and 20b are opened. Now takes place in the cylinder 3c the ignition instead.

The pressure on the plate 30 has shifted back to the other side. As soon as the last stroke is finished, takes place in the cylinder 3a another ignition instead. By alternating the pressure on the plate 30 , we achieve a constant rocking of the plate 30 , The cylinders 4a and 4b are as piston pumps with inlet valves 16a and 16b and outlet valves 15a and 15b fitted. The inlet valves 16a and 16b open on suction and close on pressure. The outlet valves 15a and 15b close on suction and open on pressure. Because of the back and forth movements in the cylinders 4a and 4b The piston 6a and 6b , a flow through the valves is achieved 15a and 15b , Through the connection 36 and a filling of the cylinders 4a and 4b , Through the connection 37 about the valves 16a and 16d ,

In 4 is a second embodiment of the four-cylinder luffing piston pump motor according to the invention which differs from the embodiment according to 3 essentially by the inclination of the cylinders 3a . 3b and 4a to the right and the cylinder 3c . 3d and 4b to the left is a (V) four-cylinder luffing piston pump motor in which the plate 30 is arched upwards.

The components have been given connections and functions such as 3 ,

In 5 is shown a first embodiment of the weight speed storage energy system according to the invention, that with two piston pumps 38 and 39 , Container 40 , Rooster 41 , Drive pump 42 , electrically driven piston pump 43 and real 44 between which the following connection takes place.

The piston pumps 38 and 39 have a connection via the hose 45 and are each with pistons 6 , Inlet valve 16 and outlet valve 15 fitted. The connections with the valves 16 have a connection through the hoses 46 . 48 . 52 . 49 with the connection 57 of the container 40 connected. The connections with the valves 15 are over the hoses 47 . 56 . 51 . 50 with the connection 58 of the container 40 connected.

In the container 40 is a movable piston 59 arranged. To one side of the cob 59 is a feather 60 built-in. On the other side of the piston 59 at the end of the container 40 is a snap 80 arranged.

The connection 61 of the container 40 has a connection to the connector 62 of the rooster 41 through the hose 67 ,

And the connection 63 of the container 40 is with the connection 64 of the rooster 41 over the hose 68 connected. The connection 65 of the rooster 41 is over the hose 71 with the connection 69 the drive pump 42 connected.

The hose 72 connects the connector 66 of the rooster 41 with the connection 70 the drive pump 42 ,

The rooster 41 is with a closing element 73 and lever 74 equipped that have a firm connection with each other.

The electrically driven piston pump 43 consists of a cylinder 75 , At both ends of the cylinder 75 are two valves each 15 and 16 built-in. In the cylinder 75 is a piston 76 arranged movably.

From the outside of the cylinder 75 are two windings 78 and 79 arranged.

The winding 78 is wrapped from the center to the left and the winding 79 from the center to the right. The ends of the windings 78 and 79 are in the real 44 connected. The real 44 is connected to a power supplier (not shown).

The drive pump 42 consists of an oval housing 81 ,

In one disc 82 is arranged on one side of the housing. The disc 82 is through two camps 83 in the housing 81 stored. There are grooves on the disc 84 eingefreßt. In the bottom of the grooves 84 are holes 85 drilled in which the compression springs 86 are classified. In the grooves 84 are deposits 87 classified.

The plate 88 is on the other side of the case 81 classified.

The plate 88 has a connection with the piston cylinder 90 over the arm 89 of the piston cylinder 90 , In the piston cylinder 90 is a duck feather 92 built in, the pressure on the piston 91 can exercise.

On the piston 91 is a rope 93 attached, the outside of the piston cylinder 90 goes. The piston cylinder is with a connection 94 equipped with a connection to the connector 69 the piston pump 42 through the hose 95 Has.

Out 5 it can be seen that the following has been achieved by connecting these components.

