السبت، 15 يوليو، 2017

Increasing Efficiency of Air-Conditioners

87 percent of the climate change pollutants found in air-conditioners
Air-conditioner uses%25electricity in offices, malls, airport, factory, hotel, house
USPTO patented pump system

Increasing Efficiency of Air-Conditioners
Efficiency doesn’t require a global treaty. It does, however, call for new regulatory policies on manufacturing standards and labeling.
It matters, researchers say, because cooling has a direct relationship with the building of coal-fired power plants to meet peak demand. If more air-conditioners are humming in more homes and offices, then more capacity will be required to meet the demand. So 1.6 billion new air-conditioners by 2050 means thousands of new power plants will have to come on line to support them.
The Lawrence Berkeley study argues that even a 30 percent improvement in efficiency could avoid the peak load equivalent of about 1,500 power plants by 2030.
But most countries have a lot of work to do in modernizing their energy policies.
“Many countries haven’t updated their standards in a while,” said Nihar Shah, a senior scientific engineering associate at the Lawrence Berkeley laboratory and lead author of the study, which examined the markets of 19 nations. “In most of these countries there’s an opportunity to do both things together.”
The countries driving the bulk of demand for air-conditioning — China, Brazil, India, and Indonesia — have energy efficiency improvement policies like labels and incentive programs. But improvements to China’s policies could have sweeping gains, because it is the key exporter to countries primarily in Southeast Asia, where demand is growing. India’s Ministry of Power is working to develop a program for bulk purchases of superefficient air-conditioners, which may include refrigerant alternatives to HFCs.
In India alone, air-conditioner purchases have risen sharply over the past decade. Many believe India will outpace China, which grew from 5 percent market penetration in the mid-1990s to more than 140 percent today, meaning millions of families have more than one air conditioner.
Durwood Zaelke, president of the Institute for Governance and Sustainable Development, a nonprofit based in Washington that commissioned the lab study, said efficiency was not getting enough attention.
“We don’t pay attention to the fact that demand for air-conditioning is growing, just as the world is becoming more populated and richer, and will grow at a much greater rate as the world gets warmer,” he said.

الخميس، 29 يونيو، 2017

prototype JPS




How to make a prototype


To make a prototype we only need $2000
 We buy;
1 water pump
7  one way valves
2  tanks each 10 litters in size
1 sensor
1 oil separator
1 air-conditioner.. second hand with its compressor not functioning



We need 7  one way valves
BCV check valve, for fluorinated refrigerants

061N3026


We need one sensor
FLT93S





We need one water pump

PEDROLLO PQ3000 pump with peripheral impeller - 3HP / 2,2KW / 380V
Stock code = PE_41PQT947A5
PQ 3000 - Pump with peripheral impeller The hydraulic characteristics of this pump, coupled with its compactness, make it suitable for use in the industrial applications. Suitable for use with clean water and liquids that are not chemically aggressive towards the materials from which the pump is made. The pump should be installed in an enclosed environment, or at least sheltered from inclement weather. Pumped liquid: clean water Use: industrial Type: surface Range: peripherals Performance range • Flow rate up to 50 l/min (3 m³/h) • Head up to 180 m Application limits • Manometric suction lift up to 8 m • Liquid temperature between -10 °C and +90 °C • Ambient temperature between -10 °C and +40 °C • Max. working pressure 18 bar • Continuous service S1
Brand: PEDROLLO
Code: 41PQT947A5
Frequency Electric: 50HZ




We need 4 Solenoid Valves
We need 4 Solenoid Valves –Parker Brand -  Size :½ "  , Part No 444494W






We need 2 steel bottles



We need 1 Oil separator






         
We need 1 second hand air-conditioner




We remove the compressor we weld all the parts above as shown in the diagram below.
This prototype just to prove the cooling capability of JPS then we can make very nice looking air-conditioners for the market where the two bottles and the pump and every thing so compact it will sit in the compressor place so easily.






this explanation was for the prototype but when making an air-conditioner for market we can put the double headed impeller pump in a casing with its solenoid valves in a metal compartment just like we do now for the compressor, so as if we remove the compressor and we replace it with the double headed impeller pump. then we connect it with the two steel bottles then we have one single unit the pump and the two bottles as one unit to be connected to the rest of the air-conditioner system.


