KR101551754B1 - Apparatus for arrow - Google Patents

Abstract

A notch of an arrow according to an embodiment of the present invention comprises a notch body having an installation space inside; a substrate arranged inside the installation space; a light emitter connected to the substrate, and emitting light; and a first sensor connected to the substrate, and sensing acceleration of an arrow, wherein the substrate includes a control part connected to the light emitter and the first sensor to allow the light emitter to emit light depending on a signal detected in the first sensor.

Description

Arrow device {APPARATUS FOR ARROW}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an arrow pattern having an illuminant and a wireless signal generator, and more particularly, it is possible to enjoy a leisure sport using an arrow equipped with a light emitter at a crossbow or the like, It is about arrows that can be easily recovered by tracking radio signals even if the fired arrows are obstructed by fallen leaves, vegetation, or obstacles.

The arrow is for shoots of string, bow, crossbow, archery, archery, etc. It consists of a shaft, a pile, a fletching and a nock. An arrowhead is mounted at the front end of the shaft, and a stem is mounted at the end of the shaft to hold the protest of the bow or crossbow.

In general, arrows that leave the protagonist of the crossbow are drawn toward the target by a parabola. At this time, the arrows swing back and forth around the center of gravity. That is, an arrow does not fly straight to the target, but the fish swirls like a swim. This phenomenon is called the paradox effect, which causes the collar of the arrow to fly straight by the air resistance.

In addition, the arrows fly while rotating by the air resistance on the feathers of the arrows, and the rotating arrows fly more steadily than the non-rotating arrows. That is, the arrow is stably moved by giving a slight pitch to the direction of the collar attached to the shaft, and this effect is called a gyro effect.

The above arrow is fired forward by the elastic force of the bow when the protest is pulled and pulled by the protest of the bow, so the arrow is aimed at the target or the target which is only a distance away. The archery, which has the meaning of archery, is a bow used by people from other regions, but it is called archery to distinguish it from Korea 's national archery, archery. The archery is similar to the origins of the old Korean ancestors used by the ancient ancestors, but it is characterized by its usage style and shape according to the culture and customs of the people of the world, and it can be classified into Mediterranean style, Mongolian style, and marine style.

Recently, people are enjoying leisure activities by searching for archery, archery, and archery, and training their physical strength. At night, people who shoot bows in archery, national archery, and crossbow fields can be overlooked. However, it is very expensive to install special lighting because it requires a very bright light for shooting the bow at night, and even if it is installed, it can not be used unless it is a special competition in terms of energy conservation .

Therefore, when a small number of people are sprayed, or when they are sprayed outdoors rather than in archery or crosswalk, they launch an invisible arrow, so there is a danger of safety accidents and difficulty in collecting the arrows. There is a problem that it can not be performed. Also, if the arrow fired in the daytime is obstructed by fallen leaves, vegetation, or other obstacles and is difficult to be detected, it is easier to find the arrow by using the pulse of the radio pulse generator to track it.

Korean Patent Publication No. 10-2011-0077088. July 7, 2011.

It is an object of the present invention to provide an arrow pattern which can be sprayed outdoors or at night.

It is another object of the present invention to provide an arrow pattern that allows a user to easily collect a humidified arrow.

Other objects of the present invention will become more apparent from the following detailed description and drawings.

According to an embodiment of the present invention, the arrow pattern can be detachably attached to the rear end of the arrow, and includes a pattern body in which an installation space is formed; A substrate disposed in the installation space; A light emitting body connected to the substrate, the light emitting body being capable of emitting light; And a first sensor connected to the substrate and sensing the acceleration of the arrow, wherein the substrate is connected to the illuminant and the first sensor and emits the illuminant according to a signal sensed by the first sensor Respectively.

The control unit may flicker the light emitting unit at a predetermined first period when the acceleration of the first sensor reaches a preset threshold value or more.

The controller may flicker the illuminant at a predetermined second period when the acceleration of the first sensor becomes 0 at a negative value, and the second period may have a blink period longer than the first period.

Wherein the arrow pattern further comprises a radio pulse generator connected to the substrate to generate a radio pulse and connected to the controller, wherein when the acceleration of the first sensor is negative, The current can be applied to the radio pulse generating section.

The controller may cut off the current applied to the light emitting unit when the acceleration of the first sensor is switched twice or more with positive and negative values within the set T ₁ time.

