KR101373824B1 - Self-tunable compound bow - Google Patents

Abstract

The present invention relates to a compound bow which enables self-tuning which includes a handle with a grip unit on the center; a bow body composed of a pair of winds joined to both ends of the handle; pulleys joined to rotary shafts formed on the rear ends of each wing to be rotated; upper and lower pulley assemblies including cams which are joined to first sides of each pulley; a bowstring of which both ends are wound on each pulley of the upper and lower pulley assemblies; and first and second cam cables of which the first ends are joined to each pulley assembly and the second ends are joined to the opposite pulley assembly and which are wound on the cams of each pulley assemblies by pulling the bowstring. A contact pin in contact with the first cam cable when the bowstring is joined to a joining hole formed on the pulley and pulled is formed on one of the pulley assemblies. An indicator which is in contact with the second cam cable and moved when the bowstring is pulled inside a guide hole formed on the pulley is formed on the other pulley assembly. The indicator is composed of a contact protrusion unit and a supporting unit which are joined to each other on both lateral surfaces of the guide hole. The contact protrusion unit and the supporting unit are joined to two joining member which are separated at a predetermined space from each other along the guide hole.

Description

Self-tuning compound bows {SELF-TUNABLE COMPOUND BOW}

The present invention relates to a compound bow, and more particularly to a compound bow capable of self-tuning the length of the cam cable alone can be adjusted so that the upper and lower cam rotation angle is the same when the bow string is pulled.

In general, compound bows use cam or wheel effects to make them easier to pull without pulling, and increase the force fired at launch. It can be used mainly for hunting.

As shown in FIGS. 1 and 2, the conventional compound bow has an upper wing 20 coupled to an upper portion of a handle 10 having a grip portion formed at the center thereof, and a lower wing 26 coupled to a lower portion thereof. . Each end 22, 28 of the upper wing 20 and the lower wing 26 has cut portions 21, 27 formed therein, and a rotating shaft 70 is formed between the cut portions 21, 27 to form an upper portion. Lower pulleys 30 and 36 are rotatably installed on the rotation shaft 70.

Each pulley 30, 36 is wound with a bowstring 50 in a guide groove, and each end of the bowstring 50 is coupled to the pulleys 30, 36. In addition, each pulley (30, 36) is coupled to the cam (32, 38) that rotates with the pulley (30, 36), one end is wound around the cam (32, 38) as the bowstring 50 is pulled The shaft 32 is coupled to the pulley 110 to which the cams 32 and 38 are coupled, and the other end is rotated on both sides of the cutouts 21 and 27 of the opposite wings 20 and 26 in the form of Y-shaped bus cables 40a and 46a. Cam cables 40, 46 are formed that are coupled to 70.

In addition, a cable guard 60 for pushing the cam cables 40 and 46 to one side of the bow string 50 is installed at one side of the central portion of the handle 10 so that the arrows are not obstructed when the arrows are fired. The guard 60 is movably coupled to the slide 66 into which the cam cables 40 and 46 are inserted.

In the conventional compound bow configured as described above, when the bow string 50 is pulled, the upper and lower pulleys 30 and 36 rotate so that the cam cables 32 and 38 coupled to the respective pulleys 30 and 36 rotate. 40, 46) is pulled by winding, and when the bowstring 50 is released in the let-off (let-off), the arrow is a strong propulsion force by the momentary elastic force of the bow that is momentarily in place.

However, in the compound bow as described above, when the bow string 50 is pulled to the let-off state due to a change in the strength of both wings 20 and 26 or a point at which the bow string 50 is pulled, the upper and lower cams ( The rotation angles of the 32 and 38 may vary, and in this case, the two cams 32 and 38 may not be let-off at the same time, thereby reducing the original bow strength and reducing the accuracy of the arrow.

As such, when the rotation angles of the upper and lower cams 32 and 38 are different, the rotation angles of the upper and lower cams 32 and 38 are adjusted by adjusting the lengths of the cam cables 40 and 46. It is difficult to grasp the difference in the rotational angles of the cams 32 and 38, and therefore, it is difficult to adjust the cable length. It is inconvenient to grasp and inform.