  













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السبت، 17 يونيو، 2017

BSW Power Output Calculations

Blinking Sail windmill

US patents 7780416 &  8702393 

Power output calculation, when the radius of the frame is 40m and height 60m

20.6MW

US patent: 21MW. First time in history sail windmill let wind pass through but extract all its energy
https://www.youtube.com/watch?v=XhY9GxsQ2i0&feature=youtu.be

Short video

Boeing microluttice Makes the most powerful windmill ENDs oil coal era

Long video

Boeing’s revolutionary microluttice lighter than Dandelion

https://www.youtube.com/watch?v=yDA0V3L8f0U#t=520

US patent 7780416 blinking sail windmill gentle wind 

 

US patent 7780416 blinking sail windmill fast wind

Industrial design windmill Boeing’s revolutionary microluttice


“BSW Power Output Calculations”
Wind speed 10m/s

When we consider a BSW with 30m x 30m frame fixed at the end of a 60m arm. Then the Total Power = (26.9MW). 0
Using the universally accepted and used formula to calculate power output by wind turbines:
Power output (P) = 0.5 x air density at sea level (1.23) x swept area x wind velocity cubed.
P = 0.5 × 1.23 × 2RH × Vwhere:
P = Power output
0.5= The efficiency rating assigned to the majority of wind turbines
R= In a classic wind turbine, with three horizontally spinning rotors, R is the radius of the spinning rotor
In the case of the BSW, however, R is the radius of the active frame denoting the distance between the frame’s vertical column and the BSW’s Central Post.
H: In a classic wind turbine, with three horizontally spinning rotors, H is thelength of the spinning rotor
In the case of the BSW, however, H is the height of the vertical column of the active frame. 
V= Wind velocity (cubed) in meters per seconds.
But before I outline the power output calculations in some detail, and in order to understand and appreciate how these calculations are achieved, it is absolutely critical to highlight an important feature of the structure of the BSW’s frame which plays an important role how power is generated and calculated:
“A BSW may have 4 frames (or 5 or 6) designed to spin and block the wind to generate electricity. Think of the BSW frame as an Excel sheet consisting of multiple columns. The columns will be juxta positioned next to each other; a series of columns, as if they are stitched together. BSWs of different sizes will have different number of columns. The larger the BSW the larger number of columns.

The frame of a 10m x10m BSW has 5 columns, each 10m long; a frame of a 20m x 20m has 10 columns, each 20m long, while a 30m x 30m frame will have 15 columns, each 30m long.

Just like an Excel Sheet with multiple cells, each column has multiple number of component units called Double Sided Units. A Double Sided Units (DSU) is 2m wide and 1m long. Different size BSWs will have different number of DSUs. For example, a BSW with 10m x 10m frame will have 200 DSU; a 20m x 20m frame will have 800 DSU while a 30m x 40m will have 2400 DSU”.

Having briefly explained the general structure of the BSW’s frame which is directly responsible for generating power, it is crucial to explain an important feature of the frame of the BSW that has an enormous and direct impact on how much power it generates; a hasty use of the aforementioned power output formula will give us a low, Conservative Power Outputfigure. On the other hand, taking into consideration the unique structure of the BSW’s frame and how the columns are arranged in series, the same BSW will yield much higher power output figure or the Actual Power Output.

By applying the same method we previously applied on example A, here is a summary of all the critical information needed to reach the two sets of power output figures, a low conservative figure and a high actual figure representing the total power generated by all columns combined:

1.     A BSW with 30m x 30m frame has 15 columns lettered A, B, C, D, E. F, G, H, I, J, k, L, M, N, and O.
2.     Each column is 2m wide and 30m long
3.     Starting from the far end of the frame and moving toward the Central Post of the BSW, column A is the farthest from the Central Pole and O is the closest; the radius values of the 15 columns, from column A to column O, are as follow: 60m, 58m, 56m, 54m, 52m, 50m, 48m, 46m, 44m, 42m, 40m,  38m,  36m,  34m and  30m.

Conservative Power output:
In a conservative power output calculation, the radius of the frame is 60m and its height 30m.
P = 0.5 x 1.23 x (2 x 30 x 60) x 103 = 2214KW = 2.2MW

Actual Power Output:
In an actual power output calculation, we shall calculate the power output of each column, a total of 15 columns. And because each column produces different amount of power corresponding directly to the value of its radius, we shall calculate all 15 power output values, add them together and reach the actual power produced by a BSW with 30m x 30m frame:

