CN114040612B - Backpack device for self-organizing network base station and infinite jump MESH communication system for ranging - Google Patents

Abstract

The invention relates to the technical field of ad hoc network communication, in particular to a backpack device for an ad hoc network base station. The self-organizing system comprises an self-organizing network assembly and a carrying unit, wherein the carrying unit comprises a carrying plate; a supporting plate is arranged at the bottom of one side wall of the backpack plate, and the self-networking assembly box body is positioned on the supporting plate; two groups of braces are arranged on the wall of the other side of the back carrying plate, a first limit sleeve is movably clamped at the edge of one side, far away from the back carrying plate, of the supporting plate, a second limit sleeve is arranged at the top of the first limit sleeve, the other end of the second limit sleeve is movably clamped on the back carrying plate, and a load reducing mechanism is arranged between the first limit sleeve and the second limit sleeve. The invention also provides a system for measuring the infinite jump MESH communication. The invention reduces the bearing capacity of the back, reduces the risk of backward tilting, and simultaneously reduces the load feeling of a user when carrying.

Description

Backpack device for self-organizing network base station and infinite jump MESH communication system for ranging

Technical Field

The invention belongs to the technical field of ad hoc network communication, and particularly relates to a backpack device for an ad hoc network base station and a ranging infinite jump MESH communication system.

Background

The portable base station based on the centerless ad hoc network technology can be automatically and wirelessly networked when being started, the whole network uses the same frequency point, and the communication is carried out in an ultra-long distance mode without depending on any public network and private network, so that a centerless ad hoc network communication system with flexibility, strong destructiveness and high confidentiality can be built.

The communication technology of the centerless ad hoc network creatively realizes the characteristics of multi-hop multi-stage relay, same-frequency and same-broadcast networking, signal overlapping combination and the like, perfectly realizes the centerless ad hoc communication network, and solves the communication problems of multi-point and same-broadcast forwarding and signal interference in an overlapping area.

As shown in fig. 15, the specific ad hoc network base station communication system 150 includes an on-channel networking base station 151, a video scheduling platform 152, an ad hoc network base station 153, and an individual soldier hand-held/back-carried networking base station 154; the video scheduling platform 152 is connected with the same-frequency networking base station 151 through a communication optical fiber 155, and the ad hoc network base station 153, the same-frequency networking base station 151 and the individual hand-held/backpack networking base station 154 are linked through a relay communication station 156.

In order to improve the flexibility of the self-networking base station, the communication system is additionally provided with the individual soldier handheld/backpack networking base station, wherein the backpack networking base station has high load, wider signal coverage range and the like, and is used more. However, the existing backpack networking base station is heavy in general weight, a user is easy to fatigue when carrying the backpack networking base station, and the risk of backward tilting is easy to occur because the weight is all at the back of the user, so that the backpack comfort is reduced.

Disclosure of Invention

In view of the above problems, the present invention provides a backpack device for an ad hoc network base station, comprising an ad hoc network assembly and a backpack unit, wherein the backpack unit comprises a back plate; a supporting plate is arranged at the bottom of one side wall of the backpack plate, and the self-networking assembly box body is positioned on the supporting plate; two groups of braces are arranged on the wall of the other side of the back carrying plate, a first limit sleeve is movably clamped at the edge of one side, far away from the back carrying plate, of the support plate, a second limit sleeve is arranged at the top of the first limit sleeve, the other end of the second limit sleeve is movably clamped on the back carrying plate, and a load reducing mechanism is arranged between the first limit sleeve and the second limit sleeve;

the load reducing mechanism comprises a stretching ball and two groups of anti-seismic plates, and the two groups of anti-seismic plates are symmetrically arranged on two opposite side walls of the first limiting sleeve and the second limiting sleeve; the stretching balls are positioned in gaps between the two groups of shock-resistant plates; the stretching ball comprises a plurality of groups of stretching ball outer plates with fan-shaped structures, wherein a plurality of groups of stretching ball outer plates can form a spherical structure in a combined manner, and gaps are arranged between two adjacent groups of stretching ball outer plates; an inner stretching ball is arranged in the spherical structure, a group of stretching springs are arranged on the inner wall of each group of stretching ball outer plates, and the other ends of the stretching springs are fixedly arranged on the outer wall of the inner stretching ball; two groups of stretching belts are arranged on each group of stretching ball outer plates, and the two groups of stretching belts are respectively arranged on the two groups of shock-resistant plates.