Accordingly, the present invention is to solve the problems of the prior art as described above, an object of the present invention is to provide a compound bow capable of self-tuning that can equally match the rotation angle of the upper and lower cams even the bow user alone. .

Compound bow according to a preferred embodiment of the present invention is rotatably rotatable on the handle is formed in the center of the grip portion, a bow body consisting of a pair of wings coupled to both ends of the handle, and the rear end of each of the wings An upper and lower pulley assembly including a pulley to be coupled, a cam coupled to one side of each pulley and rotating together with the pulley, and a bowstring both ends wound around each pulley of the upper and lower pulley assemblies; Is coupled to each of the pulley assemblies, and the other end is coupled to the opposite pulley assembly and includes first and second cam cables wound around the cam of each pulley assembly as the bowstring is pulled, and one pulley assembly includes a pulley. The contact pin is coupled to the coupling hole formed in the contact hole to contact the first cam cable when the bow string is pulled, and another pulley assembly Is provided with an indicator which is moved in contact with the second cam cable as the bow string is pulled in the guide hole formed in the pulley, the indicator is made of a contact protrusion and a support portion coupled to each other on both sides of the guide hole, The contact protrusion and the support are characterized by being coupled by two coupling members spaced apart at regular intervals along the guide hole.

In addition, one of the two coupling members is characterized in that the bolt for detachably coupling the contact protrusion and the support.

In addition, the other one of the two coupling members is a coupling pin formed on the support, characterized in that the coupling pin is inserted into the insertion hole formed in the contact projection portion is coupled.

In addition, a contact rubber pad contacting the guide hole is provided between the contact protrusion and the support of the indicator to maintain the original position in the guide hole before the indicator contacts the second cam cable.

In addition, a position display unit is formed around the guide hole to indicate a position where the indicator is moved in contact with the second cam cable.

In addition, the coupling hole has a predetermined length and the contact pin is characterized in that coupled to the position that can be in contact with the first cam cable in the coupling hole.

In another embodiment, a plurality of coupling holes are formed, and the contact pin is coupled to one of the coupling holes.

In addition, the cam of each pulley assembly has an arc shape, the cam cable wound around the cam cable is wound, and the cam cable wound around the pivot point at a position spaced a predetermined distance away from the rotation axis of the pulley to which the cam is coupled The cam module is rotatably coupled at an angle, and the cam module is wound around the cam cable winding portion as the bow string is pulled, and then sequentially wound on the outer circumferential surface thereof, and the pull-off state of the compound bow is adjusted to adjust the pulling length. It characterized in that it comprises a fixing means for rotating the cam module by a predetermined angle around the pivot point and fixed to the pulley in the rotated position.

In addition, as a fixing means for fixing the cam module to the pulley, the cam module is formed with an arc-shaped position adjusting hole centered on the pivot point of the cam module, and the pulley to which the cam module is coupled is formed with a coupling hole. The coupling member is coupled to the ball and the coupling hole is characterized in that the cam module is fixed to the pulley.

According to the present invention, a compound bow capable of self-tuning capable of equally adjusting the rotation angle of the upper and lower cams even by the bow user alone is provided.

1 is a view of a conventional compound bow,
FIG. 2 is a view from behind of the compound bow of FIG.
Figure 3 shows a compound bow according to the invention before the bowstring is pulled,
4 is a detailed view of a pulley assembly coupled to one wing in FIG.
5 is an exploded perspective view of part of FIG. 4;
6 is a view showing a compound bow according to the present invention in a state in which the bowstring is pulled,
7 is a view showing the upper and lower pulley assembly to explain the operation of the indicator,
8 is a view showing another embodiment of the contact pin and the coupling hole in FIG.

Hereinafter, a self-tuning compound bow according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a view of the compound bow according to the invention before the bowstring is pulled, Figure 4 is a detailed view of the pulley assembly coupled to one wing in Figure 3, Figure 5 is a partial disassembly of the indicator in Figure 4 6 is a perspective view of the compound bow according to the present invention while the bowstring is pulled, and FIG. 7 is an operation state diagram of the tuning indicator of the present invention.

