Super setter plastic fishing hook

A monolithic molded plastic fishing hook connectable to a monofilament fishing line. The hook by its unique parts is arranged to provide a shock absorber action during catching fish, to release from a hooked snag before the line breaks, and to maintain the axis of penetration of the barbed point substantially parallel to the line of action while under tension.

BACKGROUND OF THE INVENTION 
This invention relates to the field of fishing, and it more particularly 
relates to a unique fishing hook. 
DESCRIPTION OF THE PRIOR ART 
The art of fishing using a line and hook is ancient. Multitudes of hooks 
have been used and constructed from materials ranging from carved bones, 
metals and even modern plastics. In most cases, the design of the hook was 
an overkill, i.e., the hook was the strongest part of the fishing system. 
Naturally, this design concept has caused many a fisherman to loose his 
tackle by hooking a snag. A strong pull by the fisherman, if it did not 
retrieve the snag, usually led to the line breaking somewhere along its 
length. 
The design of the hook has been to prevent bending or uncurving of the bent 
part which connects the barbed point to the body secured to the fishing 
line. Although hooks have been proposed with flexible bends, they always 
prevented straightening and insured an inwardly curved motion to insure 
better hook setting results. Naturally, a self setting hook always holds 
the tightest to a snag, etc. 
It has been found that a strong rigid hook i.e., a heavy steel hook, does 
not always insure a hooked fish, even a fish that strikes very hard. The 
rigid hook causes a tensioning effect on the fishing line and unless its 
barbed point drives cleanly home in the cartilage of the fishes mouth, 
slight slippage of the point causes the hook to "spring" from the mouth 
and results in a lost fish. Thus, a hook that has a shock absorber action 
in firmly but not rigidly pressing the barbed point in the fishes mouth 
would be better than a cast iron-rigid hook. Also, this spring action 
allows less tear in the fishes mouth which is particularly important when 
releasing a caught fish or if one "gets off the line." 
It is the purpose of this invention to provide a unique fishing hook that 
releases from a snag before breaking the fishing line but yet "hooks" a 
fish better than steel hooks. 
SUMMARY OF THE INVENTION 
In accordance with this invention, there is provided a unique fishing hook 
formed of a monolithic molded member. The hook has an elongated body of 
uniform cross-sectional area with a connection at one end part for 
receiving the fishing line. A looping reverse curved part having a 
cross-sectional area not greater than the body connects the body at its 
other end with a barbed point. The barbed point penetrates encountered 
animal forms in the direction of the connection part. If the hook becomes 
caught on an obstruction, the barbed point will deflect outwardly from the 
body to straighten out the looping curve part so as to release the barbed 
point from the obstruction prior to the line pulling force reaching the 
rated fishing line strength. 
In one embodiment of the invention, the hook is constructed so that in a 
relaxed state the barbed point is inclined at a small angle, toward the 
line of action of the body but when placed under tension, the barbed point 
will be deflected outwardly to n ear parallel the line of action of the 
body, for optimally penetrating animal forms. This outward deflection 
occurs when the line pulling force approaches about 85% of the force 
required to release the barbed point from an obstruction. In an alternate 
embodiment, the barbed point will reach the parallel position when the 
line pulling force reaches a predetermined level within the range of 25 to 
75% of the rated fishing line strength for which the hook is designed. 
This force level is less than the force required to free the barbed point 
from an obstruction. In either embodiment, the small angle of the barbed 
point is preferably about 4 degrees and the barbed point is of the nail 
point type. 
In yet another embodiment, the barbed point, in a related state, is 
parallel with the line of action of the body and will be deflected 
outwardly when a snag is encountered and the line pulling force reaches a 
predetermined level less than the rated strength of the fishing line 
connected to the hook.

DESCRIPTION OF PREFERRED EMBODIMENTS 
Referring to FIGS. 1 and 2, there is shown a fishing hook 11 constructed in 
accordance with the present invention. The hook 11 is a monolithic molded 
plastic member which can be formed in metal dies under high pressure and 
temperature molding from thermoplastics such as Xytel 330 or Rynite 35S, 
both trademarks of Dupont plastics. For example, the hook 11 can be molded 
at 550.degree. F. and 8000 psi conditions in steel cavity molds. 
