Wind powered propulsion device

A wind powered propulsion device has a sail mount and harness means for retaining the sail mount on the back of a person. A sail is mounted on the sail mount. Preferably the harness means includes a backpack-like device having a back rest and strap for fitting over the shoulders and around the waist of a person. The mount may include a mast for holding the sail in a generally vertical position and a swinging arm. The sail is mounted at a first end of the swinging arm which is pivotal at a second end about an axis through the sail mount.

BACKGROUND OF THE INVENTION 
This invention relates to a wind powered propulsion device including a sail 
and a backpack-like device for fitting over the shoulders and around the 
waist of a person. 
The wind has been used extensively in the past and is presently used for 
powering marine vessels and, less extensively, vehicles. For example, a 
bicycle sail is disclosed in U.S. Pat. No. 3,836,176 to Ylvisaker. The 
sail in this case is curved in a somewhat airfoil-like shape. Other sails 
for bicycles are shown in U.S. Pat. No. 639,107 to Sorensen and U.S. Pat. 
No. 3,381,647 to Keeler. The latter shows an airfoil sail including a 
plurality of horizontal, vertically spaced ribs. 
Sails for bicycles have not been widely used because in many cases the 
bicycle becomes unstable when provided with a sail. In addition, past 
devices have required modification of the bicycle or have been difficult 
to install. It would therefore be convenient to provide a device for wind 
propulsion of bicycles, other vehicles and small water craft which would 
be portable and easy to use without any modification of the propelled 
device. 
SUMMARY OF THE INVENTION 
According to the invention, a wind powered propulsion device comprises a 
sail mount and harness means for retaining the sail mount on the back of a 
person. A sail is mounted on the sail mount. 
The harness means may comprise a backpack-like device having a back rest 
and straps for fitting over the shoulders and around the waist of a 
person. 
The mount may comprise means for holding the sail in a generally vertical 
position and means for swinging the sail from side to side to adjust for 
the wind direction. 
In a preferred form, the means for swinging comprises swinging arm means 
having the sail mounted at a first end which is pivotal at a second end 
about an axis through the sail mount. The sail is generally vertical when 
the device is mounted on the back of an upright person. 
The device may further include a mast means for the sail means associated 
with the mast means and means for deploying and retracting the sail. The 
means for deploying and retracting may include a spring biased roller near 
the mast means, the sail being sheet-like and being connected to the 
roller. The means for deploying and for retracting may further include 
support rod means connected to an end of the sail opposite the roller and 
means for moving the support rod means away from the mast means. The means 
for deploying and for retracting may also include a plurality of support 
arms, each being hingedly connected to the mast means at a first end and 
being slidably connected to the support rod means at a second end. The 
support arms may each have a plurality of segments interconnected by 
hinges, the device including a mechanism for moving the segments about the 
hinges so the sail forms an airfoil shape.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Referring to FIG. 1, this illustrates a wind powered propulsion device 1 
which includes a sail mount 2 and a harness 4 for retaining the sail mount 
on the back of a person 6. A sail 8 is mounted on the sail mount 2. 
Referring to FIGS. 2 and 4, the harness includes a back pad 10 which is 
relatively rigid and contoured to comfortably fit the back of a person. 
Shoulder straps 12 and a waist strap 14, provided with a buckle 16, are 
connected to the back pad. 
An upper angle bracket 18, shown best in FIG. 2, and a similar lower angle 
bracket 20, shown in FIG. 4, extend rearwardly from the back of the back 
pad. These are connected to the back pad by rivets or other such means. An 
adjustment fan 22 is mounted on top of angle bracket 18 and has a 
plurality of apertures 24 extending in a circular arc about the adjustment 
fan. A pair of upper angle arms 26 are hingedly connected to brackets 18 
and 20 by pins 28. The unit is provided with a similar pair of lower angle 
arms 30, shown in FIG. 4, also hingedly connected to angle brackets 18 and 
20 by pins 28. A connecting member 32 extends between the pair of angle 
arms 26 below adjustment fan 22 and is provided with a vertically slidable 
locking pin 34. The locking pin is actuated by a control cable 36 to 
selectively engage one of the apertures 24 on the adjustment fan, thus 
locking the angle arm in a particular rotational position with respect to 
the angle brackets 18 and 20 and the back pad 10. 