Further, the ad hoc network assembly comprises an ad hoc network box body and two groups of first sliding mechanisms; the two groups of first sliding mechanisms are symmetrically arranged on the two side walls of the self-organizing net cage body; two groups of storage battery boxes are respectively arranged on the first sliding mechanisms; a brace is arranged on a side wall of the self-organizing net box body, which is vertical to the storage battery box; the storage battery box can horizontally slide to one side close to the braces through the first sliding mechanism; a group of first positioning bolts are respectively arranged at the edges of the two sides of the top of the self-organizing net cage body, and the bottoms of the first positioning bolts are movably arranged on the first sliding mechanism; and a second positioning bolt is arranged on one side, close to the braces, of the first positioning bolt, and the bottom of the second positioning bolt is movably arranged on the first sliding mechanism.

Further, the first sliding mechanism comprises a first sliding rod and a first sliding block; a first sliding groove is formed in one side wall of the self-organizing net box body, which is perpendicular to the braces, and the first sliding rod is arranged in the first sliding groove; one end of the first sliding block is connected to the first sliding rod in a sliding way, and the other end of the first sliding block penetrates through the outside of the first sliding groove and is arranged on the shell of the storage battery box; the top of the first sliding block is fixedly provided with a bolt connecting block; the bottoms of the first positioning bolt and the second positioning bolt can penetrate into the first sliding groove, and are connected to the bolt connecting block in a threaded mode.

Further, a group of second sliding mechanisms are respectively arranged under the two groups of first sliding grooves, and each second sliding mechanism comprises a second sliding rod and a second sliding block; the second sliding groove is located right below the first sliding groove, and the second sliding rod is installed in the second sliding groove.

Further, one end of the second sliding block is slidably connected to the second sliding rod, and the other end of the second sliding block penetrates through the second sliding groove and is fixedly installed on the shell of the storage battery box.

Further, the ad hoc network assembly also comprises a power supply control module, a wireless communication module and a processor; the power supply control module, the wireless communication module and the processor are fixedly arranged in the ad hoc network box body; the ad hoc network box body is provided with a plurality of groups of communication interfaces.

Further, the plurality of groups of communication interfaces are respectively connected with the power supply control module, the wireless communication module and the processor through signals.

Further, a group of power interfaces are respectively arranged under the two groups of second sliding mechanisms, and the power control module is electrically connected with the storage battery box through the power interfaces; the storage battery box comprises a storage battery box body; the storage battery box body is fixedly connected with the first sliding block and the second sliding block; and the storage battery box body can horizontally move to one side, close to the braces, of the self-organizing net box body through the first sliding block and the second sliding block.

Further, a vertical groove is formed in the outer wall of one side, close to the self-organizing net cage body, of the storage battery box body, a transverse groove is communicated with the bottom of the vertical groove, and the other end of the transverse groove extends to one side, close to the braces, of the storage battery box body and is of an open structure; and the inner walls of the vertical groove and the horizontal groove are fixedly provided with buffer cushions.

The invention also provides a ranging infinite jump MESH communication system using the knapsack device for the self-organizing network base station.

The beneficial effects of the invention are as follows:

1. when a wearer walks, the jolt force generated by the self-organizing net box body is transmitted to the stretching ball outer plates due to vibration, so that the distance between the stretching ball outer plates of each group is changed, then the jolt force generated during walking is absorbed through a group of stretching springs in the corresponding direction of the jolt force, the jolt force is not directly acted on the wearer, then the weight of the self-organizing net box body is redispersed to two groups of storage battery box bodies through two groups of stretching belts, the overall balance of the device is further improved, the stability of the self-organizing net box body during movement is also improved, and the comfort of the wearer during carrying the device is improved.

2. When the self-organizing net assembly needs to be carried and moved, the two groups of storage battery boxes are firstly horizontally moved to one side close to the carrying strap through the first sliding mechanism. When a user wears the ad hoc network assembly on the back, the weight of the two sets of storage battery boxes can move forward from the back of the user to the two sides. So that the stress on the back and the two sides is more even when a user carries the ad hoc network assembly to move. The bearing force of the back is reduced, the risk of backward tilting is reduced, and the load feeling of a user when the user is carried on the back is reduced.

