阅读说明：本技术 一种枪枝传感器制震结构 (Vibration damping structure of gun sensor ) 是由 杨柏峰 于 2018-09-12 设计创作，主要内容包括：本发明提供一种枪枝传感器制震结构,供一传感器设置并接合于一虚拟现实用的枪枝,包括一本体和多个制震件,本体包括第一接合部和可接合于枪枝的第二接合部,且本体有一容置部供传感器容置；多个制震件为可吸震材质制成而设于本体的容置部,传感器容置于容置部时,传感器被多个制震件压制而定位于容置部,且以多个制震件吸收传感器所受的震动,而可由制震件在枪枝射击时消除传感器所受的震动,以改善传感器的定位点因震动而产生误差的问题。(The invention provides a gun sensor vibration damping structure, which is used for arranging and jointing a sensor on a virtual and practical gun and comprises a body and a plurality of vibration damping pieces, wherein the body comprises a first jointing part and a second jointing part which can be jointed on the gun, and the body is provided with a containing part for containing the sensor; the plurality of vibration-making pieces are made of a vibration-absorbing material and are arranged in the containing part of the body, when the sensor is contained in the containing part, the sensor is pressed by the plurality of vibration-making pieces and is positioned in the containing part, the plurality of vibration-making pieces absorb the vibration borne by the sensor, and the vibration borne by the sensor can be eliminated by the vibration-making pieces when a gun shoots, so that the problem that the positioning point of the sensor generates errors due to the vibration is solved.)

1. The utility model provides a rifle branch sensor system shakes structure for a sensor setting and joint in a virtual practical rifle branch, its characterized in that includes:

a body, the body including a first engaging portion engageable with a second engaging portion of the gun, the body having a receiving portion for receiving the sensor; and

the sensor is arranged in the containing part, when the sensor is contained in the containing part, the sensor is pressed by the plurality of vibration-making pieces and positioned in the containing part, and the plurality of vibration-making pieces can absorb the vibration borne by the sensor.

2. The shock-absorbing structure of a gun sensor according to claim 1, wherein the body includes a base and a cover, the cover is disposed on top and the base is disposed on bottom, the receiving portion is disposed between the base and the cover, the plurality of shock-absorbing members are pressed around the sensor, and the sensor is pressed by the shock-absorbing members in the receiving portion without contacting the body.

3. The shock-absorbing structure of a gun sensor as claimed in claim 2, wherein the seat has a front section, a middle section and a rear section, the front section and the rear section are connected to two ends of the middle section respectively, the cover and the seat are assembled to join the front section and the rear section, a chamber is formed between the cover and the rear section, and the front section has a receiving slot, so that the chamber and the receiving slot form the receiving portion for receiving the sensor.

4. The shock absorbing structure of a gun sensor as claimed in claim 3 wherein the shock absorbing members are all foam bodies capable of absorbing shock.

5. The shock absorbing structure of claim 3, wherein a hollow portion is formed between the middle portion of the base and the cover, the bottom of the sensor is exposed from the hollow portion when the sensor is received in the receiving portion, and the body is provided with a top-pulling member in the hollow portion, the top-pulling member supports the bottom of the sensor to assist in positioning the sensor in the body.

6. The shock-absorbing structure of a gun sensor as claimed in claim 5 wherein the top pulling member comprises an elastic member and a top supporting block, the middle section has a column portion protruding from the hollow portion, one end of the elastic member is connected to the column portion and the other end is connected to the top supporting block, and the top supporting block is normally supported against the bottom of the sensor by the elastic force of the elastic member.

7. The vibration suppressing structure of a gun sensor as claimed in claim 1 wherein one of said first engaging portion and said second engaging portion is concave and the other is convex, and said first engaging portion and said second engaging portion are engaged with each other in a concavo-convex manner.

8. The gun sensor shock structure of claim 7, wherein the first engagement portion is concave and is a connecting groove, and the second engagement portion is convex and is a connecting rail.

Technical Field

The invention relates to a sensor vibration damping structure, in particular to a sensor vibration damping structure for a virtual reality gun.

Background

The virtual reality is a virtual three-dimensional space generated by the simulation of a computer through software, provides the simulation of senses such as vision and the like for a user, and enables the user to feel as if the user is in the original situation. The virtual reality device has a screen for displaying a three-dimensional image and projecting the image on the eyes of a user, a sensor for sensing the rotation angle of the user, and an arithmetic unit for collecting data from the sensor to determine the image displayed on the screen.

In a virtual reality gun game, a sensor is mounted on a body-sensing gun, and in order to increase the sense of reality, the body-sensing gun generally increases the sound and light effect, the vibration sense during shooting, and the tactile sense with recoil. However, when shooting shock or recoil, the sensor on the body sensing gun can generate deviation due to shock, and the deviation can be continuously accumulated, so that the positioning point of the sensor generates errors, the aiming of the target object cannot be accurate, and shooting errors are easy to occur in the game process.