The hook 11, although monolithic, has a unique shape and cross-sectional 
relationship between its several parts to produce the novel results 
priorly listed and more fully discussed hereinafter. 
The hook 11 has a body 12 of uniform cross-sectional area. Although the 
cross-section of the body 12 may be of any structural shape capable of 
producing the desired results, it is preferred that the cross-sectional 
shape be ellipsoidal, as is shown by reference to FIG. 3. The body 12 with 
this uniform cross-sectional shape provides an elastic beam which can 
deflect between its ends to a uniform curvature upon being subjected to a 
load proportional to its bending movement. 
An eye 13 is formed at one end of the body 12, and a fishing line can be 
attached to it. The pulling force of this line acts along a line-of-action 
15 passing longitudinally through the body 12. Naturally, this acting 
force on the hook 11 produces both the bending movement and tension across 
the body 12. 
The body 12, at its other end remote from the eye 13 connects with a 
looping curved part 14 that forms a reverse curved shape and connects to a 
barbed point 16. The part 14 has a uniform cross-sectional shape like the 
body 12, but its cross-sectional area is not as great as the body. There 
is a preferred relationship between these cross-sectional areas of these 
parts that will be described hereinafter. If a great enough force is 
applied to the hook, such as when an obstruction is snagged, the curved 
part 14 will straighten out sufficiently to release the barbed point 16 
from the object. 
The barbed point 16 has a shank 17 connected with the curved part 14 and an 
end formed into a head 18 ending at a sharp point 19. The shank 17 
preferably has an ellipsoidal cross-sectional shape but is smaller in area 
than the adjacent end of the curved part 14. The barbed point 16 has 
penetration axis 21 residing in a plane common to the body and curved part 
and extending lengthwise from the sharp point 19, through the shank 17 
into the end of the curved part 14. In a relaxed state, the penetration 
axis 21 of the barbed point 16 may be parallel to line-of-action 15 or may 
be inclined towards or away from the line-of-action by no more than a 
small angle. In the embodiment illustrated in FIGS. 1-7, the penetration 
axis is shown inclined toward the line-of-action by a small angle 24. In 
this embodiment, good results are obtained when this small angle 24 is 
less than 7.5 degrees, and best results occur with the small angle 24 
about 4 degrees. 
It will be apparent that the hook 11 molded as a thermoplastic member has 
certain flexural properties. As the pull of the fishing line increases 
along the line-of-action 15, the barbed point 16 will exert a counter 
force on a hooked object such as a fish. The barbed point 16 is deflected 
outwardly decreasing the small angle 24 towards zero. The cross-sectional 
areas of the body 12, curved part 14 and barbed point 16 are adjusted in 
relative beam strength that the small angle 24 becomes zero when the 
fishing line pulling force approaches about 80-85 percent of the total 
pulling force along the line-of-action 15 required to straighten out the 
curved part 14 and release the barbed point 16 from the engaged object. 
This relationship of cross-sectional areas, for this unique result, can be 
defined by complex mathematical relationships but they can be as easily 
determined by cut-and-try testing of the hook 11 and then adjusting the 
cross-sectional area relationships. 
As the barbed point 16 becomes parallel to the line-of-action 15, its 
penetration ability on fish members (flesh and cartilage) reaches an 
optimum. Thus, the heavier fish on a given hook construction will get the 
best penetration by the barbed point 16. 
The head 18 should be designed to not only give good penetration 
performance, but only to lock into the fish when penetration is effected. 
Good results are obtained when the head is formed as a nail point type 
with several plane or concave surfaces 23 merging at the point 19. 
Preferably, the inward ends of the surfaces 23 extend beyond and below (as 
at 26) with shank 17. Thus, once the head 18 passes through the flesh, the 
outwardly extending surfaces prevent withdrawal of the barbed point 16. 
If desired, the head 18 can be of other design types, such as the pyramidal 
shape shown in FIGS. 5 and 6 on the head 18'. In this construction, the 
head 18' has trapezoidal arranged flat surfaces 27 merging to point 19' 
and with the inward surfaces 28 extending below the shank 17 to form the 
flesh lock function. 