Power produced by column A = 0.5 x 1.23 x (2 x 60 x 30) x 103 = 2250KW 
Power produced by column B = 0.5 x 1.23 x (2 x 58 x 30) x 103 = 2175KW 
Power produced by column C = 0.5 x 1.23 x (2 x 56 x 30) x 103 = 2100KW 
Power produced by column D = 0.5 x 1.23 x (2 x 54 x 30) x 103 = 2025KW 
Power produced by column E = 0.5 x 1.23 x (2 x 52 x 30) x 103 = 1950KW 
Power produced by column F = 0.5 x 1.23 x (2 x 50 x 30 x 103 = 1875KW 
Power produced by column G = 0.5 x 1.23 x (2 x 48 x 30) x 103 = 1800KW 
Power produced by column H = 0.5 x 1.23 x (2 x 46 x 30) x 103 = 1725KW 
Power produced by column I = 0.5 x 1.23 x (2 x 44 x 30) x 103 = 1650KW 
Power produced by column J = 0.5 x 1.23 x (2 x 42 x 30) x 103 = 1575KW 
Power produced by column K = 0.5 x 1.23 x (2 x 40 x 30) x 103 = 1500KW 
Power produced by column L = 0.5 x 1.23 x (2 x 38 x 30) x 103 = 1425KW
Power produced by column M = 0.5 x 1.23 x (2 x 36 x 30) x 103 = 1296KW 
Power produced by column N = 0.5 x 1.23 x (2 x 34 x 30) x 103 = 1275KW 
Power produced by column O = 0.5 x 1.23 x (2 x 32 x 30) x 103 = 1200KW 
Power produced by column P = 0.5 x 1.23 x (2 x 30 x 30 x 103 = 1125KW 

Total Power = 26946KW (26.9MW). o




“BSW Power Output Calculations”
The detailed calculations below will shed ample light on the most crucial question concerning the BSW; how much power the BSW will generate.
Using the universally accepted and used formula to calculate power output by wind turbines:
Power output (P) = 0.5 x air density at sea level (1.23) x swept area x wind velocity cubed.
P = 0.5 × 1.23 × 2RH × Vwhere:
P = Power output
0.5= The efficiency rating assigned to the majority of wind turbines
R= In a classic wind turbine, with three horizontally spinning rotors, R is the radius of the spinning rotor
In the case of the BSW, however, R is the radius of the active frame denoting the distance between the frame’s vertical column and the BSW’s Central Post.
H: In a classic wind turbine, with three horizontally spinning rotors, H is thelength of the spinning rotor
In the case of the BSW, however, H is the height of the vertical column of the active frame. 
V= Wind velocity (cubed) in meters per seconds.
But before I outline the power output calculations in some detail, and in order to understand and appreciate how these calculations are achieved, it is absolutely critical to highlight an important feature of the structure of the BSW’s frame which plays an important role how power is generated and calculated:
“A BSW may have 2 frames (or 3 or 4 or more) designed to spin and block the wind to generate electricity. Think of the BSW frame as an Excel sheet consisting of multiple columns. The columns will be juxta positioned next to each other; a series of columns, as if they are stitched together. BSWs of different sizes will have different number of columns. The larger the BSW the larger number of columns.

The frame of a 10m x10m BSW has 5 columns, each 10m long; a frame of a 20m x 20m has 10 columns, each 20m long, while a 30m x 40m frame will have 20 columns, each 30m long.

Just like an Excel Sheet with multiple cells, each column has multiple number of component units called Double Sided Units. A Double Sided Units (DSU) is 2m wide and 1m long. Different size BSWs will have different number of DSUs. For example, a BSW with 10m x 10m frame will have 200 DSU; a 20m x 20m frame will have 800 DSU while a 30m x 40m will have 2400 DSU”.

Having briefly explained the general structure of the BSW’s frame which is directly responsible for generating power, it is crucial to explain an important feature of the frame of the BSW that has an enormous and direct impact on how much power it generates; a hasty use of the aforementioned power output formula will give us a low, Conservative Power Outputfigure. On the other hand, taking into consideration the unique structure of the BSW’s frame and how the columns are arranged in series, the same BSW will yield much higher power output figure or the Actual Power Output. For example, we can show that:
(i)                A BSW with 10m x 10m frame can generate 123KW or 367KW
(ii)              A BSW with 20m x 20m frame can generate 492KW or 2.6 MW
(iii)            A BSW with 30m x 40m frame can generate 1476kw or 10MW.
But how can we explain this huge discrepancy in power output by the same BSW?

As you can notice that the power discrepancy in a BSW with 10m x 10m frame is huge; (123KW and 367KW). In using the power output formula to calculate the lower figure (123KW) we simply aggregate the power produced by all five columns i.e. we do not consider each column separately nor do we assign a unique and corresponding radius (R) to each individual column. Instead we simply use one general figure as a radius for all columns and apply it to the entire frame despite the obvious fact that each column has a unique and different radius of its own and produces its own specific amount of power which is directly corresponding to its unique radius.

In the 2RH section of the power output calculation formula quoted above we simply use 10m to denote the radius (R) of the entire frame, although each of the five columns has different radius of its own which is its distance from the Central Post of the BSW.

 In light of the above explanation, now I would like to show you how we can get two sets of different power output figures to reflect the above-mentioned observation.
To drive the above point home and make it absolutely crystal clear I shall use three examples to show you how we can get a low conservative figure and an actual high power output figure for the same BSW.