By alternating the magnetic field of the windings 78 and 79 , by controlling the real 44 reciprocation of the piston is achieved 76 in the cylinder 75 , This allows air or liquid to flow through the valves 15 (through the connection previously described) into the side of the container 40 where the piston 59 with the snap 80 Is provided. And from the side of the container 40 with the feather 60 air or liquid flows through the valves 16 in the cylinder 75 into the electric piston pump 43 ,

The same flow sequence follows when the piston pumps are inserted 38 and 39 that connect to each other via the hose 45 have that for balancing the vacuum in the piston pumps 38 and 39 provides. By building up the pressure of the pumps 38 . 39 and 43 the air or liquid flows out of the container 40 through the connection 63 , Tube 68 , Connection 64 , the rooster 41 , Connection 65 , Tube 71 , Connection 69 into the drive pump 42 , flows between the pane 82 and the plate 88 and hits the insert 87 that blocks the flow. By pressing the insert 87 the disc turns 82 with the wave 96 through storage (warehouse 83 ) through the wave 96 you can drive a wheel, not shown. By a higher re stand of the wheel, not shown, there is a higher pressure in the drive pump 42 , Through the connection between the connections 69 and 94 the pressure on the piston also increases 91 which is in the cylinder 90 emotional. So is the feather 92 pressed together. This is through the arm 89 the plate 88 from the disc 82 pulled away. There is a greater flow through the drive pump 42 between the disc 82 and the plate 88 , The spring presses to better utilize the flow 86 the deposit 87 further out of the groove 84 and blocks the flow of air or liquid. As soon as the resistance of the wheel decreases, the pressure decreases and the spring 92 presses the plate 88 over the piston 91 and arm 98 back to the window 82 ran.

The plate 88 you can also go through the rope 93 from the disc 82 move away.

Once the deposits 87 the spout 70 have reached, they disappear into the grooves 84 , by pressure on the walls of the case 81 , But if they have the enema 69 reach the deposits 87 through the feathers 86 from the grooves 84 rausgedrückt.

The further flow of air or liquid flows through the connection 70 the drive pump 42 in the port 66 through the tap 41 , Connection 62 , Tube 67 , Connection 61 , in the side of the container 40 , The further course of the river has already been described.

To store the weight speed energy, you have to simultaneously (mechanically, hydraulically or electrically) the lever 74 of the rooster 41 turn 90 ° and the piston 59 of the container 40 from the snap 80 to solve. This changes the flow of air or liquid through the tap 41 , By rotating the wheel, not shown, through the connection described above, the disc rotates 82 and conveys air or liquid through the connection 70 , Tube 72 connection 66 , Rooster 41 connection 64 , Tube 68 , Connection 63 in the container 40 , Because the valves 15 The pumps 43 . 38 and 39 closing the pressure creates pressure on the piston 59 and because the air or liquid from the container 40 from the side where the spring 60 is removed, the air or liquid is taken through the connector 61 , Tube 67 , Connection 62 , Rooster 41 , Connection 65 , Tube 71 , Connection 69 by pump 42 in the container 40 through the connection 63 pumped. This causes the piston to move 59 in the container 40 to the connections 61 and 57 and tensions the spring 60 , If you look at the tap 41 switches back again, the flow through the tap changes 41 , By the pressure of the spring 60 on the piston 59 the piston moves 59 back into place.

So the drive pump 42 driven again. If the piston 59 the stored energy has been reused.

The snap 80 fulfills the function that with running pumps 38 . 39 or 43 The piston 59 in the handicapped 40 can't move.

How to manage the pressure of the pumps 38 . 39 or 43 directly on.

By the function we described was the weight velocity energy once saved and reused.

In 6 is the drive of the step roller 110 shown.

In 7 is a first embodiment of the air or liquid powered inline skater 96 shown out of a shoe 97 which is a fixed movable up and down connection with the plate 98 , through eight rails 99 Has. Four of the rails are on the left and four are on the right.

Between the plate 98 and the shoe 97 is a pressure pump 100 arranged and two compression springs 101 , one in front and one in back. On the other side (under) the plate 98 are by two struts each 102 four wheels 103 rotatably arranged and an expansion tank 105 befestig. On the struts 102 are drive pumps 42 befestig.

The drive pumps 42 have a non-rotatable connection with the wheels 103 , The pressure pump 100 is with the enema 69 the drive pump 42 with the hose 106 connected. The outlet 70 the drive pump 42 is with the expansion tank 105 over the hose 107 connected.

