CN216115634U - Multi-quadrant target for training shooting - Google Patents

Abstract

The utility model discloses a multi-quadrant target for training shooting, and relates to a target material for shooting training. Its purpose is many, the precision is high, the training effectual training shooting multi-quadrant target of a scoring area in order to provide one kind. The multi-quadrant target for training shooting comprises a target surface, a partition layer, a first chest ring layer, a second chest ring layer and a negative layer, wherein an annular target area is drawn on the target surface, the first chest ring layer comprises a first positive plate, the second chest ring layer comprises a second positive plate, the first positive plate and the second positive plate are provided with annular target areas and correspond to the annular target areas on the target surface in position, the partition layer comprises a third positive plate, a plurality of target reporting areas are distributed on the third positive plate, conductive cloth is connected with each annular target area on the first positive plate and the second positive plate, and each target reporting area on the third positive plate, each conductive cloth connected with the positive plate is respectively connected with an external positive power supply, the negative layer comprises a negative plate, and the conductive cloth connected with the negative plate is connected with an external negative power supply.

Description

Multi-quadrant target for training shooting

Technical Field

The utility model relates to the technical field of targets, in particular to a multi-quadrant target for training shooting.

Background

Targets are devices that aid in shooting training and are typically used in conjunction with fixed or moving supports. There are two common targets currently on the market. Firstly, only the target paper has the region and does not have the target reporting function, and after the shooting is completed, the shooting is checked by people before the people come on the ground, and then the striking condition is reported manually. And secondly, the non-region has a target-reporting function, two pieces of conductive materials are respectively connected with a power supply anode and a power supply cathode, and then are attached to an insulating material at a certain distance. By the characteristic that the bullet is a conductor, when the bullet breaks through the electrode, the electrode is conducted, the control circuit captures a conducting signal, and then the controller generates a target surface hitting signal.

The conventional target generally has two problems, namely, a target scoring area is single, more signal lines are needed for transmitting signals when a multi-area scoring target is manufactured, the internal space of the target is insufficient, and the signal lines are difficult to arrange in the multi-area target; and secondly, the precision is not enough, and the target scoring area is small, so that the distinguishability is not strong, and a shooter cannot accurately know the specific position of the target hit by the shooter, so that the training effect is not enough, and the improvement of the training result is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a multi-quadrant shooting training target which has multiple target scoring areas, high precision and good training effect.

The utility model relates to a multi-quadrant target for training shooting, which comprises a target surface, a partition layer, a first chest ring layer, a second chest ring layer and a negative layer, wherein figure outline patterns and annular target areas are drawn on the target surface, the first chest ring layer comprises a first positive plate, the second chest ring layer comprises a second positive plate, a plurality of annular target areas are arranged on the first positive plate and the second positive plate in a staggered manner, the annular target areas on the first positive plate and the second positive plate correspond to the annular target areas on the target surface, the partition layer comprises a third positive plate, a plurality of target reporting areas are distributed on the third positive plate, a plurality of pieces of conductive cloth are uniformly distributed on the outer sides of the three positive plates, the conductive cloth is respectively connected with each annular target area on the first positive plate and the second positive plate and each target reporting area on the third positive plate, each conductive cloth connected with the positive plate is respectively connected with an external power supply positive electrode, the negative layer comprises a negative plate, the conductive cloth connected on the negative plate is connected with the negative electrode of an external power supply.

The utility model trains and shoots the target of the multiple quadrant, wherein said zonal layer, first chest ring layer, second chest ring layer and negative pole layer are the same with the external profile shape of the target surface.

According to the multi-quadrant shooting training target, each annular target area on the first positive plate and the second positive plate and each target reporting area on the third positive plate are connected with two pieces of conductive cloth, and the two pieces of conductive cloth are respectively located on two sides of the annular target area and the target reporting areas.

The utility model trains and shoots a multi-quadrant target, wherein six annular areas of five rings to ten rings are marked on an annular target area of the target surface.

The utility model discloses a multi-quadrant target for training shooting, wherein a first positive plate and a second positive plate are both multilayer annular plates, the first positive plate comprises a five-ring area, a seven-ring area and a nine-ring area, the second positive plate comprises a six-ring area, an eight-ring area and a ten-ring area, and the corresponding areas where five rings to ten rings are located on a target surface are respectively covered.