The upper angle arms 26 are connected to flanges 38 and 40 of mast 3 by 
sets of nuts and bolts 42 and 44. The lower angle arms 30 are connected to 
corresponding flanges on the mast in a similar manner. 
Mast 3 consists of a pair of spaced-apart uprights 46 and 48 connected 
together by bolts 52 and 54 on brackets 50 and 51 as well as by mounts 53 
and 55. A recess 56 exists between the uprights 46 and 48 extending from 
near the top of mast to near the bottom as shown in FIG. 3. However, the 
mast has connecting portions 58 and 60, above and below recess 56 
respectively, which extend between the uprights 46 and 48. These 
connecting portions serve as bearings for axle 62 of spring loaded roller 
reefer 64 which is thus rotatably mounted on the mast in a vertical 
position between the uprights. 
Four swing arms 66, 68, 70 and 72 are each hingedly connected to upright 48 
by a hinge 74 as shown in detail for swing arm 66 in FIG. 9. The hinges 
permit the swing arms to swing between the vertical positions shown in 
solid lines in FIG. 3 and the horizontal lowered positions shown in broken 
lines or intermediate positions shown in chain lines. Referring to FIGS. 
10 and 11, a roller 76 is rotatably mounted near the outer end of each 
swinging arm by means of an axle 78. The rollers 76 are each slidably 
received within a channel-shaped, vertical support rod 80 which is 
substantially equal in length to mast 3. 
A sail fabric 82 is connected to support rod 80 at one end and to roller 
reefer 64 at the opposite end. 
Referring to the swing arms in more detail, swing arm 66 is shown as an 
example and includes three segments 82, 84, and 86 interconnected by 
hinges 88 and 90. Movement of the hinged segments is controlled by push 
rods 92 and 94 acting through bellcrank 96 and control arm 98. These serve 
as a mechanism for moving the segments about the hinges 88 and 90 so the 
swing arm, and consequently sail fabric 81, form an airfoil shape as shown 
in FIG. 10 or the straight shape illustrated in FIG. 9. 
Referring to FIG. 8, the push rod 92 for each of the swing arms extends 
through a guide 99 on the swing arm and is connected to a clevis 100 
through an intermediate treaded adjustor 102. Clevis 100 is treadedly 
connected to a short control rod 104 which is hingedly connected to a 
control arm 106. The control arm 106 for each of the swing arms is 
connected to a vertical control tube 108. As shown in FIG. 4, control tube 
108 is rotatably mounted in upper and lower socket members 110 and 112 
which are connected to upright 48. Referring again to FIG. 8, an airfoil 
lever 114 extends outwardly from control tube 108 and is used to turn the 
control tube and thus place the sail in the straight position of FIG. 9 or 
the airfoil shape of FIG. 10. A pointed latch member 116 is slidably 
mounted on a bracket 118 mounted on control tube 108. The latch member is 
biased towards the illustrated extended position by a coil spring 120. A 
control cable 122 connects the latch member to an airfoil stop control 
lever 124. The sail is moved into the airfoil shape of FIG. 10 by 
squeezing airfoil stop control lever 124 against airfoil lever 114 with 
the hand and then rotating control tube 108 anti-clockwise, from the point 
of view of FIG. 8, moving lever 114 until latch member 116 passes stop 126 
mounted on upright 48. Lever 124 is then released which returns latch 
member 116 to the extended position under the action of spring 120 and 
thus stop 126 holds the sail in the airfoil shape. 
The deployment of sail fabric 81 is controlled by a deployment handle 128 
at the end of two spaced-apart levers 130 and 132 extending forwardly from 
mast 3. Handle 128 is connected to a block 134 slidably received within 
channel-shaped control column 136. A spring biased pawl 138 on the back of 
block 134 selectively engages one of the spaces between two of the teeth 
140 vertically aligned along the control column. Push bar 142 on the 
bottom of deployment handle 128 is pushed to retract pawl 138 by means of 
wedge member 139 and allows the deployment handle to move freely upwards 
along control column 136. Push bar 144 on top is pushed to extend pawl 138 
to engagement between two of the teeth 140 and thus prevents upwards 
movement of the deployment handle but allows downward movement by 
"clicking" of the spring biased pawl along the teeth. 