The expansion tank 105 has three connections 108 with the pressure pump 100 , There is an inlet valve in each of the connections 16 that closes on pressure and opens on suction.

And there is a connection between the pressure pump and the expansion tank, with a pressure tap 109 Is provided.

Out 7 is evident when you put a weight pressure on the shoe 97 exercises, the shoe moves 97 on the rails 99 to the plate 98 , There is pressure on the pressure pump 100 , The liquid flows through the hose 106 , Drive pump 42 , Tube 107 in the expansion tank 105 , The pumps rotate due to the flow 42 and the wheels 103 are driven. When the shoe is relieved 97 remove the compression spring 101 the shoe 97 from the plate 98 , It arises a vacuum in the pressure pump 100 , The inlet valves open due to the suction 16 , The pressure pump fills with the liquid.

Constant change ensures fast and comfortable driving. The pressure tap opens when braking 109 by a rope (not shown) or a brake lever. In the case of air-powered inline skaters, the expansion tank is 105 superfluous.

In 8th is a step roller 110 with a frame 111 shown out of a step plate 114 there is a connection to the storage facility 115 through the pipe 116 Has. At the other end of the step plate is a wheel 103 that with a drive pump 42 is arranged.

In the storage facility 115 is a fork 112 rotatably arranged by a handlebar 113 is steerable. On the fork 112 is still a bike 103 arranged. On the pipe 116 is a running board from both sides 117 rotatably mounted. Between every footboard 117 and the step plate 114 are each a piston pump 120 arranged that connect through the hoses 118 and 119 with the drive pumps 42 Has.

From the 8th can be seen when you step on the running boards 117 alternately occurs through the piston pumps 120 into the drive pump 42 over the hose 119 Air or liquid pumped and over the hose 118 removed again. The drive pump rotates through the circuit 42 and drives the wheel 103 on.

You can also use the front wheel with a drive pump 42 equip.

In 9 is a bike 121 shown, in which the piston pumps 120 are driven by cranks. On the frame 122 is a piston pump on both sides 120 rotatably arranged. On the other hand, the piston pumps 120 a rotatable connection through the cranks 123 on the bottom bracket assembly 124 are rotatably attached. On the cranks 123 is a pedal 200 attached. On the wheels 103 are drive pumps 42 arranged that connect to the piston pumps 120 through the hoses 118 and 119 to have. The function is the same as with the step roller 110 , There is only one difference. The piston pumps 120 are through cranks 123 driven.

In 10 is a recumbent bike 125 shown, in which the drive pump 42 by cranking 126 are driven. The recumbent bike 125 is with the weight speed storage energy system 127 (please refer 5 ) as part of 111 fitted.

In 11 is a single cylinder piston pump motor scooter 130 which is equipped with the weight speed energy storage system.

The piston pump motor 131 is at the back of the frame 132 under the seat 133 arranged. On the left side of the piston pump motor 131 is the drive pump 42 fixed through which the wheel 103 is driven. On the right side is the energy storage container 40 firmly arranged, on which an expansion tank 134 is attached. How the engine and the system work is already in advance 5 have been described.

In the case of single-cylinder pump engines, the expansion tank is 134 necessary for the volume in the system with the piston pump motor running 130 to be able to compensate.

In 12 is a first car drive 136 shown, which is equipped with four-cylinder piston pump engine 14/32/34.

The drive pump is on the four-cylinder piston pump engine 14/32/34 42 arranged. The drive pump 42 is with the gear 135 screwed. The rotatable connection between the shafts of the drive pump 42 and the shaft of the transmission 135 is the same as in conventional vehicles, with a detachable coupling 201 ,

In 13 is a second car drive 136 shown, in which the drive pump 42 and the transmission 135 are screwed together. The shafts from the drive pump 42 and the transmission 135 have a firm connection with each other. The drive pump 42 and the piston pump motor 14/32/34 are connected by two hoses 138 and 139 , The hoses 138 and 139 are together through a rooster 155 connected, through which one connects the hoses 138 and 139 can cancel and restore.