The utility model discloses a multi-quadrant target for training shooting, wherein the first breast ring layer further comprises a first insulating plate, and a first positive plate is positioned on the front side of the first insulating plate; the second chest ring layer further comprises a second insulating plate, and the second positive plate is located on the front side of the second insulating plate.

The utility model discloses a multi-quadrant target for training shooting, wherein eight target scoring areas are distributed on a third positive plate, and the eight target scoring areas are sequentially distributed along the clockwise direction.

The multi-quadrant target for training shooting comprises a first insulating plate, a second insulating plate and a third insulating plate, wherein the first insulating plate is arranged between two adjacent target reporting areas on the first positive plate.

The multi-quadrant target for training shooting comprises a partition layer, a first insulating plate, a second insulating plate, a third positive plate and a third insulating plate, wherein the partition layer further comprises the fourth insulating plate, and the third positive plate and the third insulating plate are both arranged on the front side of the fourth insulating plate.

The multi-quadrant shooting training target comprises a negative electrode layer, a negative electrode layer and a third insulating plate, wherein the negative electrode layer comprises the fifth insulating plate, and the negative electrode plate is installed on the front side of the fifth insulating plate.

Compared with the prior art, the training shooting multi-quadrant target of the utility model is different in that the training shooting multi-quadrant target comprises a plurality of subareas, and the subareas can be additionally arranged as required, thus having the effects of more subareas and high precision. The large number of sections require more wires, and conventional wires are used as wires, and are easily broken when they are connected internally because the wires are thin. The implantation of a large diameter wire in the product can lead to the product being unable to be assembled, and the product does not allow the wire to be used inside due to the characteristic of bullet striking, which is a big problem for the product to be used normally. The utility model replaces the internal lead with the widened conductive cloth which can replace the lead, and solves the problem that the target is invalid due to more winding displacement and easy breaking in the internal part.

In addition, the utility model arranges double-side signal wires on both sides of the positive plate, so that even if one side of the signal wire is hit and scrapped, the other side of the signal wire can support the normal work of target reporting, thereby improving the target capacity.

The utility model will be further explained with reference to the drawings.

Drawings

FIG. 1 is an exploded view of a multi-quadrant target of the present invention for training shooting;

FIG. 2 is a schematic view of the construction of the target surface in the multi-quadrant target for training shooting according to the present invention;

FIG. 3 is a schematic structural view of a first chest ring layer in the multi-quadrant target for training shots in accordance with the present invention;

FIG. 4 is a schematic structural view of a second chest ring layer in the multi-quadrant target for training shots in accordance with the present invention;

FIG. 5 is a schematic structural view of a zoning layer in the multi-quadrant target for training shots in accordance with the present invention;

the notation in the figures means: 1-target surface; 2-first chest ring layer; 3-second pectoral ring layer; 4-partition layer; 5-a negative electrode layer; 6-negative plate; 7-a third positive plate; 8-a second positive plate; 9-a first positive plate; 10-annular target area; 11-conductive cloth; 12-a first insulating plate; 13-the pentacyclic region; 14-heptacyclic region; 15-nine ring region; the 16-decaring region; 17-a second insulating plate; 18-a six-ring region; 19-an octacyclic region; 20-a third insulating panel; 21-fourth insulating plate.

Detailed Description

The following examples are intended to illustrate the utility model but are not intended to limit the scope of the utility model.

As shown in figure 1, the multi-quadrant target for training shooting of the utility model comprises a target surface 1, a partition layer 4, a first chest ring layer 2, a second chest ring layer 3 and a negative electrode layer 5. The target surface 1 is located at the outermost side, and other layers can be arranged in sequence as required. In this embodiment, the inner side of the target surface 1 is sequentially provided with a first thoracic ring layer 2, a second thoracic ring layer 3, a partition layer 4 and a negative electrode layer 5.

The target surface 1 is made of an insulating material, in this example, EVA plastic, and is formed by compression molding. As shown in fig. 2, the target surface 1 is painted with a figure outline pattern. In this embodiment, the contour of the target surface 1 is the contour of the head and the chest of the human body. The outer contour of the other layers is the same as the target surface 1. The target surface 1 is also delineated by an annular target area 10, which is marked by six areas, five to ten rings.