A: So, let us begin with a BSW with 10m x 10m frame.
Our calculations can show that this BSW can generate either 123KW or 367KW. But how?

This frame has 5 columns, each column is 2m wide and 10m long.
Despite the fact that the frame has 5 columns we shall assume that all 5 columns will have the same radius of 10m and they will collectively generate only 123KW. We can simplify the matter even further by assigning letters to the 5 columns, A, B, C, D and E. All five lettered columns will have the same radius value of 10m.In the conservative method we do not calculate the power generated separately by each individual column. Instead the frame will be considered as one integral frame with 10m radius and 10m height. Thus:

Conservative Power Output
P = 0.5 x 1.23 x 2RH x V3
P = 0.5 x 1.23 x (2 x 10 x 10) x 103 = 123KW

Now, let us calculate the actual power generated by the same BSW with 5 columns. The power output figure will be a lot higher. And the reason is that each of the 5 columns, A, B, C, D and E generate its own unique amount of power corresponding directly to the value of its radius.

Putting in a nutshell as a general theory: “All factors (values) of all 5 columns being equal, the value of their radius will determine the amount of energy they produce; the bigger the radius the larger the power output”

 So how do we do that?

Let us remember that each of the 5 lettered columns has its own specific radius, reflecting its corresponding distance from the Central Post of the BSW.
Remember the Columns are positioned in series.

So, starting from the far end of the frame and moving towards the Central Post: Column A is 10m away from the central Post of the BSW i.e. its radius is 10m
Column B is 8m away from the Central Post of the BSW i.e. its radius is 8m
Column C is 6m away from the Central Post of the BSW i.e. its radius is 6m
Column D is 4m away from the Central Post of the BSW i.e. its radius is 4m
Column E is 2m away from the Central Post of the BSW i.e. its radius is 2m

Now we are in a position to calculate the power generated by each column, depending on its corresponding radius.

Actual Power Output
Power produced by column A = 0.5 x 1.23 x (2 x 10 x 10 x 103 = 123 KW 
Power produced by column B = 0.5 x 1.23 x (2 x 8 x 10) x 103 = 98 KW 
Power produced by column C = 0.5 x 1.23 x (2 x 6 x 10) x 103 = 73 KW 
Power produced by column D = 0.5 x 1.23 x (2 x 4 x 10) x 103 = 49 KW 
Power produced by column E = 0.5 x 1.23 x (2 x 2 x 10) x 103 = 24 KW 
Total power output = 367kw

By adding all the power generated by all 5 columns the actual (total) power generated by the same BSW is 3,67KW, three times the value of theconservative figure of 123KW

B: In our second example we shall consider a BSW with 20m x 20m frame.
The calculations below will show that this BSW can generate as conservative power 492KW (almost 0.5 MW) or as actual power 2,675KW (more than 2.6MW).

By applying the same method we previously applied on example A, here is a summary of all the critical information needed to reach the two sets of power output figures, a low conservative figure and a high actual figure representing the total power generated by all columns combined:

1.     A BSW with 20m x 20m frame has 10 columns lettered A, B, C, D, E. F, G, H, I and J.
2.     Each column is 2m wide and 20m long
3.     Starting from the far end of the frame and moving toward the Central Post of the BSW, column A is the farthest from the Central Pole and J is the closest; the radius values of the ten columns, from column A to column J, are as follow: 20m, 18m, 16m, 14m, 12m, 10m, 8m, 6m, 4m and 2m.

Conservative Power output:
In a conservative power output calculation, the radius of the frame is 20m and its height 20m.
P = 0.5 x 1.23 x (2 x 20 x 20) x 103 = 492KW

Actual Power Output:
In an actual power output calculation, we shall calculate the power output of each column, a total of 10 columns. And because each column produces different amount of power corresponding directly to the value of its radius, we shall calculate all ten power output values, add them together and reach the actual power produced by a BSW with 20m x 20m frame:

Power produced by column A = 0.5 x 1.23 x (2 x 20 x 20) x 103 = 492KW 
Power produced by column B = 0.5 x 1.23 x (2 x 18 x 20) x 103 = 442.8KW 
Power produced by column C = 0.5 x 1.23 x (2 x 16 x 20) x 103 = 393.6KW 
Power produced by column D = 0.5 x 1.23 x (2 x 14 x 20) x 103 = 344.4KW 
Power produced by column E = 0.5 x 1.23 x (2 x 12 x 20) x 103 = 295.2KW 
Power produced by column F = 0.5 x 1.23 x (2 x 10 x 20 x 103 = 246KW 
Power produced by column G = 0.5 x 1.23 x (2 x 8 x 20) x 103 = 196.8 KW 
Power produced by column H = 0.5 x 1.23 x (2 x 6 x 20) x 103 = 147.6KW 
Power produced by column I = 0.5 x 1.23 x (2 x 4 x 20) x 103 = 98.4 KW 
Power produced by column J = 0.5 x 1.23 x (2 x 2 x 20) x 103 = 49.2 KW 
Total Power=2675.2KW (2.67MW)

C: In our third example we shall consider a BSW with 30m x 40m frame.
Our calculations will show that as conservative this BSW can generate1476KW (1.476MW) or as an actual calculation will generate 10,326KW (more than 10MW).