3. When the self-organized net cage body is impacted by external force, the self-organized net cage body is firstly contacted with the anti-collision bag body, impact force is transmitted to one or more groups of first flexible glue rods and second flexible glue rods corresponding to the self-organized net cage body, and the first flexible glue rods and the second flexible glue rods are arranged in a mutually crossing manner, so that the impact force can be immediately dispersed to other groups of first flexible glue rods and second flexible glue rods. And the impact force is further absorbed by utilizing each group of vacuum balls, so that the buffer force of the first anti-collision unit is improved. And the anti-collision bag mounting plate is movably clamped with the self-organizing net cage body through the fixed buckle, and when one group of the first anti-collision units are damaged, only the group of the first anti-collision units are required to be taken down and replaced independently.

4. When a user carries the self-networking assembly, the double arms can be respectively placed in the transverse grooves and the vertical grooves on the two sides, so that the weight of the storage battery box can be further shared through the double arms, and the bearing capacity of the back is reduced. Meanwhile, the abrasion of the storage battery box body to the skin of the double arms can be avoided, so that the comfort level of a user during carrying is improved. And the waist of the user is just positioned in the bottom groove of the fan-shaped ring structure, and the waist of the user is protected through the bottom groove, so that the waist fatigue caused by long-term carrying of the ad hoc network assembly is reduced.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 shows a schematic structural view of a backpack apparatus according to an embodiment of the present invention

FIG. 2 illustrates a schematic diagram of an ad hoc network assembly according to an embodiment of the present invention;

FIG. 3 illustrates a schematic rear view of an ad hoc network assembly according to an embodiment of the present invention;

FIG. 4 shows a schematic diagram of the structure of an ad hoc network box according to an embodiment of the present invention;

FIG. 5 shows a schematic cross-sectional view of an ad hoc network case in accordance with an embodiment of the present invention;

fig. 6 shows a schematic structural view of a first sliding mechanism according to an embodiment of the present invention;

fig. 7 shows a schematic structural view of a second sliding mechanism according to an embodiment of the present invention;

fig. 8 is a schematic view showing a structure of a battery case according to an embodiment of the present invention after being moved;

fig. 9 shows a schematic structural view of a battery case according to an embodiment of the present invention;

fig. 10 shows a schematic top cross-sectional view of a first collision avoidance unit according to an embodiment of the invention;

FIG. 11 shows a schematic structural view of a backpack unit according to an embodiment of the present invention;

FIG. 12 shows a schematic rear view of a back plate according to an embodiment of the invention;

FIG. 13 shows a schematic structural view of a load relief mechanism according to an embodiment of the present invention;

FIG. 14 shows a schematic cross-sectional view of a stretched ball according to an embodiment of the invention;

fig. 15 shows a schematic structural diagram of a conventional ad hoc network base station communication system.

In the figure: 100. an ad hoc network assembly; 110. an ad hoc network box body; 120. a first sliding mechanism; 121. a first sliding groove; 122. a first slide bar; 123. a first slider; 124. a bolt connecting block; 130. a second sliding mechanism; 131. a second sliding groove; 132. a second slide bar; 133. a second slider; 140. a communication interface; 150. a power interface; 160. a power control module; 170. a wireless communication module; 180. a processor; 190. a first positioning bolt; 191. a second positioning bolt; 200. a battery case; 210. a battery case body; 220. a vertical groove; 230. a transverse groove; 240. a cushion pad; 300. a first collision avoidance unit; 310. an anti-collision bag mounting plate; 320. a fixing buckle; 330. an anti-collision bag body; 340. a first flexible glue rod; 350. a second soft rubber rod; 360. a vacuum ball; 370. a sealing plug; 400. a second collision avoidance unit; 500. a heat radiation fan; 600. a carrying unit; 610. a back plate; 611. a bottom slot through hole; 620. a supporting plate; 630. a first stop collar; 640. a load reducing mechanism; 641. an anti-vibration plate; 642. stretching the ball; 6421. stretching the ball outer plate; 6422. an inner stretching ball; 6423. a tension spring; 643. stretching the belt; 650. the second limit sleeve; 660. a harness; 670. pulling a belt; 700. a bottom groove.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The embodiment of the invention provides a backpack device for an ad hoc network base station, which comprises an ad hoc network assembly 100, a cooling fan 500, a backpack unit 600 and two groups of storage battery boxes 200. Illustratively, as shown in fig. 1, 2 and 3, the ad hoc network assembly 100 is movably mounted on the backpack unit 600.

