Geyzer's process technology

Abstract

Liquid forced out from volume by pressure created by burned gas from fuel.

Description

BACKGROUND OF THE INVENTION

[0001] Geyser's process occurs when liquid is forced out from volume by pressure between liquid's steam (or gas) and the liquid. Also this process occurs in nature.

[0002] Gas fuel and liquid fuel burned equipment has now coefficient efficiency from 20% to 25%, because the other of the energy eventually is lost to the atmosphere.

[0003] Nature's geysers confirm that liquid can be used to perform useful work.

[0004] Liquid can perform useful work, then can be collected, reheated and used again with the same purpose.

[0005] For this process expected coefficient efficiency can be from 40% to 50% and possibly more.

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] Example of the technological scheme is shown on FIG. 1.

[0007] Two engines take turn to burn fuel.

[0008] Pistons 2 and 3 take turn to transfer their energy in accordance to pistons 13 and 14. Pistons' rods have on their surface gear racks.

[0009] These gear racks connect through gears 10 and 11.

[0010] Pistons 13 and 14 force out liquid from cylinders 15.

[0011] This liquid cools engine's cylinders 1 and then perform useful work inside turbine units 43.

[0012] Burned gas perform useful work inside gas' turbines 45.

[0013] Both gas and liquid perform useful work and then liquid collected reheated and used again for the same purpose for this reason coefficient efficiency will rise to 40% or 50% and possibly more.

REFRENCE NUMERALS

[0014] Engine's cylinder—1

[0015] Piston—2

[0016] Piston—3

[0017] Cover—4

[0018] Inlet valve—5

[0019] Exhaust valve—6

[0020] Exhaust channel—7

[0021] Piston rod—8

[0022] Piston rod—9

[0023] Gear—10

[0024] Gear—11

[0025] Clutch—12

[0026] Piston—13

[0027] Piston—14

[0028] Cylinder—15

[0029] Piston rod—16

[0030] Piston rod—17

[0031] Tip—18

[0032] Tip—19

[0033] Cover—20

[0034] Piston rod—21

[0035] Cylinder—22

[0036] Cover—23

[0037] Piston—24

[0038] Piston—25

[0039] Tube—26

[0040] Tube—27

[0041] Tube—28

[0042] Tube—29

[0043] Tube—30

[0044] Tube—31

[0045] Tube—32

[0046] Tube—33

[0047] Tube—34

[0048] Tube—35

[0049] Tube—36

[0050] Tube—37

[0051] Tube—38

[0052] Collector—39

[0053] Tube—40

[0054] Tube—41

[0055] Jacket—42

[0056] Turbine unit—43

[0057] Clutch—44

[0058] Turbine unit—45

[0059] Shaft—46

[0060] Tube—47

BRIEF SUMMERY OF THE INVENTION

[0061] Liquid forces out from volume by pressure created by burned gas from fuel.

[0062] This force out liquid and burned gas rotate turbines, that assembled on one or more shafts.

[0063] After liquid performs useful work liquid will be collected, reheated and used again for the same purpose.

DETAILED DESCRIPTION OF THE DRAWINGS

[0064] Scheme FIG. 1 consist from two similar left and right blocks.

[0065] Liquid distribution valve, collector 39, gears 10 and 11 common for two blocks.

[0066] Tubes with the liquid shown by thin lines.

[0067] Tubes with burned gas shown by dash lines.

[0068] Small cross lines shown on the gears 10; 11 and on the pistons 13;14.

[0069] Conditionally these cross lines mean, that gears tighten with its axes and pistons 13 and 14 tighten with its pistons' rods 16 and 17.

[0070] When three tubes connect together at the one place, this place shown by one dot.

[0071] When one tube located under another tube, then this place shown by arc intersect straight line.

[0072] All units tighten on the frame. This frame is not shown on FIG. 1.

[0073] When inlet valve 5 is in lower position and piston 2 is in upper position, then fuel will be forced inside cylinder 1 through inlet channel.

[0074] Inlet channel is not shown on FIG. 1

[0075] Fuel begins to burn by plugs spark or by high temperature created inside cylinder 1.

[0076] This event is shown on the left block.

[0077] When exhaust valve 6 and piston 3 are in lower position, then burned gas will flow from cylinder 1 through exhaust channel 7, then through jacket 42 and then through turbine unit 45.

[0078] This event is shown on the right block.

[0079] Outside units burned gas flow inside tubes shown by dash lines and arrows.

[0080] Inside jacket 42 burned gas transfer heat to the liquid's flow inside turbine unit 43, because turbine unit 43 is located inside jacket 42.

[0081] From jacket 42 burned gas flows in accordance to tube 44; inside turbine unit 45; by tube 47.

[0082] From tube 47 burned gas can be used to warm up cylinders 15 and collector 39.

[0083] Jackets are not shown around cylinders 15 and collector 39 on the FIG. 1.

[0084] Turbines' shafts 46 can be connected with units, that perform useful work.

[0085] Gear racks and gears connection guarantee proper position of the pistons for left and right blocks.

[0086] Piston 2 has rod 8. Piston 3 has rod 9.

[0087] Pistons' rods 8 and 9 have gear racks on its surface.

[0088] These gear racks connected by gears 10 and 11.

[0089] Rod 16 tighten with tip 18.

[0090] Rod 17 tighten with tip 19.

[0091] Tips 18 and 19 have cone surfaces.

[0092] When tips 18 and 19 move up and down, they move rod 21 by its cone surfaces to the left or to the right.

[0093] Rod 21 move pistons inside liquid distribution valve.

[0094] This movement distribute liquid from collector 39 and cylinders 15; and also between cylinders 15 and the hallows inside engines' cylinders 1.

[0095] Distribution valve consist from: pistons 24; 25; piston rod 21; cylinder 22; and two covers 23.

[0096] From collector 39 liquid flows by tube 25 between right piston 24 and piston 25; and then inside tube 26.

[0097] From tube 26 liquids' flows divided between tubes 27 and 28; then liquid flow under piston 13 and above piston 14.

[0098] Above piston 13 liquid force out to tube 30 and below piston 14 liquid force out to tube 31.

[0099] From tubes 30 and 31 two flows will unite inside tube 29.

[0100] From tube 29 liquid flows between piston 25 and left piston 24.

[0101] Then liquid flows inside tubes 32, 33, two tubes 34, then liquid flows inside hallows of engines' cylinders 1.

[0102] From the hollows inside engine cylinders 1 liquid flows inside turbine unit 43; then liquid flows inside tubes 41 to the collector 39.

[0103] Liquid can be leaked to the spaces between covers 23 and pistons 24. This liquid can return to the collector 39 by tubes 36.

[0104] When pistons 13 and 14 will change its position, then liquids' flows will change direction inside tubes with referrals numerals from 26 to 31.

[0105] Scheme FIG. 1 presented only units and parts, that needed to understand how described process must worked and don't presented all needed systems, units and parts.

[0106] Order can be changed, in which liquid flows between units.

[0107] Also type of used equipment can be changed, but principle described in the claim must remain.

Claims

1. Liquid can be forced out from volume by pressure between gas and liquid.

2. This liquid can be used to perform useful work, then this liquid can be collected, reheated and used again for the same purpose.