By applying the same method which we’ve applied in the previous two examples, here is a summary of all the critical information needed to reach the two sets of power output figures, a low conservative figure and a highactual figure representing the total power generated by all the columns combined:

4.     A BSW with 30m x 40m frame has 20 columns lettered A, B, C, D, E. F, G, H, I, J, K, L, M, N, O, P, Q, R, S and T.
5.     Each column is 2m wide and 20m long
6.     Starting from the far end of the frame and moving toward the Central Post of the BSW, column A is the farthest from the Central Post and J is the closest; the radius values of the columns from column A to column T are as follow: 40m, 38m, 36m, 34m, 32m, 30m, 28m, 26m, 24m, 22m, 20m, 18m, 16m, 14m, 12m, 10m, 8m, 6m, 4m and 2m.

Conservative Power output:
In a conservative power output calculation, the radius of the frame is 40m and height 30m.
P = 0.5 x 1.23 x (2 x 40 x 30) x103 = 1,476KW 

Actual Power Output:
In an actual power output calculation, however, we shall calculate the power output of each column, a total of 20 columns. And because each column generates different amount of power corresponding directly to the value of its radius, we shall calculate all 20 power output values, add them up and reach the actual power produced by a BSW with 30m x 40m frame:

Power produced by column A = 0.5 x 1.23 x (2 x 40 x 30) x 103 = 1476KW 
Power produced by column B = 0.5 x 1.23 x (2 x 38 x 30) x 103 = 1402KW 
Power produced by column C = 0.5 x 1.23 x (2 x 36 x 30) x 103 = 1328KW 
Power produced by column D = 0.5 x 1.23 x (2 x 34 x 30) x 103 = 1254KW 
Power produced by column E = 0.5 x 1.23 x (2 x 32 x 30) x 103 = 1180KW 
Power produced by column F = 0.5 x 1.23 x (2 x 30 x 30 x 103 = 1107KW 
Power produced by column G = 0.5 x 1.23 x (2 x 28 x 30) x 103 = 1033KW 
Power produced by column H = 0.5 x 1.23 x (2 x 26 x 30) x 103 = 959KW 
Power produced by column I = 0.5 x 1.23 x (2 x 24 x 30) x 103 = 885KW 
Power produced by column J = 0.5 x 1.23 x (2 x 22 x 30) x 103 = 811KW 
Power produced by column K = 0.5 x 1.23 x (2 x 20 x 30) x 103 = 738KW 
Power produced by column L = 0.5 x 1.23 x (2 x 18 x 30) x 103 = 664KW 
Power produced by column M = 0.5 x 1.23 x (2 x 16 x 30) x 103 = 590KW 
Power produced by column N = 0.5 x 1.23 x (2 x 14 x 30) x 103 = 516KW 
Power produced by column O = 0.5 x 1.23 x (2 x 12 x 30) x 103 = 442KW 
Power produced by column P = 0.5 x 1.23 x (2 x 10 x 30 x 103 = 369KW 
Power produced by column Q = 0.5 x 1.23 x (2 x 8 x 30) x 103 = 295KW 
Power produced by column R = 0.5 x 1.23 x (2 x 6 x 30) x 103 =221KW 
Power produced by column S= 0.5 x 1.23 x (2 x 4 x 30) x 103 = 147KW 
Power produced by column T = 0.5 x 1.23 x (2 x 2 x 30) x 103 = 73KW 

Total Power = 10,326KW (10.326MW)



















































