Compound bow is self-tunable according to the present invention is the bow body 100 is coupled to each end of the handle, the upper and lower pulley assembly (107, 108) coupled to the rear end of each wing 103, bow First and second cam cables 150a and 150b wound around the string 140, the cam 200 of each pulley assembly 107 and 108 as the bowstring 140 is pulled, and one pulley assembly 108. The second cam cable in the contact pin 500 is coupled to the coupling hole 503 formed in the pulley 110 and the guide hole 403 formed in the pulley 110 of another pulley assembly 107 And an indicator 400 moved in contact with 150b.

Compound bow according to a preferred embodiment of the present invention shown in the drawings as a dual cam method to describe in detail each configuration first bow body 100 is a handle (grip) is formed in the center is gripped by the user ( 102 and a pair of limbs 103 coupled to both ends of the handle 102, the rear portion of which consists of two branches, and between the two ends of the wings 103. A rotating shaft 101 is formed to which the pulley assemblies 107 and 108 are rotatably coupled. The cable guard 105 for pushing the first and second cam cables 150a and 150b to one side of the bowstring 140 is coupled to the central portion of the handle 102 so that the arrow is not disturbed when the arrow is fired.

The upper and lower pulley assemblies 107 and 108 are rotatably coupled to the rotation shaft 101 at the rear end of each wing 103, and the upper and lower pulley assemblies 107 and 108 are symmetrically configured. The same pulley 110 is rotatably coupled to the rotary shaft 101 formed at the rear end of each wing 103, and coupled to one side of each pulley 110 to rotate with the pulley 110 It comprises a cam 200.

The pulley 110 has a plate shape close to an oval shape, and an eccentric through hole is formed at the center thereof so that the rotation shaft 101 is coupled thereto. The outer circumferential surface of each pulley 110 is formed with a guide groove recessed to a predetermined depth so that the bowstring 140 can be wound. A bowstring 140 wound on a guide groove is formed on one side of each pulley 110, A fixing protrusion 111 for fixing one end of the fixing protrusion 111 is formed. In addition, fixing pulleys 112 and 113 to which the cam cables 150a and 150b are fixed are formed at each pulley 110.

The cam 200 is formed on each pulley 110 and rotated together as the pulley 110 rotates, and has an arc shape, and the cam cable winding unit 210 to which the cam cables 150a and 150b are wound; The cam 200 is rotatably coupled to a predetermined angle from the cam cable winding part 210 about the pivot point A at a position spaced a predetermined distance from the rotation shaft 101 of the pulley 110 to which the cam 200 is coupled. As the cam cable winding groove is formed so that the bow string 140 is pulled, the cam cable 150 is wound on the cam cable winding 210 and then includes a cam module 220 which is wound around the outer circumferential surface sequentially.

In addition, the cam 200 rotates the cam module 220 by a predetermined angle about the pivot point A to adjust the draw length of the let-off state of the compound bow, and the pulley ( Fixing means for fixing to 110 is further provided.

The cam cable winding unit 210 is wound so that the cam cables 150a and 150b having one end coupled to the fixing protrusion 112 located near the cam cable winding unit 210 as the bow string 140 is pulled. It is made of a shape and the outer circumferential surface is formed with a winding groove wound around the chem cable (150a, 150b).

The cam module 220 is rotatable by a predetermined angle from the cam cable winding part 210 about the pivot point A at a position spaced a predetermined distance from the rotation shaft 101 of the pulley 110 to be coupled. It is coupled to the elongated arcuate portion 222 and the elongated arcuate portion 222 is formed in the elongated arcuate portion 222 is formed to extend close to the rotating shaft 101 is made of a steep inclined portion 223. In addition, on the outer circumferential surface of the curved portion 222 and the steep inclined portion 223 is formed a winding groove in which the cam cables 150a and 150b are wound. Accordingly, as the bow string 140 is pulled, the cam module 220 rotates together with the pulley 110 so that the cam cables 150a and 150b are bent at the cam module 220 adjacent to the cam cable winding 210. 222 and the steep slope 223 are sequentially wound.

