CN113074151A - Fluid pressure boost increment device - Google Patents
Fluid pressure boost increment device Download PDFInfo
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- CN113074151A CN113074151A CN202010012407.1A CN202010012407A CN113074151A CN 113074151 A CN113074151 A CN 113074151A CN 202010012407 A CN202010012407 A CN 202010012407A CN 113074151 A CN113074151 A CN 113074151A
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- piston
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B3/00—Intensifiers or fluid-pressure converters, e.g. pressure exchangers; Conveying pressure from one fluid system to another, without contact between the fluids
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- Engineering & Computer Science (AREA)
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- Fluid Mechanics (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Supply Devices, Intensifiers, Converters, And Telemotors (AREA)
Abstract
The fluid pressure-increasing increaser is characterized by that it has two concentric circles whose large and small diameters are different, volume and length are equal, and is a three-dimensional container device fixed by piston rod and respectively equipped with a piston, and the fluids of these two three-dimensional container devices are respectively closed, and are connected with two pistons by means of piston rod, and do not communicate with each other, when the fluid with a certain pressure flow rate is applied to right side or left side of small piston of small three-dimensional container, the small piston can be moved leftwards or rightwards, and the large piston can be driven to move leftwards or rightwards, and the fluid on the left side or right side large piston can produce identical pressure intensity and flow rate of fluid with large and small piston area times, and the fluid pressure-increasing increaser can provide proof for fluid pressure-increasing law increment Refrigeration, heating, hydraulic press and robot, all kinds of hydraulic rams, hydraulic pump provide hydraulic energy, various mechanical automation service.
Description
Technical Field
Fluid pressure increment devices, which are devices that increase the pressure of a liquid or gas during its operation, transfer, or conversion, are known as such; meanwhile, the proof is provided for the theoretical basis of the fluid pressurization increment law.
Background
I use this device to design "permanent hydraulic power machine" also known as "hydraulic engine", have announced invention and utility model patent to the country respectively, and the patent number is 98118926.1 and 99237384.0 respectively.
Disclosure of Invention
Pascal in 1653 proposed a well-known "Pascal's law":
"the pressure applied to any part of the sealed fluid is transmitted from the fluid to all directions according to the original size of the pressure. "
This law applies primarily to fluid (gas or liquid) mechanics. According to pascal's law, a certain pressure is exerted on the first piston (the small piston) in a liquid system, and the same pressure increase must be produced on the second piston (the large piston).
Such as: the area of the second piston is 10 times the area of the first piston and since the pressure equals the applied pressure divided by the force area, the force acting on the second piston will increase by 10 times the first piston while the pressures on the two piston surfaces remain equal.
P1 ═ P2, i.e., D1/F1 ═ D2/F2;
∴F2=F1·D2/D1。
in the formula: p1 and P2 refer to pressures on the large piston and the small piston;
f1 and F2 refer to the pressure on the large piston and the small piston;
d1 and D2 indicate the areas of the large and small pistons.
In the 'pascal' test, there is fluid communication and pressure between the small piston and the large piston, and the amount of fluid applied to the small piston is equal to the amount of fluid available to the large piston, so i recognize the 'pascal' as the 'fluid pressurization' law. According to the 'Pascal law', in a fluid system, a certain pressure is applied to a small piston, and the same pressure must be generated on a large piston, which is called as the pressurization of fluid; when a certain amount of fluid is applied to the small piston, the small piston is pushed to displace, the small piston and the large piston are fixed by the piston rod, and the large piston is inevitably driven to displace, because the ratio of the small cylinder to the large cylinder is 1: 10, ten times of the amount of the fluid applied to the small piston is inevitably obtained on the large piston, which is called as the increment of the fluid.
This is the fact that the pressure exerted on the large and small pistons is equal. The pressures of the large and small pistons applied to the device are also equal. Why? Because the two devices are identical in form, the different "Pascal's law" test devices have liquid transfer between the large and small pistons (soft transfer), while the two pistons of the fluid pressurization incremental device are piston rod transfer (hard transfer);
drawings
FIG. 1 is a schematic internal view of a fluid pressure boost increment device
The present invention will be described in detail with reference to the following embodiments illustrated in the accompanying drawings
Fluid pressurization increment devices, namely: two cylinders which are closed, connected and not communicated are oppositely and proportionally manufactured, and each cylinder is provided with a piston, the central points of the two pistons are fixedly connected by a piston rod and are closed in the two cylinders. As shown in the attached drawings, the small cylinder on the left and the large cylinder on the right, if: 1: 10; in the fluid of the device, a certain pressure is exerted on the small piston, and the same pressure must be generated on the large piston; meanwhile, the flow of the fluid, namely the flow of a certain fluid is applied to the small piston of the small cylinder, and the flow of the fluid 10 times of that of the large piston is generated.
P1 ═ P2, i.e., D1/F1 ═ D2/F2;
∴F2=F1·D2/D1。
p1 ═ P2, i.e., F1/S1 ═ F2/S2;
∴S2=S1·F2/F1。
the formula: s1 and S2 indicate hydraulic pressures of the large and small pistons.