Out 13 it can be seen that with the piston pump motor 14/32/34 running, the approach can be made by slowly closing the tap 155 can control.

In 14 is a third car drive 136 shown in the case of the front axle 140 and rear axle 141 one drive pump each 42 is attached which can be controlled automatically or mechanically. The drive pumps 42 are through the hoses 138 and 139 connected to the piston pump motor 14/32/34. Between the hoses 138 and 139 there is the same connection as in 13 , Before connecting 69 the drive pump 42 that on the front axle 140 is arranged is a control valve 142 built-in, through which you have a higher flow through the front or rear An powered pump 42 can avoid.

Out 14 it can be seen that the car drive 136 is equipped with front-wheel drive and rear-wheel drive. When spinning the wheels 103 controls the control valve 142 the flow to the drive pumps 42 and so that they have wheels 103 can't go crazy.

In 15 is a fourth car drive 136 shown with all four wheels 103 of own drive pumps 42 are driven. There are three control valves in the drive system 142 classified. The first control valve 142 is arranged on the division of the left and right side of the lines. The other two control valves 142 are before dividing the lines on the front and rear drive pumps 42 are connected.

Out 15 it can be seen that the car is powered by four drive pumps and that by the arrangement of the control valves 142 spinning the wheels 103 avoided.

In 16 is a control valve 142 shown that from a housing 145 consists. In the housing 145 are an enema 143 and two spouts 144 created. Inside the case 145 a cross-shaped valve is installed in such a way that with higher flow through one of the outlets 144 the cruciform valve 146 the spout 144 closes.

In 17 is the drive of the bike 121 shown.

In 18 and 19 is the drive of the scooter 130 shown.

In 20 is an excavator 180 shown, which is equipped with a piston pump motor 14/32/34. The excavator 180 can be equipped with the same drives as the 12 / 13 / 14 / 15 ,

The piston pump motor 14/32/34 has a connection to the control block 181 through the hose 182 that goes directly to the control block 181 is connected and a connection through the hose 183 , which also connects to the expansion tank 105 Has.

Out 20 it can be seen that you have an excavator 180 or can equip a tractor (not shown) with the piston pump motor.

In 21 is a forklift 185 shown with several containers 40 is equipped that have a connection with each other. Once on the side of the container 40 (without feather 60 ) and once on the side of the container 40 (with feather 60 ). To the air or liquid in the side (without spring 60 ) to pump and from the side (with spring 60 ) is an electrically driven pump 186 built-in. The pump 186 has a connection with one of the containers through the hoses 187 and 188 , The hose 187 is on the side of the container 40 (with feather 60 ) connected and the hose 188 is with the side of the container 40 (without feather 60 ) connected. The forklift gets over the wheel 103 that from the pump 42 is driven.

In order to be able to drive the forklift correctly, there is a control valve 198 between the tubes 68 and 71 built-in. To avoid accidents that can be caused by the damaged system, there are two safety taps 199 built-in. The safety taps 199 can be opened at the push of a button (not shown). A safety tap 199 connects the hoses 67 and 71 , so we avoid driving the pump again 42 of the wheels 103 , The second safety tap 199 connects the hoses 182 and 183 , so no liquid can enter the control block 181 flow. This way we avoid an accident. Around the control block 181 to protect, cuts a pressure reducer 202 the hose 182 ,

Claims (30)