The fixing means rotates the cam module 220 by a predetermined angle about the pivot point A and fixes the cam module 220 to the pulley 110 in the rotated position. For this purpose, the cam module 220 has a pivot point A. An arc-shaped position adjusting hole 230 having a center is formed, and a coupling hole is formed in the pulley 110 to which the cam module 220 is coupled. Therefore, the cam module 220 is rotated by a predetermined angle about the pivot point A, and the coupling member 115 is coupled to the coupling hole formed in the pulley 110 at a predetermined position of the positioning hole 230 and the cam. Module 220 is fixed to pulley 110. The bolt is inserted into the position adjusting hole 230 and then screwed into the coupling hole formed in the pulley 110 to fix the cam module 220 to the pulley 110. [ In addition, as the fixing means, the pulley 110 is similarly formed with an arc-shaped coupling hole 116 centered on the pivot point A, and the cam module 220 has a bolt (bolt) in a bolt hole formed at a predetermined position. 117 is coupled, the bolt 117 is passed through the circular arc-shaped coupling hole 116 formed in the pulley 110, the nut is coupled to one end of the bolt 117 additionally pulls the cam module 220 (110) It is fixed to).

In addition, around the position adjusting hole 230 is formed a position display portion indicated by a number to indicate the position where the cam module 220 is fixed. Each cam module 220 coupled to the upper and lower pulleys 110 should have the same rotation angle, but the position display part is indicated by numbers so as to know the rotation angle of one cam module 220. The location indicator may be made of alphabetic characters instead of numbers.

In the present invention, the cam module 220 may adjust the pulling length of the bowstring 140 by having such a configuration, and the cam module 220 of the upper and lower pulley assemblies 107 and 108 may have the same pivot point A. When the cam module 220 is rotated by the same angle from the cam cable winding unit 210 and the cam module 220 is fixed to the pulley 110 again in the rotated position, the cam cable 150 of the cam module 220 is The length of the winding in the elongated portion 222 is increased, and the length of the cam cable 150 is wound from the cam cable winding portion 210 to the cam module 220 until the let-off state is increased, and thus the pulling length is increased. will be.

The bow string 140 is wound around the guide grooves of the pulleys 110 of the pulley assemblies 107 and 108 so that both ends are coupled to the fixing protrusion 111 formed at each pulley 110.

The first and second cam cables (cam cables, 150a and 150b) are formed between the pair of wings 103 of the bow body 100 and formed on each pulley 110 as the bowstring 140 is pulled. Being wound on the cam 200, each cam cable (150a, 150b) is coupled to the fixing projection 113, one end of which is formed on the pulley 110 of each pulley assembly (107, 108) and the rotating shaft 101 The other end of the cam cables 150a and 150b is fixed to the fixing protrusion 112 of the opposite pulley 110 by being wound around the rotating wheel 120 which is rotatably coupled to the rotating wheel 120. do. Accordingly, as the bow string 140 is pulled, the bow string 140 is wound around the cam 200 coupled to the opposite pulley 110.

The rotating wheel 120 has a through hole in which the rotating shaft 101 of the pulley 110 is coupled at the center thereof, and the other side of each pulley 110, that is, the opposite side of one side of the pulley 110 to which the cam 200 is coupled. The other side is coupled to the rotation shaft 101 of the pulley 110, the rotation shaft 101 of the pulley 110 is rotatably coupled to the pulley 110 separately. In addition, on the outer circumferential surface of the circular rotating wheel 120 is formed a winding groove for winding the cam cable (150a, 150b) is wound so that the cam cable (150a, 150b) is wound on the rotary wheel 120, then cam cable (150a, 150b) One end of the) is coupled to the fixing protrusion 113 formed in the pulley 110 in the vicinity of the rotary wheel (120). As the cam cables 150a and 150b are wound around the cam 200 of the opposite pulley 110 by pulling the bow string 140, portions of the cam cables 150a and 150b that are wound around the rotary wheel 120 rotate. When the wheel 120 is released from the wheel 120, the rotary wheel 120 is rotatably coupled to the rotary shaft 101 separately from the pulley 110, thereby reducing the friction between the cam cable 150 and the rotary wheel 120. The force pulling the string 140 is reduced.