Therefore, how to improve the problem that the positioning point has errors due to the deviation of the sensor of the motion sensing gun caused by the vibration is the key point of the invention.

Disclosure of Invention

In order to solve the above problems, the present invention provides a damping structure for a gun sensor, wherein a plurality of damping members are disposed in a receiving portion of a sensor through a body, and when the sensor is disposed in the body and vibration is generated, the vibration can be eliminated by the plurality of damping members, so that the sensor is not affected by the vibration.

An embodiment of the present invention provides a gun sensor vibration damping structure for a sensor to be installed and engaged with a virtual gun, comprising:

a body, the body including a first engaging portion engageable with a second engaging portion of the gun, the body having a receiving portion for receiving the sensor; and

the sensor is arranged in the containing part, and when the sensor is contained in the containing part, the sensor is pressed by the plurality of vibration-making pieces and positioned in the containing part, and the plurality of vibration-making pieces absorb the vibration of the sensor.

Preferably, the body includes a base and a cover, the cover is disposed above and below the base, the accommodating portion is disposed between the base and the cover, the plurality of damping members are pressed around the sensor, and the sensor is pressed by the damping members in the accommodating portion without contacting the body.

Preferably, the seat body has a front section, a middle section and a rear section, the front section and the rear section are respectively connected to two ends of the middle section, the cover body and the seat body are combined with the front section and the rear section when assembled, a containing chamber is formed between the cover body and the rear section, and the front section has a containing groove, so that the containing chamber and the containing groove form the containing part for containing the sensor.

Preferably, the plurality of vibration-making members are all cotton bodies capable of absorbing vibration.

Preferably, a hollow portion is formed between the middle section of the seat body and the cover body, the bottom of the sensor is exposed out of the hollow portion when the sensor is accommodated in the accommodating portion, and the body is provided with a top pulling member in the hollow portion, so that the top pulling member supports the bottom of the sensor to assist in positioning the sensor in the body.

Preferably, the top pulling member includes an elastic member and a top supporting block, the middle section has a column portion protruding from the hollow portion, one end of the elastic member is connected to the column portion and the other end is connected to the top supporting block, and the top supporting block is normally supported against the bottom of the sensor by the elastic force of the elastic member.

Preferably, one of the first joint part and the second joint part is concave and the other is convex, and the first joint part and the second joint part are jointed in a concave-convex manner.

Preferably, the first engaging portion is concave and is a connecting groove, and the second engaging portion is convex and is a connecting rail.

Therefore, the sensor can be pressed and positioned by the vibration-making pieces arranged in the accommodating part, and the vibration generated by the body can be eliminated by the vibration-making pieces, so that the vibration generated by the body in the gun-holding shooting process is not transmitted to the sensor, the sensor can be prevented from displacing in the accommodating part due to the vibration, the problem that the positioning point of the sensor cannot accurately aim at a target object due to error is solved, and the trouble that the sensor needs to be repeatedly positioned and corrected in the game is avoided.

Drawings

Fig. 1 is a perspective view of a sensor of an embodiment of the invention in a body coupled to a gun.

Fig. 2 is a schematic view of the body of the embodiment of the present invention engaged with the first engaging portion and the second engaging portion of the gun.

Fig. 3 is an exploded view of the base and the cover of the main body according to the embodiment of the invention.

Fig. 4 is a schematic diagram of a sensor according to an embodiment of the present invention when the sensor is assembled to a body.

FIG. 5 is a cross-sectional view of the sensor of the embodiment of the invention with the damper disposed in the receiving portion pressed around the sensor when the sensor is coupled to the body.

Description of the reference numerals

Second joint part 11 of gun 10

Sensor 20 head 21

Bottom 221 of handle 22

First joint part 31 of body 30

Receptacle 32 receptacle 321

Receptacle 322 and base 33

Front section 331 intermediate section 332

Rear 333 post 334

Hollow part 35 of cover 34

Resilient member 361 of the top detent 36

The top support blocks 362 make up the seismic elements 40.

Detailed Description

To facilitate the explanation of the present invention, the central ideas shown in the above summary are shown in the following embodiments. Various objects in the embodiments are illustrated in scale, size, amount of distortion or displacement as appropriate for the description, rather than in scale of actual components, as previously described.