Moving parts and maintenance
The only moving parts in the blinking sail windmill are theswinging windows and the sails.
The swinging windows do not move all the time; they simply swing in high winds only. Since swinging windows are made from metal so they will last for a hundred years. Since they move in just a quarter turn only and in high winds only so their ballbearing will last minimum for hundred years. So the swinging windows will not need maintenance for hundred years.
So we left with the movement of the sails of quarter turn per cycle. The ballbearing will last minimum for 50 years since the ballbearings are currying negligible weight. When we make the sails from long lasting materials like Grafeen or “Carbon Fiber-Reinforced Polymer” or Carbyne, The sail will last for tens of years with no need for maintenance.
So the blinking sail windmill practically shot and forget. Install it and forget the maintenance for 50 years.
Noise  
The sails of the BSW won't bang against the green swinging windows, not only because the sails are extremely rigid but also because the spiral springs attached to ball bearing of the sails will prevent the sails from banging against the green swinging windows. They are always a distance of 10cm away from the green swinging windows because when it returns the spiral spring will keep the sail at 10 °degree angle from the vertical plane.
When a powerful wind push the sail it will slowly move until it touches the green swinging window with no noise. When that happens the sail will start to push the green swinging window out of plane to let some of the air pass through. As the wind gets stronger and stronger the gap to let the air pass through will get bigger and bigger; the stronger the wind the larger the gap.
The BSW's built-in safety mechanism is designed so that it can work when wind speed is strong or super strong. The green swinging windows are fitted with spiral Springs. When the wind is weak the green swinging windows are in vertical position but as the wind gets stronger and stronger and the sails start to push the green swinging windows the increased force will push the spiral springs. This will cause the green swinging windows to shift out of plane and consequently permit some of the air to pass freely through the slowly widening gap. As the wind gets stronger the gap will get wider allowing more air to pass through it. The BSW will produce power in slow and fast wind, without making noise.
Birds
the bird can see the Blinking sail windmill clearly since it has wide surface area and its speed is not so fast so no bird deaths will take place like present windmills do since the tip of the blade is moving at 300km per hour and it is invisible due to small surface aria at the tip of the blade.
 Helical BSW 
Although the animations show “linear” frames, in fact when the BSWs are built and deployed in commercial wind farms their frames will be helical. So, how are the frames arranged and how do they look like as their numbers change?
In a BSW with 4 frames, each frame starts at a point at the bottom on the Central Post and end at the top of the Central Post at 90 degree angle, while in a BSW with three frames, each frame starts at a point at the bottom on the Central Post and end at top of the Central Post at 120 degree angle. Finally, each frame of a BSW with two frames will start at a point at the bottom of the Central Post and end at the top of the Central Post at 180 degrees angle.
Helically-shaped frames are more aerodynamic, evenly spread the torque experienced by the frames as they spin and will prevent pulsations. When the blinking sail windmill becomes helical the columns will spread creating gaps between them, where the wind pushing the sails will have an aerodynamic passageway where wind current move dynamically in the system of blinking sail windmill.

A powerful windmill made from the lightest material in the world manufactured by Boeing a revelatory microluttice lighter than Dandelion.

Easily assembled and deployable.

It generates electricity even at extreme low wind.

The sails of the blinking sail windmill are so light since they are made from microluttice which is lighter than Dandelion. So the lowest wind will blow them away so the wind will pass freely from three frames while the active frame blocks the wind so we have a 20 meter by 20 meter sale blocking the wind and generating huge energy.

A wind farm made from this blinking sail windmill which cost $100 million it will generate electricity more than a wind farm cost $10 billion made from present windmills.

The blinking sail windmill will change the landscape of wind energy.

 

HRL Researchers Develop World's Lightest Material

http://www.hrl.com/hrlDocs/pressreleases/2011/prsRls_111117.html

 

Boeing: Lightest. Metal. Ever.

https://www.youtube.com/watch?v=k6N_4jGJADY

https://www.youtube.com/watch?v=rWEzq8m9KHQ

 

Industrial design windmill with Boeing’s revolutionary microluttice lighter than Dandelion. Makes the most powerful windmill in history.For Wind farms very low cost easy to assemble by unskilled workers.
https://www.youtube.com/watch?v=yDA0V3L8f0U#t=520


http://www.youtube.com/watch?v=LNXTm7aHvWc



My US patents 7780416 &  8702393 windmills the energy it generates is tens of times more than the present windmill for a windmill which costs tenth the cost of the present windmill.
Therefore this windmill is hundreds of times more efficient than the present windmill per cost/power generated






The blinking sail windmill generates so much electricity due to its large size let’s say the 20 meters by 20 meters that the owner will get his money back in 142 days and that will never happen in any windmill even when they dream of one, the owner of the blinking sail windmill will get his money back in 142 days when he use it to generate electricity or make distilled water in desert countries or when making hydrogen from water to use it in cars instead of using petrol.

 My windmill has all these three properties it cost 10% only of the cost of the present windmill and this low cost BLINKING SAIL WINDMILL generates ten time more electricity than the present windmill therefore it is 10 x 10 = 100 times more efficient than the present windmill, in view of the cost. Besides that it has much less maintenance cost since the generator is not 170 meters above the ground like the present windmillbecause the blinking sail windmill generator is few meters above the ground .

therefore no lightening can damage the generator of the blinking sail windmill

.