As shown in FIGS. 4 and 5, the indicator 400 includes a second cam as the bow string 140 is pulled in the guide hole 403 formed in the pulley 110 of the upper pulley assembly 107. To move in contact with the cable 150b, the indicator 400 is a contact projection 410 is coupled to each other by two coupling members having a predetermined length along the guide hole 403, respectively on both sides of the guide hole (403) And a support 420. One of the two coupling members is a bolt 430 for detachably coupling the contact protrusion 410 and the support 420, and the other is spaced apart from the bolt 430 along the guide hole 403. A coupling pin 421 is formed on the 420. Accordingly, the contact protrusion 410 is formed with a bolt hole 411 and a pin hole 412 for coupling the bolt 430 and the coupling pin 421 are spaced at regular intervals along the guide hole 403, the bolt ( A female thread is formed in the bolt hole 411 to which the 430 is coupled. In addition, the support part 420 is provided with a coupling pin 421 to be inserted into the pin hole 412 of the contact protrusion 410, the bolt hole 422 is coupled to the bolt 430 at a position spaced apart from the coupling pin 421 ) Is formed.

The reason why the contact protrusion 410 and the support 420 of the indicator 400 is coupled by two coupling members in the present invention is that when the two are coupled by one coupling member, the second cam cable is connected to the contact protrusion 410. Due to the distance between the contact portion 150b and the guide hole 403, a coupling member such as a bolt may be inclined, and thus, the indicator 400 may not move smoothly in the guide hole 403. In the present invention, the contact protrusion 410 and the support 420 of the indicator 400 is coupled by two coupling members spaced apart at regular intervals along the guide hole 403, so that the indicator 400 is the second cam cable 150b. You can move smoothly when you touch.

In addition, a contact rubber pad 440 is provided between the contact protrusion 410 and the support 420 of the indicator 400 to be inserted into the guide hole 403 to contact the inner circumferential surface of the guide hole 403. As shown in FIG. 5, the contact rubber pad 440 is sandwiched between two coupling members, the bolt 430 and the coupling pin 421, in the guide hole 403, so that the indicator 400 has a second cam cable ( Before contact with 150b) to maintain the original position in the guide hole 403 and to contact the second cam cable (150b) serves to smoothly move the indicator 400 in the guide hole (403).

The guide hole 403 to which the indicator 400 is coupled is formed at a position corresponding to each other with the coupling hole 503 of the lower pulley 110 in the upper pulley 110, and has an arc shape centering on the rotation shaft 101. Is done.

The indicator 400 is pulley 110 while maintaining the position where the indicator 400 is coupled in the guide hole 403 at the beginning when the bow string 140 is pulled as shown in Figs. When the contact protrusion 410 is rotated together with the second cam cable 150b and the pulley 110 continues to rotate, the contact protrusion 410 is pushed against the second cam cable 150b by the guide hole 403. It will move within. Thus, the indicator 400 is coupled to the guide hole 403 to a strength that can be moved in contact with the second cam cable 150b. In addition, the position display unit 404 is formed around the guide hole 403 to indicate the movement position of the indicator 400 in the guide hole 403. The location display unit 404 is composed of a plurality of lines and numbers spaced at regular intervals, similar to the location display unit 504 around the coupling hole 503, but may be composed of alphabet letters instead of numbers.

The contact pin 500 has an arc-shaped predetermined length as shown in FIG. 7 at any position of the coupling hole 503 formed in the pulley 110 of the lower pulley assembly 108 (at the let-off state). The contact pin 500 is coupled to the first cam cable 150a), and when the bowstring 140 is pulled, that is, when the let-off state (arrow firing state) occurs, the first cam cable In contact with 150a. In addition, the contact pin 500 is made of a contact protrusion and a support portion that is in contact with the cam cable 150a, like the indicator 400, and is coupled to each other detachably by bolts 530 at both sides of the coupling hole 503. do. Since the contact protrusion and the support of the contact pin 500 are similar to the indicator 400 described above, detailed description thereof will be omitted.