Preferably, the hook 11 is constructed so that for a given fishing line 
strength, the curved part 16 will deflect or straighten out to release the 
hook from an obstruction at a magnitude of fishing line pull of 90-95 
percent of the test breaking strength of the line. For example, a 15 pound 
test nylon monofilament fishing line is to be used with the hook 11. In 
this case, the curved part 14 will deflect to release the barbed point 16 
at about 13.5 pounds pull on the hook 11. For this hook 11, the barbed 
point 16 is deflected into parallel with the line-of-action 15 when the 
line pulling force is about 11 pounds. With this arrangement of the hook 
11, it will catch fish efficiently of the magnitude on 15 pound test line 
in a sportsmanlike manner. If a limb or other snag is snaired or hooked, 
the hook 11 can be pulled free, and there is no loss of equipment through 
broken tackle, line or hook which quickly reassumes its relaxed state 
shape shown in FIGS. 1 and 2. 
The functioning of the hook 11 can be understood by viewing FIG. 7. The 
hook 11 is shown with the barbed point 16 secured with the point 19 
against a restraint surface (not shown). The line pull along the 
line-of-action 15 is of a magnitude to reduce the small angle 24 to zero 
and the penetration line 21 falls on the line 22. 
At this condition the body 12 as an elastic beam, assumes a uniform radius 
of curvature through lateral deflection indicated by the arrows 28. 
Likewise, the curved part 14 is bent into a slightly greater curvature 
through lateral deflection indicated by the arrows 29. It will be apparent 
that this deflection of the body 12 and curved part 14 is induced flexure 
by design relationship of the respective cross-sectional areas (i.e., 
their bending movements). 
If the line force were varied, as by a fighting fish, the hook 11 responds 
by variations in beam flexure which is a shock absorber function. As a 
result of this function, the barbed point 16 is held with its point 19 
against the encountered surface and does not tend to slip loose as does a 
hard, less resilient steel hook. 
It will be apparent that a superior performing hook 11 is described, but 
also a hook that can be designed to pull free of a snag, etc., at some 
line pull less than the tensile strength of the fishing line. Then the 
hook 11 snaps-back to its relaxed state shape ready for a new fishing 
encounter. 
Now referring to FIGS. 8 and 9, there is shown a fishing hook 111, 
comprising a further embodiment of this invention, and constituting a 
monolithic molded plastic member which can be formed of the materials and 
under the conditions hereinabove described for the embodiment shown in 
FIGS. 1 and 2. The hook 111 includes body portion 112 of uniform 
cross-sectional area obround in profile, as shown in FIG. 12. An eye 113 
is formed at one end of the body 12 and a fishing line can be attached to 
the hook as previously described. The pulling force acts along the line of 
action 115 passing longitudinally through body 112. At its other end, the 
body 112 connects with a looping curved portion 114 that forms a reverse 
curved shape and connects to a barbed point 116. The part 114 has a 
uniform obround cross-sectional shape corresponding to, but smaller than, 
that of body 112. Shank 117 connects the curved part 114 with the barbed 
point 116. The shank 117 preferably has a circular cross-sectional shape, 
smaller in area than the adjacent end of the curved part 114. 
As in the previous embodiment, the head 118 is formed as a nail point type 
head with several plane or concave surfaces 123 merging at point 119. 
Preferably the inward ends of the surfaces 123 extend beyond and below (as 
at point 126) with shank 117. Thus, once the head 118 passes through the 
flesh, the outwardly extending surfaces prevent withdrawal of the barbed 
point 116. In a relaxed state, the barbed point 116 has a penetration axis 
121 extending lengthwise from the sharp point 119, through the shank 117 
into the end of the curved part 114. The penetration axis 121 resides in a 
plane common to the body and, in the illustrated embodiment, is inclined 
at the small angle 124 to the line of action 115 passing longitudinally 
through the body 112. Good results are obtained when the small angle 124 
is less than 7.5.degree. and best results occur when the small angle 124 
is about 4.degree.. As in the previous embodiment of the invention, the 
penetration axis could, if desired, be positioned parallel to the 
line-of-action 115, or even inclined away therefrom at a slight angle, 
with equally effective results. 
Table A represent the International Game Fishing Association (IGFA) 
standards for adjusting the drag on a fishing line for a particular line 
strength. 
