DE8812113U1 - Arrow system on a bow - Google Patents

Description

Arrow system on a bow

The invention relates to an arrow rest on a bow, which consists of a support pin that can be adjusted to a basic position transversely to the central axis of an arrow.

In the case of bows that are designed as sports equipment, the arrow is placed on an arrow rest for support and on the side of an arrow system, the so-called button, when preparing to shoot, so that it is guided precisely and aligned with the sighting device thanks to the two-point system. Due to the fletching of the arrow, a collision with the arrow rest occurs. For this reason, well-designed bows are equipped with an arrow rest that deflects.

As a result of the extremely high force that acts on the arrow when it is fired to accelerate it lengthwise, the arrow bends immediately after firing, causing the arrow to take up more space than is allocated to it by the initial position of the arrow rest and arrow system. An evasive arrow system is therefore also useful.

It is therefore the object of the invention to improve an arrow system of the type mentioned at the beginning so that the oscillations inherent in the arrow in the event of a collision with

the arrow system causes virtually no change in the direction of the arrow.

To solve this problem, the invention proposes that the contact pin is slidably mounted within a housing and is held elastically in the basic position by means of a spring and that the position of the abutment of the spring is adjustable in the spring direction.

The arrow system according to the invention is therefore able to deflect in a spring-like manner, whereby the hardness of the spring can be adjusted by changing the preload. Of course, the spring itself can also be replaced so that different spring characteristics can be taken into account. If it turns out that after the compression movement the support pin rebounds again while the arrow is still in the area of the arrow system, the movement of the support pin can also be dampened, whereby various means are available.

On the one hand, the mass of the support pin can be changed by means of ballast bodies, so that a delay in movement is brought about, particularly in the case of rapid changes in speed. On the other hand, friction or hydraulic damping can be provided in addition or independently of this. Hydraulic damping is particularly advantageous in an arrow system according to the invention because it enables particularly precise, repeatable damping processes to be achieved, which allow repeatable accuracy.

A wide variety of concepts are possible. On the one hand, it can be provided that the support pin springs in without damping, so that the arrow is given the space it requires during the acceleration phase. So that the rebound movement does not influence the flight path, the rebound movement is dampened. If

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However, if it turns out that the arrow cannot be given such leeway, but that guidance must be maintained for a longer period, both the inward and outward movements can be dampened, so that long-lasting guidance is combined with keeping the extended flight path clear. If guidance is to be restored as soon as possible after a deflection of the arrow system, only the inward movement of the arrow system is dampened, while the outward movement to the basic position is undamped. The measure of increasing the mass of the support pin described above is most comparable in its characteristics to dampening the inward and outward movements.

Details of hydraulic damping and advantageous further developments of the invention are presented below in connection with the explanation of an embodiment of the invention. The embodiment is shown in the drawing. The figures of the drawing show:

Figure 1 is a side view of an arrow rest according to the invention in the installed state,

Figure 2 is a cross-sectional view through a

first embodiment of the invention and

Figure 3 is a cross-sectional view of another

Embodiment of the invention.

Figure 1 shows a diagram of a bow 1 into which an arrow system is screwed. The actual system is on the front face of a support pin 2f which is slidably mounted in its housing 3. The housing 3 has a thread on its outside,

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which serves both for screwing into the bend 1 and for receiving a threaded sleeve 4 and a screw cap 5. The threaded sleeve 4 and the screw cap 5 can be fixed at any point relative to the housing 3 using clamping screws 6.

The threaded sleeve 4 is used to adjust the basic position of the support pin 2. The basic position of the support pin 2 is set by screwing the housing 3 into the internal thread of the bow 1 to different depths. After the desired position, which depends on the arrow diameter, among other things, has been found, the threaded sleeve 4 is screwed against the bow and fixed using the clamping screw 6. In this position, the entire arrow system can be unscrewed from the bow 1 and later screwed back in while maintaining the basic position. Adjusting the screw cap 5 relative to the housing 3 causes a displacement of the abutment of a spring 7, which indirectly rests against the support pin 2. The springs 7 enable the compression movement of the support pin 2. Screwing the screw cap 5 in to different depths therefore causes an adjustment of the spring hardness.

In Figure 2, a guide tube 9 is shown inside the housing 3, in which the contact point between the spring 7 and the contact pin 2 is located. It can be clearly seen that there is enough space within the guide tube 9 to accommodate ball bodies (not shown) that are screwed onto the extended contact pin 2 in order to increase its mass. The ballast bodies can be solid steel bodies or tubular structures with a lead filling or the like.