As described above, in the present invention, the cam modules 220 of the pulley assemblies 107 and 108 are equally rotated from the cam cable winding part 210 about the pivot point A to adjust the pulling length. In this case, since the rotation angle of each pulley 110 is changed in the let-off state according to the movement of the cam module 220, the position of the contact pin 500 is moved accordingly. At this time, by releasing the bolt 530 for coupling the contact pin 500 to the coupling hole 503, the contact pin 503 is released within the coupling hole 503 in a state where the fixing of the contact pin 500 is released. After moving to the position it is fixed to the contact pin 500 is coupled to the coupling hole 503 again. The coupling hole 503 to which the contact pin 500 is moved is formed in an arc shape around the rotating shaft 101, and is positioned around the coupling hole 503 to distinguish the position at which the contact pin 500 is coupled. The display unit 504 is formed. In the present embodiment, the position display unit 504 is composed of a plurality of lines and numbers spaced apart at regular intervals, but may be composed of alphabet letters instead of numbers.

Hereinafter, the operation of the compound bow according to the preferred embodiment of the present invention will be described.

As shown in FIGS. 3 and 4, before the bow string 140 is pulled, the contact pin 500 in the lower pulley assembly 108 is in the let-off state according to the position of the cam module 220. ) Is fixedly coupled to the coupling hole 503 at a position in contact with it. In the upper pulley assembly 107, the indicator 400 is disposed such that the contact protrusion 410 is positioned at one end of the guide hole 403 (the front end side in the direction in which the pulley rotates). When the bow string 140 is pulled in this state, the contact protrusion 410 is rotated together with the rotation of the pulley 110 while the position of the contact protrusion 410 in the guide hole 403 is maintained, and the contact protrusion 410 is the second cam. As the pulley 110 continues to rotate when the cable 150b is in contact, the contact protrusion 410 is pushed by the second cam cable 150b to move in the guide hole 403.

At the same time, the contact pin 500 formed on the lower pulley assembly is fixedly coupled in the coupling hole 503 to rotate together with the pulley 110 while maintaining its position, and the first cam cable 150a in the let-off state. Will come in contact with

The bow state when the bowstring 140 is pulled in this way, that is, when the bow string is in a let-off state capable of firing an arrow, is illustrated in FIGS. 6 and 7. FIG. 7 is a view of the compound bow when the bowstring 140 is pulled when the rotation angles of the cams 200 of the upper and lower pulley assemblies 107 and 108 are the same. In this case, the indicator 400 is moved. Is coincided with the position corresponding to the contact pin 500. The indicator 400 is formed to be moved in the guide hole 403 only by the contact of the cam cable 150b, so that the indicator 400 maintains the same position even after releasing the bow string 140 so that the bow user 140 may move the bow string 140. After releasing, the position of the indicator 400 in the guide hole 403 is moved to confirm that the position of the contact pin 500 coincides with the rotation angle of the upper and lower cams 200. .

However, the angle of rotation of the upper and lower cams 200 until the let-off state may vary due to the difference in the strength of the blades, and the rotation angle of the cam 200 coupled to the upper pulley assembly 107 may be lower than the lower pulley assembly ( When larger than the cam 200 coupled to the 108, the rotation angle of the cam 200 coupled to the upper pulley assembly 107 becomes larger, so that the contact protrusion 410 of the indicator 400 is also guide hole 403. Will move more within. Accordingly, the rotational angle of the cam 200 coupled to the upper pulley assembly 107 by confirming that the moving position of the indicator 400 moves more than the position of the contact pin 500 is lower than the lower pulley assembly ( Larger than the cam 200 of the 108 can be confirmed. In this case, by reducing the length of the cam cable 150a wound on the cam 200 of the upper pulley assembly 107, it is possible to reduce the rotation angle of the cam and thus to equally match the rotation angles of the upper and lower cams. .

On the contrary, when the rotation angle of the cam 200 coupled to the upper pulley assembly 107 is smaller than the cam 200 coupled to the lower pulley assembly 108, the contact protrusion 410 of the indicator 400 is used. It is also moved smaller in the guide hole (403). Therefore, the rotational angle of the cam 200 coupled to the upper pulley assembly 107 by the user confirming that the movement distance of the indicator 400 is moved smaller than the position of the contact pin 500 is determined by the lower pulley assembly ( It can be seen that it is smaller than the cam 200 of 108. In this case, the rotation angle of the cam 200 can be increased by increasing the length of the cam cable 150a wound on the cam 200 of the upper pulley assembly 107. Accordingly, the rotation angles of the upper and lower cams 200 are increased. Can be set equally.