More energy is used to produce present wind turbine than it will ever generate



Blinking sail windmill only uses 14.8 tons of steel. All of it can be packed in one single track and assembled by unskilled workers without the use of any crane. It cost %1 of the cost of the present windmill.

  


Building Blinking sail windmill using tower crane

We can use present tower crane to make the one megawatt, 1MW blinking sail windmill, simply we fix four arms of the tower crane at the top instead of one. Where we hang on each arm of the tower crane a frame 25m width by 33m height.






From the photos below we can see how strong is the tower crane and it can carry the four frames of blinking sail windmill so easily as if it is carrying a father.




As we see the crane price can be as low as  $22,000 where the four frames will cost less than $15,000
So with less than $40,000 we will have a 1MW windmill, if we add the generator price and the foundation cost the entire blinking sail windmill cost will be less than $175,000. With such price the blinking sail windmill will land slide the world of wind power generation.





Links to tower crane
https://www.youtube.com/watch?v=RB91Sm-kGJ8



The life time of a ballbearing is 500000000 revelations to one million revelation.
The BSW spins between 40-100 rev per minute. Thus, taking the higher figure of turns:
BSW turn/year = 100 x 60 x 24 x 365 = 52,560,000
500000000 ÷ 52560000 = 9.61
Since the blinking sail windmill two sail ballbearing is caring very light weight and running at very low speed it will last minimum 20 to 30 years. The same applies to the green swinging window ballbearing.
But Since the sail ballbearing only turns 90 degree only that means quarter turn therefore it will last: years
9.61
x
4
=
38.44 years

Where the green swinging window only move in strong wind so the ballbearing will last much longer than 38.44 years
Let me now address the concern about noise.
The sails of the BSW won't bang against the green swinging windows, not only because the sails are extremely rigid but also because the spiral springs attached to ball bearing will prevent the sails from banging against the green swinging windows. They are always a distance of 10cm away from the green swinging windows because when it returns the spiral spring will keep the sail at 10 °degree angle from the vertical plane.
The BSW's built-in safety mechanism is designed so that it can work in when wind speed is weak or super strong. Thus, a powerful wind will slowly push the sail until it touches the green swinging window so no noise is resulted. When that happens it will start to push the green swinging window out of plane to let some of the air pass through. As the wind gets stronger and stronger the gap to let the air pass through will get bigger and bigger; the stronger the wind the larger the gap.
The green swinging windows too are fitted with spiral Springs. When the wind is weak the green swinging windows are in vertical position but as the wind gets stronger and stronger and the sails start to push the green swinging windows the increased force will push the spiral springs. This will cause the green swinging windows to shift out of plane and consequently permit some of the air to pass freely through the slowly widening gap. As the wind gets stronger the gap will get wider allowing more air to pass through it. The BSW will produce power in slow and fast wind, without making noise.
Given the two salient characteristics of the BSW, massive size and slow motion, it is unfathomable that this turbine will result in killing birds




The Blinking sail windmill does not need a prototype to prove its magical capability since the sails which move boats and ships is the proto type for this invention.
This windmill has one of the sales blocking the wind all the time. Therefore it generates power. While all the other sails letting the wind to pass through freely without any obstruction, so as if they do not exist. The result is one sail like in the ship generating power capable of moving a big electrical generator or a big water pump.
The sail boats race which takes place every year where the boats travel around the world and all the power is supplied to these boats for this very long trip comes from a piece of cloth its price equivalent to some gallons of petrol. If changed to an engine boat it will need tons and tons of petrol to complete the journey around the world besides the spare parts and the initial high cost.
When you watch these boats you can really see them moving at a high speed and cutting through the water with real force and big power and all of this is coming from a peace of cloth practically worth's nothing.

TP52 Quantum Racing on the edge downwind in big breeze




my solo transatlantic trip 2012


  

If we make the electrical generator of the Blinking Sail Windmill having multi coil so when the wind is week only one coil activated then when the wind gets faster the second coil is activated so we get more electrical power and if the wind gets stronger the third coil activated and so on.
when the wind gets much stronger the spiral spring of the horizontal bars starts to act so the horizontal bars start to swing to the other side, so even the active sail ( the sail which is blocking the wind) starts to let some of the wind to pass through the active sail so the wind do not damage the sail and as the wind gets stronger the gap gets bigger, therefore  all the time the Blinking Sail Windmill is safe and generates electricity at the strongest winds besides generating electricity at the weakest wind near to stand still speed.
Jasim Al-azzawi

Giant manufacturers have to scrap all their factories & make new once. Therefore they don’t 
want this breakthrough Blinking sail windmill.
Plus it will cancel all their contracts for new wind farms which they have now they will lose billions
This new windmill can be made by any one it is so simple design. And can be assembled by any one with no cranes at all

 It's rare to see that clearly how much concrete there's in an offshore wind turbine, this is just for 30MW