A cable 146 is connected to the top of block 134 and extends over a pulley 
148. Referring to FIG. 5, it may be seen that cable 146 is connected to a 
cable extending to each of the swing arms by means of a system of pulleys 
and cables. For example, cable 146 is connected to swing arm 70 by means 
of cable 149 which extends over pulley 150 mounted on the end of a pulley 
arm 152 connected to mast 3. Cable 146 is connected to cable 154 of swing 
arm 72 and then extends about double pulleys 158 and then pulley 156 on 
pulley arm 160 to cable 146. Thus, it may be observed that, by moving 
deployment handle 128 downwardly along control column 136, swing arms 66, 
68, 70 and 72 swing downwardly from the raised vertical position 
illustrated in FIG. 5 to either one of the intermediate positions, one of 
which is shown in chain lines in FIG. 3, or the fully deployed, horizontal 
position shown in broken lines in FIG. 3. The pivoting of the swing arms 
causes support rod 80 to move outwardly away from mast 3 and thus deploys 
sail fabric 81. The sail may be partially deployed as shown in chain lines 
in FIG. 3 or fully deployed as shown in broken lines in FIG. 3. The 
deployment of the sail causes clockwise rotation of roller reefer 64 shown 
in FIG. 11. The sail thus unwinds from the roller reefer which is 
resiliently biased in the anticlockwise direction. It should be noted that 
sail fabric 161 is deployed at the same time on the opposite side of the 
roller reefer from sail fabric 81. The sail mechanism has been described 
only with respect to the right hand side of the mast from the point of 
view of FIG. 1. However, identical swing arms, such as swing arm 162, are 
employed on the opposite side of the mast for deployment of the sail. 
These swing arms are also formed by hingedly connected segments to form an 
airfoil shape as shown in FIG. 1 controlled by another airfoil lever 164. 
In use, the device is strapped on to the back of a person 6 using harness 4 
including shoulder straps 12 and waist strap 14. The device may be used 
for propelling a bicycle 166 as shown in FIG. 1, or, alternatively, roller 
skates, another vehicle, or a surf board. These are examples only. After 
securing the device on the back of the person, the person chooses the 
proper angle of the sail according to the wind direction. Cable 36 is 
connected to a sail release handle 168 shown in FIG. 4. This handle is 
depressed to move locking pin 34 downwardly and out of engagement with 
aperture 24 shown in FIG. 2. A sail angle handle 170, mounted on lever 
132, as shown in FIG. 1, is used to rotate the sail about pins 28 to the 
desired direction. Two possible positions are shown in solid lines in FIG. 
1 and also in broken lines in this figure. When the chosen sail angle is 
reached, handle 168 is relieved to engage locking pin 34 and hold the sail 
in that position. 
The person then uses deployment handle 128 to deploy sail fabrics 81 and 
161. Push bar 144 is depressed and handle 128 is moved downwardly until 
the sails are deployed to the desired extent. Pawl 138 prevents the 
deployment handle from moving upwardly to retract the sail fabrics. When 
this is desired, however, push bar 142 is pushed to retract pawl 138. This 
must only be done when the swing arms are straight. 
The person may choose to have the sail in the airfoil shape shown on the 
left side of FIG. 1 according to wind velocity and conditions. However, 
the airfoil shape can only be achieved when the sails are fully deployed 
by moving handle 128 to the bottom of control column 136. The swing arms 
must be horizontal before they can be articulated. As described 
previously, the airfoil lever 114 is used to achieve the airfoil shape on 
one side of the sail, while airfoil lever 164 is used for the same purpose 
on the opposite side. During use, the person may change the shape of the 
sail, the amount of sail deployed as well as the angle of the sail 
according to his wishes and conditions encountered.