The systems with drive pumps (which can be used as a drive pump or feed pump), tap (in which the flow can change), container (which stores and releases the applied energy), pressure pumps, piston pumps, piston pump motors or electrically driven piston pumps, ( through which one can exert energy directly on the air or liquid). The systems can be used to equip simple inline skaters to complex machines. The system is characterized by the fact that the composition of the components creates an energy-saving system that can be used in many different ways. System is characterized according to claim 1, the single-cylinder piston pump engine, that in the engine block 2 the cylinder 3 over the cylinder 4 arranged on a line that in the cylinder 3 The piston 5 arranged with the arm 7 over the bolt 9 is rotatably connected to the other side of the arm 7 a rotatable connection with the arm 8th on the crank 11 has that other side of the arm 8th with piston 6 that is in the cylinder 4 by the bolt 10 is rotatably connected. System is characterized according to claim 2 of the single-cylinder piston pump motor in that the cylinder 4 with valves 15 and 16 Is provided, that of the camshaft 25 be controlled that the camshaft 25 a rotatable connection with the crankshaft 12 through the gears 26 . 23 and straps 27 has that in two-stroke engines by the pressure of the piston 6 the valves on the air or liquid 15 but open valve 16 closes. The valve opens when there is suction 16 and the valve 15 closes. System is characterized according to claim 3 of the four-cylinder piston pump motor in that the cylinder 3a . 3b . 3c . 3d , about the cylinders 4a . 4b . 4c . 4d , are arranged in a row and that the crankshaft 12 between each cylinder is that the crankshaft 12 a non-rotatable connection through the gears 23 . 26 and the strap 24 with the camshaft 25 and the valves 15 and 16 are controlled so that when the fuel is ignited in the cylinder 3a . 3b . 3c . 3d who have favourited Valves 15 in the cylinders 4a . 4b . 4c . 4d one bar open and three bars to stay and that the valves 16 three bars open and only one bar to stay and only in the cylinder in which the ignition takes place. System according to claim 4 of the four-cylinder piston pump rocker motor, characterized in that in the engine block 2 a plate 30 through two camps 31 and 32 is centered so that the plate 30 seesaws that on the seesawing sides from one side to the shaft 33 two arms 7a and 7b are directed upwards and between the two arms 8a is rotatably arranged facing down that on the other side on the shaft 33 the plate 30 the poor 7c and 7d directed upwards and between arm 8b , which is directed downwards, that are rotatably arranged on the arms 7a . 7b . 7c . 7d piston 5a . 5b . 5c . 5d through a bolt 9a . 9b . 9c . 9d that the pistons are rotatably attached 5a . 5b . 5c . 5d in the cylinder 3a . 3b . 3c . 3d are movably arranged that the arms 8a and 8b with the pistons 6a and 6b through the bolts 10a and 10b that the pistons are rotatably arranged 6a and 6b in the cylinder 4a and 4b Are arranged movably that the cylinder 4a and 4b with the valves 15a . 15b and 16a and 16b are equipped that the connections 37 and 36 on the cylinders 4a and 4b are connected. System is characterized according to claim 5 of the four-cylinder piston pump rocker motor in that the cylinder head 18 with the valves 20a . 20b . 20c . 20d and 19a . 19b . 19c and 19d is equipped by camshaft 21a and 21b are controlled by a rotatable connection with the crankshaft 12 about the gears 23 . 22a . 22b and straps 24 has that cylinder head 18 about the cylinders 3a . 3b . 3c . 3d firmly with the engine block 2 is screwed. System is characterized according to claim 6 of the four-cylinder piston pump rocker motor in that the crankshaft 34 in the engine block 2 is rotatably mounted, and that the crankshaft 12 on the crank 11 a rotatable connection with the side of the plate 30 through the arm 34 Has. System is characterized according to claim 7 of the (V) four-cylinder piston pump rocker motor in that the cylinders 3a . 3b and 4a to the right and the cylinders 3e . 3d and 4b to the left so the one (V) that arises over the cylinder 3a and 3b a cylinder head 18 is arranged and over the cylinder 3c and 3d also a cylinder head 18 is arranged that the plate 30 is arched. System according to claim 8 of the weight speed energy storage system is characterized in that the piston pumps 38 . 39 and the electrically driven piston pump 43 from the connection with the valves 16 connect to the connector 57 of the container 40 through the hoses 46 . 48 . 52 and 49 have and the connections with the valve 15 are with the connection 58 of the container 40 through the hoses 47 . 56 . 