The first breast ring layer 2 and the second breast ring layer 3 are sequentially disposed on the rear side of the target surface 1, wherein, as shown in fig. 3, the first breast ring layer 2 includes a first positive plate 9 and a first insulating plate 12, and the first positive plate 9 is located on the front side of the first insulating plate 12. The first positive plate 9 is a multilayer annular plate, and comprises a five-ring area 13, a seven-ring area 14 and a nine-ring area 15, and covers corresponding areas of the target surface 1 where the five rings, the seven rings and the nine rings are located. The two sides of the first positive plate 9 are respectively provided with a plurality of pieces of conductive cloth 11, and the conductive cloth 11 is respectively connected with the five-ring area 13, the seven-ring area 14 and the nine-ring area 15 of the first positive plate 9 and is connected with the positive electrode of each area. The conductive cloths 11 are symmetrically arranged on the left side and the right side of the first positive plate 9, so that two conductive cloths are connected in each area and are respectively connected with the positive electrode of an external power supply. When the conductive cloth on one side is connected and has problems, the conductive cloth on the other side can also ensure the normal use of the target material, effectively reduce the replacement times of the target material and reduce the failure rate of the target material.

As shown in fig. 4, the second breast ring layer 3 includes a second positive electrode plate 8 and a second insulating plate 17, and the second positive electrode plate 8 is positioned at the front side of the second insulating plate 17. The second positive plate 8 is a multilayer annular plate, and comprises a six-ring area 18, an eight-ring area 19 and a ten-ring area 16, and covers the corresponding areas of the target surface 1 where the six rings, the eight rings and the ten rings are located. And a plurality of pieces of conductive cloth 11 are respectively arranged on two sides of the second positive plate 8, and the conductive cloth 11 is respectively connected to the six-ring area 18, the eight-ring area 19 and the ten-ring area 16 of the second positive plate 8 and is connected with the positive electrodes of the areas. The conductive cloths 11 are symmetrically arranged on the left side and the right side of the second positive plate 8, so that two conductive cloths are connected in each area and are respectively connected with the positive electrode of an external power supply.

The partition layer 4 is disposed at the rear side of the breast ring layer, and as shown in fig. 5, the partition layer 4 includes a third positive electrode plate 7, a third insulating plate 20, and a fourth insulating plate 21. Eight target reporting areas, namely a subarea to an eight subarea, are distributed on the third positive plate 7 in sequence along the clockwise direction, and a third insulating plate 20 is arranged between every two adjacent areas. The third positive electrode plate 7 and the third insulating plate 20 are mounted on the front side of the fourth insulating plate 21. A plurality of pieces of conductive cloth 11 are arranged on the outer side of the third positive plate 7, the conductive cloth 11 is respectively connected with one partition to eight partitions on the third positive plate 7, each partition is connected with two pieces of conductive cloth, and each piece of conductive cloth 11 is respectively connected with the positive electrode of an external power supply.

The negative electrode layer 5 is located at the rearmost side and includes a negative electrode plate 6 and a fifth insulating plate, and the negative electrode plate 6 is installed at the fifth insulating plate front side. The negative plate 6 is connected with two pieces of conductive cloth 11, and the conductive cloth 11 connected with the negative plate 6 is connected with an external power supply negative electrode.

When the multi-quadrant target for training shooting is used, all parts of the structure of the target are arranged on the base, the leads led out of the positive conductive plates and the negative conductive plates are respectively connected with the positive electrode and the negative electrode of a power supply and connected with a controller capable of capturing conduction signals. When the bullet hits the target, the bullet is left between the positive electrode layer conductive plate and the negative electrode conductive plate, the corresponding loop is conducted, an electric signal is generated, and the controller sends a signal of hitting the corresponding part after receiving the electric signal.

When the bullet breaks through the first chest ring layer 2 and the second chest ring layer 3, if the conductive cloth 11 connected with the positive plate in the first chest ring layer 2 and the second chest ring layer 3 is broken through at the same time, namely two ring areas simultaneously obtain signals, a ring area with low priority number of reports can be drawn up in the controller. When a bullet breaks through the partition layer 4 and two partitions simultaneously acquire signals, the controller can be programmed to give priority to the first partition, the third partition, the fifth partition and the seventh partition. The above-mentioned drafting process is a simple logic setting, belongs to the prior art, and is not an innovative point of the present application.