The cooling fan 500 is fixedly installed on a side wall of the case of the ad hoc network assembly 100, and the cooling fan 500 is communicated with the inner cavity of the ad hoc network assembly 100.

The two groups of battery boxes 200 are respectively and slidably connected to two side walls of the self-networking assembly 100, which are perpendicular to the cooling fan 500, and the two groups of battery boxes 200 are electrically connected to the self-networking assembly 100. When one group of storage battery boxes 200 is not powered, the storage battery boxes 200 can be automatically switched to the other group of storage battery boxes 200, so that the service time of the ad hoc network assembly 100 is prolonged.

A plurality of groups of first anti-collision units 300 are distributed on the outer wall of the side, close to the cooling fan 500, of the self-networking assembly 100 in a rectangular array, and each group of first anti-collision units 300 are movably clamped with the outer wall of the self-networking assembly 100. The first anti-collision unit 300 can reduce the damage to the ad hoc network assembly 100 caused by external impact.

A plurality of groups of second anti-collision units 400 are distributed on the outer wall of the box body of the storage battery box 200 in a rectangular array, and each group of second anti-collision units 400 are movably clamped with the outer wall of the box body of the storage battery box 200. And the structure of the second collision preventing unit 400 is the same as that of the first collision preventing unit 300. The second collision preventing unit 400 may reduce damage to the battery case 200 caused by external impact.

The bottom groove 700 is formed in the bottom of the outer wall of one side, far away from the first anti-collision unit 300, of the tank body of the ad hoc network assembly 100, the bottom groove 700 is of a fan-shaped structure, and a bottom groove cushion is fixedly mounted on the inner wall of the bottom groove 700.

When the user wears the ad hoc network assembly 100 on the back, the waist of the user is just positioned in the bottom groove 700 of the fan-shaped ring structure, and the waist of the user is protected through the bottom groove 700, so that the waist fatigue caused by long-term wearing of the ad hoc network assembly 100 is reduced.

The ad hoc network assembly 100 includes an ad hoc network box 110, two sets of first sliding mechanisms 120, and two sets of second sliding mechanisms 130. As shown in fig. 4 and 5, the heat dissipation fan 500 is installed on one side wall of the ad hoc network case 110. The two sets of first sliding mechanisms 120 are symmetrically disposed on two sidewalls of the ad hoc network case 110 perpendicular to the cooling fan 500. The two sets of second sliding mechanisms 130 are respectively disposed directly below the two sets of first sliding mechanisms 120. The sides of the first sliding mechanism 120 and the second sliding mechanism 130 far from the ad hoc network box body 110 are fixedly installed on the battery box 200. The battery case 200 may be horizontally moved to a side remote from the heat radiation fan 500 by the first and second sliding mechanisms 120 and 130.

The ad hoc network assembly 100 further includes a power control module 160, a wireless communication module 170, and a processor 180. Illustratively, the power control module 160, the wireless communication module 170, and the processor 180 are fixedly mounted within the ad hoc network housing 110. The ad hoc network box 110 is provided with a plurality of communication interfaces 140, and the plurality of communication interfaces 140 are respectively connected with the power control module 160, the wireless communication module 170 and the processor 180 in a signal manner. A set of power interfaces 150 is disposed under the two sets of second sliding mechanisms 130, and the power control module 160 and the battery case 200 are electrically connected through the power interfaces 150.

The first sliding mechanism 120 includes a first slide bar 122 and a first slider 123. As shown in fig. 6, a first sliding groove 121 is formed on a side wall of the ad hoc network box 110 perpendicular to the cooling fan 500, and the first sliding rod 122 is fixedly installed in the first sliding groove 121. One end of the first slider 123 is slidably connected to the first sliding rod 122, and the other end of the first slider 123 penetrates through the first sliding groove 121 and is fixedly mounted on the housing of the battery case 200. The top of the first slider 123 is fixedly provided with a bolt connection block 124.

The second sliding mechanism 130 includes a second slide bar 132 and a second slider 133. As shown in fig. 7, a second sliding groove 131 is formed on a side wall of the ad hoc network box 110 perpendicular to the cooling fan 500, and the second sliding groove 131 is located right below the first sliding groove 121. The second sliding rod 132 is fixedly installed in the second sliding groove 131. One end of the second slider 133 is slidably connected to the second slide bar 132, and the other end of the second slider 133 penetrates through the second sliding groove 131, and is fixedly mounted on the housing of the battery case 200.