Referring to fig. 1 to 5, the present invention provides a gun sensor vibration damping structure, which can be installed on a gun 10 for a virtual reality game and is used for installing a sensor 20 to aim at a target object for shooting in a shooting game, wherein the gun 10 and the sensor 20 are in communication connection. In the embodiment of the present invention, the sensor 20 is a commercially available VIVE controller for virtual reality, and when the gun 10 is in the shooting game, the sensor 20 is used for the alignment tracking of the gun 10, and the gun 10 is aimed at the object to be shot through the sensor 20. The gun sensor vibration damping structure comprises a body 30 and a plurality of vibration damping members 40, wherein:

as shown in fig. 1 to 2, the body 30 has a first engaging portion 31, the body 30 has a receiving portion 32, the corresponding gun 10 has a second engaging portion 11, the body 30 is engaged with the second engaging portion 11 of the gun 10 by the first engaging portion 31, and the sensor 20 is received in the receiving portion 32 of the body 30. In the embodiment, the main body 30 includes a seat 33 and a cover 34, the main body 30 is formed by assembling the cover 34 on top and the seat 33 on bottom, and the accommodating portion 32 is located between the seat 33 and the cover 34. Further, one of the first joining portion 31 and the second joining portion 11 is concave and the other is convex, and the first joining portion 31 and the second joining portion 11 are joined to each other in a concavo-convex manner. In the preferred embodiment, the first engaging portion 31 is concave and is a connecting groove, the second engaging portion 11 is convex and is a connecting rail, and the first engaging portion 31 and the second engaging portion 11 are in a groove-rail type and are concave-convex opposite to each other.

As shown in fig. 3 to 4, the base 33 has a front section 331, a middle section 332 and a rear section 333, the front section 331 is connected to one end of the middle section 332, the rear section 333 is connected to the other end of the middle section 332 and is located at two ends away from the front section 331, when the cover 34 and the base 33 are assembled, the cover 34 is connected to the front section 331 and the rear section 333, a receiving chamber 321 is formed between the cover 34 and the rear section 333, and the front section 331 has a receiving groove 322, and the receiving chamber 321 and the receiving groove 322 form the receiving portion 32. The sensor 20 of the embodiment has a head end 21 and a handle body 22 extending from the head end 21, when the sensor 20 is received in the receiving portion 32, the head end 21 is received in the receiving portion 321 and partially exposed out of the body 30, and the handle body 22 is extended into the body 30 and disposed in the receiving slot 322 at the end.

The damping members 40 are made of a material capable of absorbing shock, the damping members 40 are disposed in the accommodating portion 32 of the body 30, when the sensor 20 is accommodated in the accommodating portion 32, the sensor 20 is pressed by the damping members 40 and positioned in the accommodating portion 32, and the damping members 40 absorb shock received by the sensor 20. Referring to fig. 3 to 5, in the present embodiment, the vibration dampers 40 are foam bodies (e.g., vibration absorbing sponges) capable of absorbing vibration, and the vibration dampers 40 are pressed around the sensor 20, i.e., the vibration dampers 40 are not only pressed on a single side of the sensor 20, but also pressed on the upper, lower, left, and right sides of the sensor 20, so that the sensor 20 is only pressed and positioned by the vibration dampers 40 in the accommodating portion 32 and does not contact the body 30, and if the body 30 has vibration, the vibration is not directly transmitted to the sensor 20, but is absorbed and eliminated by the vibration dampers 40.

In the body 30 of the present embodiment, a hollow portion 35 is formed between the middle section 332 of the seat body 33 and the cover 34, when the sensor 20 is accommodated in the accommodating portion 32, the bottom 221 of the handle body 22 of the sensor 20 is exposed in the hollow portion 35, and the body 30 is provided with a supporting member 36 in the hollow portion 35, so that the supporting member 36 supports the bottom 221 of the handle body 22 of the sensor 20 to assist in positioning the sensor 20 on the body 30. In this embodiment, the top pulling element 36 includes an elastic element 361 and a top supporting block 362, the middle section 332 has a pillar 334 protruding from the hollow portion 35, one end of the elastic element 361 is connected to the pillar 334 and the other end is connected to the top supporting block 362, and the top supporting block 362 is normally supported on the bottom 221 of the handle 22 of the sensor 20 by the elastic force of the elastic element 361. Furthermore, since the elastic member 361 also has the function of absorbing vibration, it can cooperate with a plurality of vibration dampers 40 to eliminate the vibration received by the sensor 20.

As can be seen from the above description, the present invention has the advantages that a plurality of shock-absorbing members 40 are disposed in the accommodating portion 32 of the body 30, the sensor 20 can be pressed by the plurality of shock-absorbing members 40 to be positioned on the body 30, when the gun 10 plays the gun battle game in the virtual reality, the main body 30 vibrates with the shooting of the gun 10 or the vibration generated by recoil, the vibration damping members 40 can be eliminated, and the sensor 20 is supported on the bottom 221 of the handle body 22 by the supporting member 36, to assist in positioning the sensor 20 on the body 30, so that the positioning of the sensor 20 on the body 30 is more stable, therefore, the vibration generated by the body 30 in the gun-holding shooting process is not transmitted to the sensor 20, and the displacement of the sensor 20 in the accommodating part 32 due to the vibration can be prevented, so that the problem that the positioning point of the sensor 20 cannot be accurately aimed at the target object due to error is solved, and the trouble that the sensor 20 needs to be repeatedly positioned and corrected when a game is not played is avoided.

It is to be understood that the described embodiments are merely a few embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.