As described above, even when the rotation angles of the upper and lower cams 200 are changed, they can be easily checked by themselves, and thus the rotation angles of the cams 200 can be equally adjusted by adjusting the length of the cam cable 150a.

Meanwhile, FIG. 8 illustrates another form of the coupling hole 603 to which the contact pins 602 are coupled. In FIG. 8, the coupling hole 603 is formed of a plurality of coupling holes formed at regular intervals, unlike the above-described embodiment. The contact pin 602 is coupled to one of the coupling holes 603.

Determination of the coupling hole 603 to which the contact pin 602 is coupled depends on the position where the cam module 220 is moved from the cam cable winding 210 as in the previous embodiment, and the position where the cam module 220 is changed. In the let-off state by selecting the coupling hole 603 that the contact pin 602 can contact the first cam cable 150a to couple the contact pin 602. Other configurations and effects are the same as in the previous embodiment.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be readily understood.

100: Bow main body 101:
102: handle 103: wing
110: pulley 111: fixing projection
140: bow string 150a, 150b: cam cable
200: cam 210: cam cable winding part
220: cam module 400: indicator
410: contact protrusion 420: support
403: guide hole 500: contact pin
503: combined holes

Claims (9)

A bow body having a grip portion formed at the center, and a pair of wings coupled to both ends of the handle,
An upper and lower pulley assembly including a pulley rotatably coupled to a rotation shaft formed at a rear end of each wing, and a cam coupled to one side of each pulley to rotate together with the pulley;
Bow strings, both ends of which are wound around each pulley of the upper and lower pulley assemblies,
One end is coupled to each of the pulley assemblies, the other end is coupled to the opposite pulley assembly and comprises a first and second cam cable wound around the cam of each pulley assembly as the bowstring is pulled,
One pulley assembly is formed with a contact pin is coupled to the coupling hole formed in the pulley to contact the first cam cable when the bowstring is pulled,
Another pulley assembly is provided with an indicator that moves in contact with the second cam cable as the bowstring is pulled in the guide hole formed in the pulley,
The indicator is made of a contact projection and the support portion coupled to each other on both sides of the guide hole, the contact projection and the support portion is self-tuning, characterized in that coupled by two coupling members spaced apart at regular intervals along the guide hole Compound bow available. The method of claim 1,
One of the two coupling members is a self-tunable compound bow, characterized in that the bolt for detachably coupling the contact protrusion and the support. 3. The method of claim 2,
The other one of the two coupling members is a coupling pin formed in the support portion, the coupling pin is a self-tunable compound bow that is inserted into the insertion hole formed in the contact projection. The method of claim 1,
A self-tuning compound is provided between the contact protrusion and the support of the indicator to provide a contact rubber pad in contact with the guide hole to maintain the original position in the guide hole before the indicator contacts the second cam cable. bow. The method of claim 1,
And a position display portion formed around the guide hole to indicate a position at which the indicator moves in contact with the second cam cable. The method of claim 1,
The coupling hole has a predetermined length and the contact pin is a self-tunable compound bow coupled to any position in the coupling hole. The method of claim 1,
A plurality of coupling holes are formed, the compound bow capable of self-tuning the contact pin is coupled to one of the coupling holes. The method of claim 1,
The cam of each pulley assembly is made of an arc shape and the cam cable wound around the cam cable wound;
The cam cable is rotatably coupled to the cam cable winding part by a predetermined angle around the pivot point at a position spaced a predetermined distance from the rotation axis of the pulley to which the cam is coupled, and as the bow string is pulled, the cam cable is wound on the cam cable winding part. A cam module that is wound up and wound around the outer circumference sequentially,
Self-tuning comprising the fixing means for rotating the cam module at an angle with respect to the pivot point and fixing it to the pulley in the rotated position to adjust the pull-off length of the compound bow. Compound bow available. 9. The method of claim 8,
As a fixing means for fixing the cam module to the pulley, the cam module is formed with an arc-shaped position adjusting hole centering on the pivot point of the cam module, and a coupling hole is formed at the pulley to which the cam module is coupled to the position adjusting hole and the Self-tuning compound bow, characterized in that the coupling member is coupled to the coupling hole is fixed to the pulley cam module.

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