Figure 3 shows a hydraulically dampened arrow rest according to the invention. It can be clearly seen that instead of the guide tube 9, a damper housing 10 is used, which otherwise has the same external shape

In this way, the arrow system can be converted or retrofitted at any time. To do this, first loosen the clamping screw 6, then remove the screw cap 5 and remove the spring 7. Then, a clip 8 is removed from the housing 3 by reducing its circumference, whereby the guide tube 9 or the damper housing 10 can be removed. Any component can then be inserted or replaced, after which it is fixed again using the clip 8. After inserting the spring 7, the screw cap 5 is put back on and fixed in the desired position using the clamping screw 6.

Inside the damper housing 10 there is a piston 12 associated with the contact pin 2 and another piston 13 associated with the spring 7, which are hydraulically connected to one another in the area of an intermediate wall by means of a throttle 14. The lower free end of the damper housing 10 is closed with the aid of a plug 11 after the unit consisting of the contact pin 2 and the piston 12 has been inserted. The piston 13 facing the spring 7 has a central passage which can be closed with the aid of a ball 15 and a screw plug 16; the cylindrical spaces facing the throttle 14 are filled with hydraulic fluid via this channel. The seals which close off the hydraulic spaces in front of the pistons 12 and 13 are indicated by means of arrows.

As soon as a force acting in the longitudinal direction acts on the contact pin 2, the piston 12 is displaced in the direction of the throttle 14, which opposes this displacement with a certain resistance due to the narrow section.

The amount of hydraulic fluid passing through the throttle 14 pushes the piston 13 against the action of the valve 7 in the direction of displacement, so that there is a dampened, springy inward movement of the contact pin

2 comes. When the force on the contact pin 2 decreases or disappears, the restoring force of the spring 7 prevails, which in turn is dampened. The volume displaced by the piston 13 must pass through the throttle 14 in order to reach the space in front of the piston 12. The end of the movement is determined by the collar in the lower area of the contact pin 2.

Again, the hardness of the spring can be adjusted by adjusting the screw cap 5. Of course, the spring in this example can also be completely replaced, so that a softer or harder spring can be used.

Figure 1 shows that the non-knurled, cylindrical section of the screw cap 5 is provided with markings. These serve as a guide to the preload setting. Since the marking is on the threaded sleeve 4, it must be noted that an adjustment of the basic setting also results in a change in the display of the preload force. This must be taken into account when making adjustments. Furthermore, it is not difficult to shorten the threaded sleeve 4 and the screw cap to such an extent that the markings can be observed in relation to the housing 3.

Claims (9)

Protection claims 1. Arrow rest on a bow, consisting of a support pin which can be adjusted to a basic position transversely to the central axis of an arrow, characterized in that the support pin (2) is slidably mounted within a housing (3) and is held elastically in the basic position by means of a spring (7), and that the position of the abutment of the spring (7) is adjustable in the spring direction. 2. Arrow system according to claim 1, characterized in that the mass of the support pin (2) can be changed by placing ballast bodies. 3. Arrow system according to claim 1 or 2, characterized in that the inward movement and/or outward movement can be dampened with the aid of a damper. 4. Arrow system according to claim 3, characterized in that the damper is a hydraulic damper. $1 5. Arrow system according to claim 4, characterized in that % characterized in that the housing (10) has two £ a throttle (14) separate cylindrical spaces which each enclose a piston (12, 13), and that on one piston (12) the contact pin ■Γ (2) and on the other piston (13) the spring (7) is present. 6. Arrow system according to claim 5, characterized in that in addition to the throttle (14) a further throttle is provided, and that a check valve is arranged in front of one throttle and behind the other throttle. 7. Arrow system according to claim 5 or 6, characterized in that the piston (13) facing the spring (7) is provided with a closable opening for filling the cylindrical spaces. 20 8. Arrow system according to one of the preceding claims, characterized in that the housing (3) is provided over its entire length with an external thread on which a threaded sleeve (4) as a stop for adjusting the basic position and j a screw cap (5) for adjusting the resistance u bearing position of the spring (7) can be fixed in each case. ; 9. Arrow system according to claim 8, characterized in that g e k e &eegr;&eegr; - that the screw cap (5) and the threaded sleeve (4) overlap. 35