51 and 50 connected. That the connection 63 of the container 40 a connection to the connector during normal operation 69 the drive pump 42 through the hose 68 , Connection 64 through the tap 41 , Connection 65 , Tube 71 has that connection 70 the drive pump 42 with the connection 61 of the container 40 through the hose 72 , Connection 66 , through the tap 41 , Connection 62 and hose 67 Has. System is characterized according to claim 9 of the weight speed energy storage system, that when switching the tap 41 the flow through the tap 41 is changed that in the case the drive pump 42 is used as a feed pump and that by the pump 42 from one side of the piston 59 Air or liquid in the container 40 is pumped and from the other side of the piston 59 from the container 40 taken. System according to claim 10, characterized in that the container 40 with a feather 60 , a piston 59 and a snap 80 Is provided. System is characterized according to claim 11, characterized in that the electric feed pump 43 from the outside of the cylinder 75 with two windings 78 and 79 is equipped, and inside with a piston 76 is equipped that the windings 78 and 79 by reals 44 to be controlled. System according to claim 12, characterized in that the flow of air or liquid through the drive pump 42 can control this is with the plate 88 by the piston cylinder 90 hydraulically or mechanically in the drive pump 42 is movable back and forth, possible. In addition, it is characterized by the deposits 87 from the spring 86 from the grooves 84 be pushed out. System is characterized according to claim 13, that the inline skater is powered by air or liquid. System according to claim 14, characterized in that the shoe 97 a movable connection with the plate 98 through the rails 99 that between the plate 98 and the shoe 97 Has. It is also characterized in that a pressure pump 100 is arranged, and that with the pressure pump 100 the wheels 103 through the drive pumps 42 are driven. That the liquid from the pressure pump 100 through the drive pumps 42 in the expansion tank 105 flows and through the connections 108 back to the pressure pump 100 , through the feathers 101 who the shoe 97 from the plate 98 Pushing away. System according to claim 15, characterized in that the scooter 110 is powered by air or liquid. System is characterized according to claim 16, characterized in that by straying occurrence on the running boards 117 drive the piston pumps 120 the drive pumps 42 on, so they become the wheels 103 set in motion. System according to claim 17, characterized in that the bicycle 121 with piston pumps 120 is equipped by cranks 123 are driven. System is characterized according to claim 18, that the recumbent 125 the drive pump 42 by cranking 126 that is driven in the frame 122 a weight speed energy storage system is arranged. System according to claim 19, characterized in that the scooter 130 with single-cylinder piston pump motor 1 and weight speed energy storage system. System according to claim 20, characterized in that on one side of the single-cylinder piston pump motor 1 the drive pump 42 is arranged and on the other side is the energy storage container 40 arranged that to the energy storage container 40 a volume expansion tank 134 is arranged. System according to claim 21, characterized in that the car drive 136 with a four-cylinder piston pump engine 14 . 32 or 34 is equipped that on the engine 14 . 32 or 34 the drive pump 42 is arranged that the rotatable connection between the shafts of the drive pumps 42 and gears 135 through the clutch 201 takes place. System is characterized according to claim 22, that in the car drive 136 the drive pump 42 on the gearbox 135 is arranged, and that through the arranged tap 137 the start is controllable. System according to claim 23, characterized in that the car drive 136 the drive pumps 42 , one on the front axle 140 and one on the rear axle 141 , are arranged, and that by the arrangement of the control valve 142 spinning the wheels 103 is avoidable. System according to claim 24, characterized in that the car drive 136 with four drive pumps 42 is equipped with a direct connection to the wheels 103 have, and that through the arrangement of the three control valves 142 spinning the wheels 103 is avoided. System according to claim 25, characterized in that the control valve 142 from a housing 145 consists of an enema 143 and two spouts 144 are created, and that in the housing 145 a cross valve 146 is arranged, which closes the outlet through which a higher flow has arisen. System according to claim 26, characterized in that an excavator 180 or an implement tractor with a piston pump motor 14 . 32 or 34 Is provided. System according to claim 27, characterized in that a forklift 185 driven by air or liquid. System according to claim 28, characterized in that the forklift 185 with one or more energy storage containers 40 is equipped and that the air or liquid from an electric or motorized pump 186 from the side (with spring 60 ) of the container 40 in the side (without spring 60 ) of the container 40 is pumped. System according to claim 29, characterized in that the forklift 185 with safety taps 199 Is provided.