As shown in fig. 4 and 5, a set of first positioning bolts 190 are respectively disposed at two side edges of the top of the ad hoc network box 110, and the bottoms of the first positioning bolts 190 may penetrate into the first sliding grooves 121 and be screwed onto the bolt connection blocks 124. The side of the first positioning bolt 190 away from the cooling fan 500 is provided with a second positioning bolt 191, and the bottom of the second positioning bolt 191 may penetrate into the first sliding groove 121 and be screwed on the bolt connection block 124.

When the ad hoc network assembly 100 is in a stationary state, the two sets of battery boxes 200 are in a parallel state with the ad hoc network box body 110, and the bottoms of the two sets of first positioning bolts 190 are respectively screwed on the two sets of bolt connecting blocks 124.

For example, as shown in fig. 8, when the ad hoc network assembly 100 needs to be carried on the back, the first positioning bolts 190 are first taken out from the bolt connection blocks 124, and then the two sets of battery boxes 200 are simultaneously pushed horizontally to the side far from the heat dissipation fan 500. So that the first slider 123 and the second slider 133 slide on the first slide bar 122 and the second slide bar 132, respectively, when the bolt connection block 124 moves to the right under the second positioning bolt 191, the pushing is stopped, and then the bottom of the second positioning bolt 191 is screwed on the bolt connection block 124, so as to prevent the displacement of the battery case 200 due to vibration when the ad hoc network assembly 100 moves.

After the operation is completed, the user wears the backpack 600 on his/her shoulder so that the self-organizing net cage 110 can be attached to the user's back. The weight of the battery case 200 is then moved forward to both sides of the user by moving the battery case 200 so that the user is more evenly stressed on the back and both sides while the piggyback ad hoc network assembly 100 is moved. The bearing force of the back is reduced, the risk of backward tilting is reduced, and the load feeling of a user when the user is carried on the back is reduced.

The battery case 200 includes a battery case body 210. As shown in fig. 9, the battery case body 210 is fixedly connected to the first slider 123 and the second slider 133. And the battery case body 210 can horizontally move to a side of the ad hoc network case body 110 far from the cooling fan 500 through the first slider 123 and the second slider 133. The outer wall of one side of the storage battery box body 210, which is close to the self-organizing net box body 110, is provided with a vertical groove 220, the bottom of the vertical groove 220 is communicated with a horizontal groove 230, and the other end of the horizontal groove 230 extends to one side far away from the cooling fan 500 and is in an open structure. The inner walls of the vertical grooves 220 and the horizontal grooves 230 are fixedly provided with buffer cushions 240.

When the movement of the battery case body 210 is completed, the user can place the double arms in the horizontal grooves 230 and the vertical grooves 220 at both sides, respectively, and not only can the weight of the battery case 200 be further shared by the double arms, thereby reducing the bearing force of the back. And simultaneously, the abrasion of the battery box body 210 to the skin of the two arms can be avoided, so that the comfort level of a user when the user carries the battery box is improved.

The first crash unit 300 includes a crash bag mounting plate 310, a crash bag body 330, a plurality of sets of first flexible glue sticks 340, and a plurality of sets of second flexible glue sticks 350. As shown in fig. 10, a fixing buckle 320 is fixedly installed on a side wall of the anti-collision bag mounting plate 310, which is close to the ad hoc network box 110, and the anti-collision bag mounting plate 310 is movably clamped on the outer wall of the ad hoc network box 110 through the fixing buckle 320. The anti-collision bag body 330 is fixedly mounted on a side wall of the anti-collision bag mounting plate 310 away from the fixing buckle 320. The first soft rubber rods 340 and the second soft rubber rods 350 are distributed in the anti-collision bag body 330 in rectangular arrays, and the first soft rubber rods 340 and the second soft rubber rods 350 are vertically arranged. The vacuum ball 360 is fixedly installed at the joint of the first soft rubber rod 340 and the second soft rubber rod 350. A sealing plug 370 is fixedly mounted on a side wall of the airbag mounting plate 310 away from the airbag body 330.