When the current applied to the light emitting unit is interrupted and the acceleration of the first sensor is switched to a positive value and a negative value at least two times within a preset T ₂ time, a current is applied to the light emitting unit .

The arrow pattern may further include a wireless pulse generator connected to the substrate to generate a wireless pulse.

Wherein the control unit interrupts the current applied to the light emitting unit and the wireless pulse generator when the acceleration of the first sensor is switched between a positive value and a negative value twice or more within a predetermined time T ₁ , When the acceleration of the first sensor is switched between positive and negative values within a predetermined time T ₂ in a state in which the applied current is blocked, the current can be applied to the illuminant and the radio pulse generator have.

The patterned body may include a rechargeable battery that supplies current to the substrate and the light emitting body, and the rechargeable battery may be a rechargeable secondary battery.

The patterned body may further include a mounting groove recessed from a rear end thereof to receive a bowstep.

According to an embodiment of the present invention, leisure sports such as a crossbow can be enjoyed in a state in which the night view or the view of the smog is limited through the illuminant provided on the arrow pattern provided at the rear end of the arrow. In addition, the controller mounted on the arrow pattern can be connected to the acceleration sensor and the light emitting body to easily control the light emitting body, thereby maximizing the economy and efficiency of the arrow pattern.

1 is a view showing a general crossbow.
Fig. 2 is a view showing a crossbow arrow shown in Fig. 1. Fig.
3 is a view schematically showing an arrow pattern according to an embodiment of the present invention.
4 is a side view of the arrow pattern shown in Fig.
FIG. 5 is a diagram showing the blinking period of the illuminant and the operating state of the wireless pulse generator according to the speed of the acceleration sensor shown in FIG.
6 is a schematic diagram of a charging and detecting device according to an embodiment of the present invention.
FIG. 7 is a view illustrating a connection state of the controller shown in FIG. 6. FIG.

In order to facilitate understanding of the present invention, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described below will be described on the basis of the embodiments best suited to understand the technical characteristics of the present invention and the technical features of the present invention are not limited by the embodiments described, Illustrate that the present invention may be implemented as embodiments.

Therefore, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. In order to facilitate the understanding of the embodiments described below, in the reference numerals shown in the accompanying drawings, among the constituent elements that perform the same function in the respective embodiments, the related constituent elements are indicated by the same or an extension line number.

On the other hand, in the embodiment, it is described that the arrow pattern is connected to the arrow for crossbow, but not only the article that can be blown by a string or a string such as an archery or an archery but also a thing which can be blown by a machine or a human hand For example, a dart, etc.). Also, the charging and detecting device is not limited to the arrow for a crossbow, and may be used in a charging device for charging a battery including a wireless pulse generating part.

Fig. 1 is a view showing a general crossbow, and Fig. 2 is a view showing a crossbow arrow shown in Fig. As shown in Figs. 1 and 2, the crossbow 1 has a crossbow body 5 having a trigger means 2 made of a trigger 2 for mounting and launching an arrow 10, and a front end side And a rim member 9 including a rim 7 and a ramp 8 mounted through a mounting groove 6 provided in the rim member 7. The arrow 10 pulled backward by the pulling of the bow string 8 causes the arrow 10 to fly by the elastic force of the bow 8 released from the latch 4 by pulling the trigger 2 .

In the state where the crossbow arrow 10 is made up of the rod-shaped shaft 15 having a predetermined length, a plurality of blades 17 for stable flight of the arrow are formed on the outer circumferential surface on the rear side, And an arrowhead 13 to be seated on the target can be provided. An arrow pattern 100 is formed at the rear end of the shaft 15 in which a mounting groove 19 for locking the protrusion of the crossbow 1 (or the bow) is formed.

FIG. 3 is a view schematically showing an arrow pattern according to an embodiment of the present invention, and FIG. 4 is a side view of the arrow pattern shown in FIG. As shown in FIGS. 3 and 4, the arrow pattern 100 includes a patterned body, and the patterned body is connected to the rear of the body with a body 30 insertable into the rear end of the shaft 15, And a blade (40) formed with a mounting groove (19) for protruding. The body 30 may include a first battery 35 and the first battery 35 may be a secondary battery such as a rechargeable lithium polymer battery. Also, the body 30 may be formed of the first battery 35 itself.