TABLE A 
______________________________________ 
Recommended 
Full or 
# IGFA Line Class Strike Setting 
Max. Setting 
______________________________________ 
12H 12 3-5 lbs. 6-8 lbs. 
30 20 4-7 lbs. 10-12 lbs. 
50 30 7-10 lbs. 15-18 lbs. 
50W 50 12-17 lbs. 21-26 lbs. 
80 50 12-28 lbs. 21-26 lbs. 
80W 80-80 30-45 lbs. 35-40 lbs. 
130 130 35-40 lbs. 55-65 lbs. 
______________________________________ 
In the embodiment shown in FIGS. 8-13, for a given IGFA line class, the 
size of the hook and the relative cross-sectional areas of body 112, 
curved part 114 and shank 117 may be adjusted so that the small angle 124 
becomes zero when the fishing line pulling force approaches a 
predetermined value within the range between the recommended IGFA strike 
setting and the full maximum setting. In other words, the small angle 124 
becomes zero between 25% and 75% of the rated (breaking) line strength for 
which the hook is designed. Preferably, the small angle becomes zero at 
the values listed under Strike Setting for a certain IGFA Line Class in 
Table A. Then, the 5 lbs. value for decreasing the angle 124 to zero is 
suitable for both 12 and 20 lbs. IGFA line classes. 
The embodiment shown in FIGS. 8-9 also exhibits shock absorbing functions 
as previously described for the embodiment shown in FIGS. 1-7, wherein the 
flexure of the body 112, curved part 114 and shank 117 assist the barbed 
point 116 in resiliently penetrating a fish. 
In the above discussions, it has been assumed that the barbed point of the 
fishing hook has encountered the obstruction. However, it is possible for 
a small diameter submerged tree limb, etc., to slip past the barbed point 
and contact the fishing hook in the curved portion connecting the body 
with the shank. The size of the hook and the relative cross-sectional area 
of the body curved part and shank are adjusted so that the curved portion 
will straighten out and release the hook when the line pulling force 
reaches a predetermined level with the IGFA Full or Maximum Setting given 
in Table A. Preferably, the hook is also constructed so that at the same 
time the hook will be released from an obstruction on the barbed point 
when the line pulling force reaches a predetermined level within the IGFA 
recommended strike setting given in Table A, or approximately one-third 
(1/3) of the force required to straighten out the hook when pulling on the 
curved part. 
Referring now again to FIGS. 8-13, a pair of spurs 125 are formed at the 
top of head 113 at oblique angle to the line of action 115 and are 
commonly referred to as a "cat's head." When a hook of the present 
invention is used with artificial bait, such as a plastic worm, the bait 
is commonly impaled upon the hook with a portion of the bait extending 
lengthwise in surrounding relation to body 112 and impaled a second time 
on barbed point 118. During casting or over time, the bait may shift or 
slip off of the hook. The spurs 125 prevent this slippage by firmly 
engaging the bait adjacent the eye 113. Although two spurs are shown, this 
part of the invention may be employed with only one spur or more than two 
spurs, with equal effectiveness. Also, the spurs may be located at other 
locations on the hook, such as along body portion 112. 
As illustrated in FIG. 14, it is within the spirit and scope of this 
invention to construct a fishing hook employing a common body and two, 
three or more curve parts, shanks and barbed points depending from the 
common body. The structure of a multiple barbed point embodiment is, in 
all other respects, as described hereinabove and shown in FIGS. 1-13. The 
barbed points may be positioned equidistant from each other, or in other 
configurations as may be found to be advantageous. The flexural properties 
of each segment of the hook corresponds to the various embodiments of the 
single fishing hook hereinabove described. 
Importantly, in both embodiments, the present hook becomes an integrated 
part of the fishing system for novel results as compared to the strongest 
part (overkill) design of the conventional fishing hook made of metal. 
Although the hook is shown with an eye to receive the fishing line, the 
connection can be provided by a socket or even an adhesive or thermoweld 
connection to the fishing line. 
From the foregoing, it will be apparent that there has been provided a 
novel hook for fishing. It will be appreciated that certain changes or 
alterations in the present hook may be made without departing from the 
spirit of this invention. These changes are contemplated by and are within 
the scope of the appended claims which define the invention. Additionally, 
the present description is intended to be taken as an illustration of this 
invention.