When the ad hoc network box 110 is impacted by external force, the ad hoc network box is firstly contacted with the anti-collision bag body 330 and transmits the impact force to one or more groups of first soft rubber rods 340 and second soft rubber rods 350 corresponding to the anti-collision bag body, and then the impact force is immediately dispersed to the other groups of first soft rubber rods 340 and second soft rubber rods 350 due to the fact that the first soft rubber rods 340 and the second soft rubber rods 350 are distributed in a rectangular array and are mutually crossed. At the same time, the impact force is further absorbed by the respective sets of vacuum balls 360 located at the junction of the first and second soft rubber sticks 340 and 350, thereby improving the buffering force of the first crash unit 300. And the anti-collision bag mounting plate 310 is movably clamped with the self-organizing net cage body 110 through the fixing buckle 320, and when one group of the first anti-collision units 300 is damaged, only the group of the first anti-collision units 300 is required to be independently taken down and replaced.

The backpack unit 600 includes a back plate 610, a pallet 620, a first stop collar 630, and a second stop collar 650. As shown in fig. 11 and 12, the supporting plate 620 is fixedly installed at the bottom edge of a sidewall of the carrying plate 610, and a supporting plate limiting groove is formed in the supporting plate 620. The ad hoc network box 110 is located in the pallet limiting groove. The back carrying plate 610 has a fan-shaped ring structure on a side wall far away from the supporting plate 620, and a bottom slot through hole 611 is formed at the bottom. Two groups of braces 660 are symmetrically arranged on two sides of the bottom groove through hole 611, a group of pull belts 670 are arranged on the two groups of braces 660, and the other ends of the pull belts 670 are movably arranged on the storage battery box body 210. The edge of one side of the supporting plate 620 far away from the back plate 610 is movably clamped with a first limit sleeve 630, the top of the first limit sleeve 630 is provided with a load reducing mechanism 640, and the top of the load reducing mechanism 640 is fixedly connected with a second limit sleeve 650. The other end of the second stop collar 650 is movably clamped on the back plate 610.

The relief mechanism 640 includes a tension ball 642 and two sets of shock-resistant plates 641. As shown in fig. 13 and 14, two sets of the shock-resistant plates 641 are symmetrically mounted on opposite side walls of the first stop collar 630 and the second stop collar 650. And a gap is provided between the two sets of the shock-resistant plates 641, in which the tension balls 642 are located. The stretching ball 642 comprises a plurality of groups of stretching ball outer plates 6421 with fan-shaped ring structures, the groups of stretching ball outer plates 6421 can form a sphere-shaped structure, and gaps are arranged between two adjacent groups of stretching ball outer plates 6421. An inner stretching ball 6422 is arranged in the spherical structure, and the center point of the inner stretching ball 6422 coincides with the center point of the spherical structure. A set of extension springs 6423 are arranged on the inner wall of each set of extension ball outer plate 6421, and the other ends of the extension springs 6423 are fixedly arranged on the outer wall of the inner extension ball 6422. Two groups of stretching belts 643 are fixedly arranged on each group of stretching ball outer plates 6421, and the two groups of stretching belts 643 are respectively and fixedly arranged on the two groups of shock-resistant plates 641.

When the ad hoc network assembly 100 needs to be moved, the ad hoc network box 110 is first placed in the pallet limiting groove, and then one ends of the first limiting sleeve 630 and the second limiting sleeve 650, which are far away from each other, are respectively clamped on the pallet 620 and the back bearing plate 610. So that the first stop collar 630 and the second stop collar 650 can implement a stop function on the ad hoc network box body 110. The harness 660 is then carried on the wearer, and after the two sets of battery case bodies 210 are unfolded, the two sets of pull straps 670 are respectively mounted on the two sets of battery case bodies 210. When a wearer walks, the bumping force generated by the self-organizing net cage body 110 is transmitted to the first limit sleeve 630 and the second limit sleeve 650 due to vibration and acts on the stretching ball outer plates 6421, the distance between the stretching ball outer plates 6421 of each group is changed, then the bumping force generated during walking is absorbed through the group of stretching springs 6423 in the corresponding direction with the bumping force, so that the pulling caused by bumping can not directly act on the wearer, and then the weight of the self-organizing net cage body 110 is redispersed to the two groups of storage battery cage bodies 210 through the two groups of stretching belts 670, so that the overall balance of the device is further improved, the stability of the self-organizing net cage body 110 during movement is also improved, and the comfort of the wearer during the device is improved.