The multi-quadrant target for training shooting comprises a plurality of subareas, and the subareas can be additionally arranged according to needs, so that the multi-quadrant target has the effects of more subareas and high precision. The large number of sections require more wires, and conventional wires are used as wires, and are easily broken when they are connected internally because the wires are thin. The implantation of a large diameter wire in the product can lead to the product being unable to be assembled, and the product does not allow the wire to be used inside due to the characteristic of bullet striking, which is a big problem for the product to be used normally. The utility model replaces the internal lead with the widened conductive cloth which can replace the lead, and solves the problem that the target is invalid due to more winding displacement and easy breaking in the internal part.

In addition, the utility model arranges double-side signal wires on both sides of the positive plate, so that even if one side of the signal wire is hit and scrapped, the other side of the signal wire can support the normal work of target reporting, thereby improving the target capacity.

Although the utility model has been described in detail above with reference to a general description and specific examples, it will be apparent to one skilled in the art that modifications or improvements may be made thereto based on the utility model. Accordingly, such modifications and improvements are intended to be within the scope of the utility model as claimed.

Claims (10)

1. A training shooting multi-quadrant target which characterized in that: comprises a target surface, a partition layer, a first chest ring layer, a second chest ring layer and a negative electrode layer, wherein figure outline patterns and annular target areas are drawn on the target surface, the first chest ring layer comprises a first positive plate, the second chest ring layer comprises a second positive plate, a plurality of annular target areas are arranged on the first positive plate and the second positive plate in a staggered manner, the annular target areas on the first positive plate and the second positive plate correspond to the annular target areas on the target surface, the partition layer comprises a third positive plate, a plurality of target reporting areas are distributed on the third positive plate, a plurality of pieces of conductive cloth are uniformly distributed on the outer sides of the three positive plates, and the conductive cloth is respectively connected with each annular target area on the first positive plate and each annular target area on the second positive plate, and each target reporting area on the third positive plate, each conductive cloth connected with the positive plates is respectively connected with the positive electrode of an external power supply, the negative layer comprises a negative plate, and the conductive cloth connected with the negative plate is connected with the negative electrode of the external power supply.

2. The multi-quadrant target of claim 1, wherein: the outer contour shapes of the partition layer, the first chest ring layer, the second chest ring layer and the negative electrode layer are the same as those of the target surface.

3. The multi-quadrant target of claim 1, wherein: every annular target area on first positive plate and the second positive plate to and every target practice area on the third positive plate all are connected with two electrically conductive cloths, and two electrically conductive cloths are located the both sides of annular target area and target practice area respectively.

4. The multi-quadrant target of claim 1, wherein: six annular areas from five rings to ten rings are marked on the annular target area of the target surface.

5. The multi-quadrant target of claim 4, wherein: the first positive plate and the second positive plate are both multilayer annular plates, the first positive plate comprises a five-ring area, a seven-ring area and a nine-ring area, the second positive plate comprises a six-ring area, an eight-ring area and a ten-ring area, and the corresponding areas where the five rings to the ten rings are located on the target surface are covered respectively.

6. The multi-quadrant target of claim 1, wherein: the first breast ring layer further comprises a first insulating plate, and the first positive plate is located on the front side of the first insulating plate; the second chest ring layer further comprises a second insulating plate, and the second positive plate is located on the front side of the second insulating plate.

7. The multi-quadrant target of claim 1, wherein: eight target reporting areas are distributed on the third positive plate and are sequentially arranged along the clockwise direction.

8. The multi-quadrant target of claim 7, wherein: the partition layer further comprises a third insulating plate, and a third insulating plate is arranged between every two adjacent target reporting areas on the third positive plate.

9. The multi-quadrant target of claim 8, wherein: the partition layer further comprises a fourth insulating plate, and the third positive plate and the third insulating plate are both arranged on the front side of the fourth insulating plate.

10. The multi-quadrant target of claim 1, wherein: the negative electrode layer comprises a fifth insulating plate, and the negative electrode plate is arranged on the front side of the fifth insulating plate.

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