An installation space 42 may be formed in the blade 40, and a substrate may be mounted in the installation space 42. The first sensor 60 and the pulse generator 70 are connected to the substrate 50. The first sensor 60 and the pulse generator 70 are connected to the first battery 60 35). The light emitting unit 80 may be connected to the substrate 50. For example, the light emitting unit 80 may be a light emitting diode (LED) disposed behind the substrate 50. [

The light emitting diode has a small number of carriers (electrons or holes) injected using a pn junction structure of a semiconductor, and emits light by recombination thereof. The light emitting diode has a small size and a long lifetime as compared with a conventional light source, Electrical energy is converted directly into light energy, so it is less power and more efficient. A part or all of the wings may be a translucent or transparent material so that the light of the light emitting body 80 located in the installation space 42 can be transmitted. Meanwhile, although the first sensor 60 is described as an acceleration sensor in the present embodiment, it may be replaced with another position sensor.

The substrate 50 may be connected to a one-chip microprocessor 90. The one-chip microprocessor 90 may turn on the light emitter 80 through an electrical signal applied from the acceleration sensor 60. [ The one-chip microprocessor 90 can be provided with functions such as a CPU, a RAM, a ROM, a timer, and an A / D in a single IC, and the peripheral components can be simplified and reduced in size and weight.

For example, the acceleration sensor 60 may be a gyro sensor, and the gyro sensor is a sensor that detects the angular velocity (how many times the sensor moves in one second). When a gyro sensor rotates (at a certain speed) an object is rotating, it acts perpendicular to the velocity direction, "Coriolis force" (the inertial force that appears when an object moves in a rotational coordinate system, And the magnitude of the force proportional to the velocity) work. The output format of the gyro may be an analog signal, and the analog signal may be converted into a digital signal using an AD converter, and processed by the one-chip microprocessor 90. The acceleration sensor 60 may be replaced with an inertia type, a silicon semiconductor type or the like depending on the detection method.

The wireless pulse generator 70 is an electronic circuit that generates various pulses for examining a response of a circuit element such as an electronic circuit or a transistor or for testing a logic circuit. ) Has a built-in device for generating a pulse, that is, a high frequency of a shock wave.

FIG. 5 is a diagram showing the blinking period of the illuminant and the operating state of the wireless pulse generator according to the speed of the acceleration sensor shown in FIG. 5, when the arrow 10 is detached from the crossbow 1 and the arrow 10 is in the slide state, the arrow 10 leaving the bowstep has an increased state of acceleration for a certain period of time, And finally reaches the stop state.

When the acceleration sensor 60 has a positive value, the one-chip microprocessor 90 blinks the light emitter 80 in the first period, and when the acceleration sensor has a negative value of 0, Flashes periodically. The first period may have a light emission period shorter than the second period. Accordingly, the user can accurately recognize the flying state of the arrow 10 and can easily find the position of the stopped arrow 10. Also, in the stopped state, the arrow pattern 100 has a longer light emitting period than the first period, so that the power of the first battery 35 provided in the arrow pattern 100 can be minimized and used for a long time.

Meanwhile, when the light emitter 80 is switched from the second period (the acceleration sensor is negative to zero), the one-chip microprocessor 90 can generate a radio pulse by applying a current to the radio pulse generator 70 . Therefore, it is possible to easily find the arrow 10 and the arrow pattern 100 that are in the stopped state by using the antenna (250 in FIG. 6) provided in the charging and detecting apparatus 200 (FIG. 6) described later.

In addition, the one-chip microprocessor 90 can cut off the current applied to the light emitter 80 when the acceleration of the acceleration sensor 60 is switched twice or more with positive and negative values. For example, if the arrow 100 is swung vertically or horizontally after the user finds the arrow 10 in a stopped state, the acceleration of the acceleration sensor 60 is set to a positive value and a negative value of 2 The light emitting unit 80 is turned off. In addition, the one-chip microprocessor 90 turns off the light emitting unit 80 and interrupts the current applied to the wireless pulse generating unit 70 to stop the wireless pulse.

In addition, when the acceleration of the acceleration sensor 60 is switched between a positive value and a negative value two or more times in a state in which the luminous body 80 is turned off, the one-chip microprocessor 90 applies a current to the luminous body 80 So that the light emitting body 80 can be switched to the lighting state. On the other hand, when the acceleration of the acceleration sensor 60 is switched between a positive value and a negative value twice or more in a state in which the luminous body 80 is turned off, the one-chip microprocessor 90 switches the luminous body 80 to the first cycle It is possible.