And it can be assembled in very short time by very unskilled people. see this vidio..
The video above shows step by step how it is made and assembled that is the 20x20 meter windmill
It can be assembled by any unskilled people it is so cheep so efficient so easy for maintenance.
The solution to energy problem of this planet is this breakthrough windmill
Which is 1000 times more efficient than present windmills in view of cost to the energy production
Where with this Blinking sail windmill if we build offshore huge windmills with a cost of one billion dollars
They will give us power equivalent to one trillion dollars windmills of the types used to day.
It may sound unbelievable but the calculations prove it without any doubt.
Send me an email I will send you the calculations which proves that.
 No one can argue with calculations because math’s is a constant thing no one can proves it wrong no one at all.



US patent 7780416 blinking sail windmill fast wind 




US patent 7780416 blinking sail windmill gentle wind 





Blinking sail windmill
Patent Number: 7780416

  Blinking sail windmill with safety control
Patent Number: 8702393



Blinking sail windmill, BSW
The rotational surface area for a BSW which has frames 20 meters by 20 meters is:
40m x 20m = 800 square meters
Since only one frame is active therefore:
We have %50 of the surface area is generation power which is:
800 x %50 = 400 square meters.
.


Three blades windmill  

 The blade length is 20 meters therefore it rotates in a circle its radius is 20 meters.
Surface area for this windmill is:
2Πr2 
2 x 3.141 x 20 x 20 = 2513 square meters

The blade width is one meter therefore its surface area is:
1 x 20 = 20 square meters
We have three blades therefore their total surface area which is responsible for generating the power is:
20 x 3 = 60 square meters

So the Three blades windmill has surface area of  2513 square meters of which only 60 square meters are active.
Therefore the efficiency of this windmill in surface area wise is:
60/2513 x 100 = %2.388
.

If the blade is 2 meters wide the three blades surface area will be:
2 x 60 = 120
Therefore the efficiency of this windmill in surface area wise will be:
120/2513 x 100 = %4.78

Conclusion
The blinking sail windmill efficiency in surface area wise is %50.
The Three blades windmill  efficiency in surface area wise is %2.388
Therefore if we divide the efficiency of the blinking sail windmill by the efficiency of the Three blades windmill :
%50 / %2.388 = 20.9
Therefore the blinking sail windmill is more efficient than the Three blades windmill  in active surface area wise by 20.9 times.

If the Three blades windmill  has blades 2 meters wide then:
The blinking sail windmill is more efficient than the Three blades windmill in active surface area wise by %50 / %4.78= 10.5  times.




If we take cost and efficiency in consideration then the 20 x 20 meters Blinking sail windmill is more efficient than the 170 meter three blades windmill



The blade length is 170 meters therefore it rotates in a circle its radius is 170 meters.
Surface area for this windmill is:
2Πr2 
2 x 3.141 x 170 x 170 = 181549.8 square meters

The blade width is one meter therefore its surface area is:
1 x 20 = 170 square meters
We have three blades therefore their total surface area which is responsible for generating the power is:
170 x 3 = 510 square meters

So the Three blades windmill has surface area of  181549.8 square meters of which only 510 square meters are active.
Therefore the efficiency of this windmill in surface area wise is:
510 /181549.8 x 100 = %0.281

The blinking sail windmill efficiency in surface area wise is %50.
The Three blades windmill  efficiency in surface area wise is %0.281
Therefore if we divide the efficiency of the blinking sail windmill by the efficiency of the Three blades windmill :
%50 / %0.281= 177.93
Therefore the blinking sail windmill is more efficient than the three blades windmill in active surface area wise by 177.93 times per cost/ power generated.



Industrial design windmill for Wind farms very low cost easy to assemble by unskilled workers.
http://www.youtube.com/watch?v=2vvbmGa0XVY&feature=youtu.be


Industrial-size Blinking Sail Windmill can easily be manufactured, packed, transported and quickly assembled at site by unskilled people in a very short period of time.

This video step by step shall outline the manufacturing process of the Frame Unit, one of the key components of the Blinking Sail Windmill.
Which consists from very simple parts which can be made by any small factory in any country, even the poorest country in the world.

These parts are perforated steel flat bars, steel Angle, Mounted Bearings,
Swinging Window, Sail, Sail Shaft, very small Spiral Springs, Vertical Post.

The Sail can be made of two thin layers of plastic or synthetic materials,
ratenge,  sandwiching a mesh of fine steel wires, such as piano wires. The result is a tough, yet light sail that can easily be moved by a light breeze

The Vertical Post made in 0ne or two meters parts then assembled on site. Where each of these parts is made to be assembled on site therefore it is easily manufactured, packed, transported and quickly assembled at site.