It has two manifestations:
firstly, when fluid with certain pressure flow is applied to the left side of the front surface of the small piston 2 of the small cylinder 1, the small piston 2 is enabled to displace towards the right side, the piston rod 5 is connected with the two pistons to drive the large piston 4 of the large cylinder 3 to displace towards the right side, and the same pressure intensity and 10 times of fluid flow are necessarily generated on the large piston 4 facing the front surface;
secondly, when fluid with certain pressure flow is applied to the right side of the back surface of the small piston on the small cylinder 1, the small piston 2 is enabled to displace towards the left side, the piston rod 5 is connected with the two pistons to drive the large piston 4 of the large cylinder 3 to displace towards the left side, and the same pressure intensity and 10 times of fluid flow are generated on the back surface towards the large piston 4.
The fluid pressurization increment device provides proof for theoretical basis of fluid pressurization increment law, i think that
Fluid boost increment law, namely:
the pressure added to any one sealed fluid and the pressure transmitted to the other fluid are the same in the liquid or gas in two connected non-communicated, sealed and special containers, and are necessarily transmitted to all directions by the fluid according to the original size, and meanwhile, the flow rates of the two fluids are in direct proportion to the capacity of the containers.
In two cylinders with different diameters, which are made oppositely and proportionally, the fluids of the two cylinders are respectively sealed and are not communicated with the two pistons by piston rods, when fluid with certain pressure flow is applied to the right side or the left side of the small piston of the small cylinder, the small piston is enabled to move leftwards or rightwards, the large piston of the large cylinder is driven to move leftwards or rightwards, and the fluid on the large piston on the left side or the right side can generate the same pressure intensity and the flow of the fluid with the area multiple of the large piston and the small piston.
The constant hydraulic power machine, also known as hydraulic engine, is invented and manufactured based on the fluid pressure increment law as a theoretical basis.
The fluid pressurizing and increasing device is described in the attached drawings as a cylinder, and can be any three-dimensional container in production and manufacturing, as long as two pistons connected by a piston rod can interact in the three-dimensional container, and the fluid pressurizing and increasing device can be a cuboid, a cube or an ellipsoid and the like.
Two large and small three-dimensional solution vessel devices of the fluid pressurization increment device, for example, two small solution vessel devices or more than two small solution vessel devices are provided with one large solution vessel device; one small vessel device is provided with two large vessel devices, and the like;
therefore, an infinite number of mechanical devices are designed in the "hydraulic engine". For example, a small container device is provided with a large container device, which is similar to the English letter "T" and is called T-shaped series; two small solution vessel devices are provided with a large solution vessel device which is shaped like a reversed U-shaped device and is called a reversed U-shaped series; an M-shaped series of three small container devices provided with a large container device; an H-type series, TT-type series, etc. in which one small container device is equipped with two large container devices.
The fluid is divided into liquid and gas, and the fluid pressurization increment device is suitable for all the fluids; that is, a "hydraulic engine" accommodates all fluid materials. Three properties of matter, except that solids cannot flow, the fluid properties of any matter, are the fluid materials of a "hydraulic perpetual motion machine".
After the water is gasified by the steam engine, the pressure of the pressurized gas pushes the cylinder to work;
the internal combustion engine compresses gas and sprays fuel into the cylinder to increase the pressure of the gas to drive the cylinder to do work;
the hydraulic engine combines the advantages of the former two energy machines and utilizes the existing hydraulic body to drive the piston to do work.
The hydraulic engine replaces an internal combustion engine to become power for a power machine to support, the application range is expanded by the hydraulic energy of the liquid of the hydraulic engine, and various hydraulic machines can operate forever without mechanical energy or electric energy.
The hydraulic engine can directly generate electricity, refrigerate and warm, provides hydraulic energy for hydraulic machines, robots, various hydraulic jacks and hydraulic pumps, and provides various mechanical automation services.
Claims (1)
1. The fluid pressure boost increment device has two concentric circles with different diameters, volume and length, and a solid solution container device fixed by a piston rod and having a piston, and is characterized in that: the transmission of hydraulic force through the piston rod is shown in that when fluid with certain pressure flow is applied to the right side or the left side of the small piston of the small three-dimensional container, the small piston is enabled to move leftwards or rightwards to drive the large piston to move leftwards or rightwards, and the fluid on the large piston on the left side or the right side can generate the fluid with the same pressure intensity and the fluid flow of the area multiple of the large piston and the small piston.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202010012407.1A CN113074151A (en) | 2020-01-03 | 2020-01-03 | Fluid pressure boost increment device |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202010012407.1A CN113074151A (en) | 2020-01-03 | 2020-01-03 | Fluid pressure boost increment device |
Publications (1)
Publication Number | Publication Date |
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CN113074151A true CN113074151A (en) | 2021-07-06 |
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Family Applications (1)
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CN202010012407.1A Withdrawn CN113074151A (en) | 2020-01-03 | 2020-01-03 | Fluid pressure boost increment device |
Country Status (1)
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CN (1) | CN113074151A (en) |
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2020
- 2020-01-03 CN CN202010012407.1A patent/CN113074151A/en not_active Withdrawn
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WW01 | Invention patent application withdrawn after publication |
Application publication date: 20210706 |
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WW01 | Invention patent application withdrawn after publication |