FIG. 6 is a schematic view of a charging and detecting apparatus according to an embodiment of the present invention, and FIG. 7 is a view illustrating a connection state of the controller provided in FIG. 6 and 7, the charging and detecting apparatus 200 includes a charging body 230 having an internal space 210 and having a plurality of holders 220 for charging an arrow pattern 100 on an upper surface thereof, And an antenna 250 installed at one side of the inner space 210 and capable of receiving a radio pulse generated from a radio pulse generator included in an arrow pattern.

The holder 220 is recessed from the upper surface of the charging body 230, and the arrow pattern 100 is inserted to fill the arrow pattern 100. The holder 220 may have a connection terminal 225 exposed to the outside so as to be electrically connected to the first battery 35 of the arrow pattern 100. When the first battery 35 is charged, The first battery 35 can be charged by keeping the first battery 35 and the connection terminal 225 of the holder 220 connected to each other and maintaining the electrically connected state.

Antenna 250 may be a miniaturized directional antenna with a ceramic substrate having at least one resonant printed wiring structure and may be an electrical or electronic component such as SMD - Surface Mounted Devices) mounted on the surface of a printed circuit board. Alternatively, the antenna may be replaced by an external monopolar antenna, or an internal planar inverted F antenna (PIFA) on a dielectric substrate, and the antenna 250 may be replaced with another Sensors.

The second battery 240 is mounted on the inner space 210 and the alarm device 260 is installed on one side of the holder 220 to provide an alarm to the user. The second battery 240 can supply current to the holder 220 and the antenna 250. [ The second battery 240 may be a secondary battery, and is preferably an eco-friendly battery that can be used semi-permanently by charging a nickel-cadmium battery, a lithium ion battery, a lithium polymer battery, or the like.

The alarm device 260 may be a speaker 263 that provides sound to the user or a lamp 266 that provides the user with visual sensitivity and may be provided with a speaker 263 and a lamp 266 together. The control unit 300 provided in the charging and detecting apparatus 200 is connected to the antenna 250 and the alarm device 260 and is connected to the alarm device 260 according to the sensitivity of the radio pulse generated from the arrow pattern 100 Can be controlled.

For example, as the reception sensitivity of the wireless pulse generated from the arrow pattern 100 approaches, the controller 300 may have a short alarm period of the speaker 263 or generate an alarm sound of a high frequency band. The controller 300 may sequentially turn on the plurality of lamps 266 to guide the user to the position of the arrow pattern 100 as the reception sensitivity of the wireless pulse generated from the arrow pattern 100 is closer . The charging and detecting apparatus 200 further includes an amplification unit 280 capable of adjusting the reception sensitivity of the antenna 250. The amplification unit 280 amplifies the signal received from the antenna 250, It is possible to amplify the wireless pulse of FIG. Therefore, the charging and detecting apparatus 200 can easily check the position of the arrow pattern 100 by adjusting the reception sensitivity according to the distance of the arrow pattern 100. [

The charging and detecting apparatus 200 may include a storage holder 228 at one side of the holder 220 and a first battery 35 that has been charged at the storage holder 228. The charging and detecting device 200 may include a first indicator lamp 270 for indicating a charged state of the first battery 35 being charged in the holder 220, And a second indicator lamp 290 for displaying the amount of power or the remaining amount of the second battery 240 mounted on the second battery 240.

For example, when the first battery 35 is charged by inserting the first battery 35 into the holder 220, the voltage across the first battery 35 rises, but the voltage is slightly lowered when the charging is almost completed. The control unit 300 senses the lowering voltage to recognize the completion of the charging and stops the charging current to be supplied to the first battery 35. When the charging is completed in the red state in which the first display lamp 270 is being charged Green, etc. < / RTI > Accordingly, the user can recognize the state of charge of the first battery 35. [ The control unit 300 is connected to the second battery 240 and controls the second indicator lamp 290 according to the voltage of the second battery 240 to check the amount of power or the remaining amount of the second battery 290 have.