The invention also provides a distance measurement infinite jump MESH communication system using the knapsack device for the self-organizing network base station, and the specific working principle of the distance measurement infinite jump MESH communication system is shown as the specific description in the embodiment of the knapsack device for the self-organizing network base station.

The backpack device for the self-networking base station and the ranging infinite jump MESH communication system transmit the bumping force generated by the self-networking box body to the stretching ball outer plates due to vibration, so that the distance between the stretching ball outer plates is changed, the bumping force generated during walking is absorbed through the group of stretching springs in the direction corresponding to the bumping force, the pulling caused by bumping cannot directly act on a wearer, then the weight of the self-networking box body is redispersed on the two groups of storage battery box bodies through the two groups of stretching belts, the overall balance of the device is further improved, the stability of the self-networking box body during moving is also improved, and therefore the comfort of the wearer during the backpack device is improved.

When the self-organizing net assembly needs to be carried and moved, the two groups of storage battery boxes are firstly horizontally moved to one side close to the carrying strap through the first sliding mechanism. When a user wears the ad hoc network assembly on the back, the weight of the two sets of storage battery boxes can move forward from the back of the user to the two sides. So that the stress on the back and the two sides is more even when a user carries the ad hoc network assembly to move. The bearing force of the back is reduced, the risk of backward tilting is reduced, and the load feeling of a user when the user is carried on the back is reduced.

When the self-organized net cage body is impacted by external force, the self-organized net cage body is firstly contacted with the anti-collision bag body, impact force is transmitted to one or more groups of first flexible glue rods and second flexible glue rods corresponding to the self-organized net cage body, and the first flexible glue rods and the second flexible glue rods are arranged in a mutually crossing manner, so that the impact force can be immediately dispersed to other groups of first flexible glue rods and second flexible glue rods. And the impact force is further absorbed by utilizing each group of vacuum balls, so that the buffer force of the first anti-collision unit is improved. And the anti-collision bag mounting plate is movably clamped with the self-organizing net cage body through the fixed buckle, and when one group of the first anti-collision units are damaged, only the group of the first anti-collision units are required to be taken down and replaced independently.

When a user carries the self-networking assembly, the double arms can be respectively placed in the transverse grooves and the vertical grooves on the two sides, so that the weight of the storage battery box can be further shared through the double arms, and the bearing capacity of the back is reduced. Meanwhile, the abrasion of the storage battery box body to the skin of the double arms can be avoided, so that the comfort level of a user during carrying is improved. And the waist of the user is just positioned in the bottom groove of the fan-shaped ring structure, and the waist of the user is protected through the bottom groove, so that the waist fatigue caused by long-term carrying of the ad hoc network assembly is reduced.

Although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (8)

1. The utility model provides a backpack device for self-organizing network basic station which characterized in that: comprising an ad hoc network assembly (100) and a backpack unit (600), the backpack unit (600) comprising a back plate (610); a supporting plate (620) is arranged at the bottom of one side wall of the backpack plate (610), and the box body of the self-networking assembly (100) is positioned on the supporting plate (620); two groups of braces (660) are arranged on the other side wall of the back carrying plate (610), a first limit sleeve (630) is movably clamped at the edge of one side, far away from the back carrying plate (610), of the supporting plate (620), a second limit sleeve (650) is arranged at the top of the first limit sleeve (630), the other end of the second limit sleeve (650) is movably clamped on the back carrying plate (610), and a load reducing mechanism (640) is arranged between the first limit sleeve (630) and the second limit sleeve (650);

the load reducing mechanism (640) comprises a stretching ball (642) and two groups of shock-resistant plates (641), and the two groups of shock-resistant plates (641) are symmetrically arranged on two opposite side walls of the first limit sleeve (630) and the second limit sleeve (650); the stretching balls (642) are positioned in the gaps between the two groups of shock-resistant plates (641); the stretching ball (642) comprises a plurality of groups of stretching ball outer plates (6421) with fan-shaped structures, the groups of stretching ball outer plates (6421) can form a sphere-shaped structure in a combined way, and gaps are arranged between every two adjacent groups of stretching ball outer plates (6421); an inner stretching ball (6422) is arranged in the spherical structure, a group of stretching springs (6423) are arranged on the inner wall of each group of stretching ball outer plates (6421), and the other ends of the stretching springs (6423) are fixedly arranged on the outer wall of the inner stretching ball (6422); two groups of stretching belts (643) are arranged on each group of stretching ball outer plates (6421), and the two groups of stretching belts (643) are respectively arranged on the two groups of shock-resistant plates (641);