The charging and detecting device 200 may further include a cover 235 hinged to the upper portion of the charging body 230 and an illuminating lamp 238 may be installed on the lower surface of the cover 235. The cover 235 can be switched to a standby position for blocking the upper portion of the charging body 230 from the outside and an operating position for releasing the upper portion of the charging body 230 from the upper portion of the charging body 230, Can emit light at the operating position so that the user can use the charging and detecting device 200 in a comfortable environment even at night through the illumination lamp 238. [

Therefore, the present invention can enjoy leisure sports such as the crossbow (1) even in a state in which the night view or the view of the smog is limited through the light emitter 80 provided in the arrow pattern 100 provided at the rear end of the arrow 10 . The one-chip microprocessor 90 mounted on the arrow pattern 100 is connected to the acceleration sensor 60 and the light emitter 80 to easily control the light emitter 80 according to the acceleration, Economical efficiency and efficiency can be maximized.

In addition to filling the arrow pattern 100 recovered through the charging and detecting device 200 and the antenna 250 provided in the charging and detecting device 200, It is possible to detect the arrows 10 and the arrow pattern 100 in the shortest time period to maximize the recovery rate of the expensive arrow 10 and to increase the recovery rate of the arrow 10 And the environmental pollution caused by the loss of the arrow pattern 100 can be expected.

The above-described arrow pattern can be applied to a limited range of the above-described embodiments, but the embodiments can be selectively combined with all or some of the embodiments so that various modifications can be made.

1: Crossbow 2: Trigger
4: Brace 5: Crossbow body
7: Rim 8:
10: arrow 13: arrowhead
15: shaft 19: mounting groove
30: Body 35: First Battery
40: wing 50: substrate
60: first sensor 70: wireless pulse generator
80: illuminator 90: one-chip microprocessor
100: Arrow pattern 200: Charging and detecting device
210: inner space 220: holder
230: Charging body 240: Second battery
250: Antenna 260: Alarm device
270: first display light 280: amplification unit
290: Second display lamp 300:

Claims (10)

An arrow device comprising a detection device for detecting an arrow pattern and an arrow pattern,
Wherein the arrow-
A handle body detachably attached to a rear end of the arrow and having a mounting space formed therein;
A substrate disposed in the installation space;
A wireless pulse generator connected to the substrate to generate a wireless pulse;
A light emitting body connected to the substrate, the light emitting body being capable of emitting light; And
And a first sensor connected to the substrate and sensing an acceleration of the arrow,
The detection device receives the radio pulse generated from the radio pulse generator and generates an alarm according to the sensitivity of the radio pulse,
The substrate includes a light emitter and a control unit connected to the first sensor and emitting a light according to a signal sensed by the first sensor,
Wherein,
When the acceleration of the first sensor reaches a preset threshold value or higher, the light emitter is flickered in a predetermined first period,
When the acceleration of the first sensor becomes 0 at a negative value, the light emitter is flickered at a predetermined second period,
Wherein the second period has a blink period that is longer than the first period. The method according to claim 1,
The detection device further includes a speaker or a lamp for generating the alarm,
Wherein the controller adjusts the volume or period of the alarm sound of the speaker in proportion to the sensitivity of the wireless pulse or adjusts the brightness or blink period of the lamp. delete The method according to claim 1,
Wherein the control unit is connected to the wireless pulse generator and applies a current to the wireless pulse generator when the acceleration of the first sensor is zero from a negative value. The method according to claim 1,
Wherein,
And cuts off the current applied to the light emitting unit when the acceleration of the first sensor is switched twice or more as a positive value and a negative value within a set T ₁ time. 6. The method of claim 5,
Wherein,
And a current is applied to the light emitter when the acceleration of the first sensor is switched between positive and negative values within a predetermined time T ₂ in a state in which the current applied to the light emitter is blocked. delete The method according to claim 1,
Wherein,
When the acceleration of the first sensor is switched between a positive value and a negative value more than once within a predetermined time T ₁ , the current applied to the illuminant and the radio pulse generator is blocked,
When a current applied to the light emitting unit is interrupted and the acceleration of the first sensor is switched to a positive value and a negative value at least two times within a preset T ₂ time, An arrowing device. The method according to claim 1,
Wherein the patterned body has a rechargeable battery for supplying current to the substrate and the light emitting body,
Wherein the rechargeable battery is a rechargeable secondary battery. The method according to claim 1,
And the pattern body further comprises a mounting groove formed by being recessed from the rear end to receive a bowstep.

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