the self-networking assembly (100) comprises a self-networking box body (110) and two groups of first sliding mechanisms (120); the two groups of first sliding mechanisms (120) are symmetrically arranged on the two side walls of the self-organizing net cage body (110); two groups of first sliding mechanisms (120) are respectively provided with a group of storage battery boxes (200); a brace (660) is arranged on one side wall of the self-organizing net box body (110) perpendicular to the storage battery box (200); the storage battery box (200) can horizontally slide to one side close to the braces (660) through the first sliding mechanism (120); a group of first positioning bolts (190) are respectively arranged at the edges of the two sides of the top of the self-organizing net cage body (110), and the bottoms of the first positioning bolts (190) are movably arranged on the first sliding mechanism (120); a second positioning bolt (191) is arranged on one side, close to the braces (660), of the first positioning bolt (190), and the bottom of the second positioning bolt (191) is movably arranged on the first sliding mechanism (120);

the first sliding mechanism (120) comprises a first sliding rod (122) and a first sliding block (123); a first sliding groove (121) is formed in one side wall of the self-organizing net box body (110) perpendicular to the braces (660), and the first sliding rod (122) is arranged in the first sliding groove (121); one end of the first sliding block (123) is connected to the first sliding rod (122) in a sliding way, and the other end of the first sliding block (123) penetrates through the outside of the first sliding groove (121) and is arranged on the shell of the storage battery box (200); a bolt connecting block (124) is fixedly arranged at the top of the first sliding block (123); the bottoms of the first positioning bolt (190) and the second positioning bolt (191) can penetrate into the first sliding groove (121) and are connected to the bolt connecting block (124) in a threaded mode.

2. The backpack device for an ad hoc network base station according to claim 1, wherein: a group of second sliding mechanisms (130) are respectively arranged under the two groups of first sliding grooves (121), and each second sliding mechanism (130) comprises a second sliding rod (132) and a second sliding block (133); the second sliding groove (131) is positioned right below the first sliding groove (121), and the second sliding rod (132) is arranged in the second sliding groove (131).

3. The backpack device for an ad hoc network base station according to claim 2, wherein: one end of the second sliding block (133) is slidably connected to the second sliding rod (132), and the other end of the second sliding block (133) penetrates through the second sliding groove (131) and is fixedly mounted on the shell of the storage battery box (200).

4. A piggyback device for an ad hoc network base station according to claim 3, wherein: the ad hoc network assembly (100) further comprises a power supply control module (160), a wireless communication module (170) and a processor (180); the power supply control module (160), the wireless communication module (170) and the processor (180) are fixedly arranged in the ad hoc network box body (110); the ad hoc network box body (110) is provided with a plurality of groups of communication interfaces (140).

5. The backpack device for an ad hoc network base station according to claim 4, wherein: the communication interfaces (140) are respectively connected with the power supply control module (160), the wireless communication module (170) and the processor (180) in a signal manner; and a group of power interfaces (150) are respectively arranged under the two groups of second sliding mechanisms (130), and the power control module (160) is electrically connected with the storage battery box (200) through the power interfaces (150).

6. The backpack device for an ad hoc network base station according to claim 1, wherein: the battery case (200) includes a battery case body (210); the storage battery box body (210) is fixedly connected with the first sliding block (123) and the second sliding block (133); and the storage battery box body (210) can horizontally move to one side, close to the braces (660), of the self-organizing net box body (110) through the first sliding block (123) and the second sliding block (133).

7. The backpack device for an ad hoc network base station according to claim 6, wherein: a vertical groove (220) is formed in the outer wall of one side, close to the self-organizing net box body (110), of the storage battery box body (210), a transverse groove (230) is communicated with the bottom of the vertical groove (220), and the other end of the transverse groove (230) extends to one side, close to the braces (660) and is of an open structure; and buffer cushions (240) are fixedly arranged on the inner walls of the vertical grooves (220) and the horizontal grooves (230).

8. A ranging infinite jump MESH communication system using the backpack apparatus for an ad hoc network base station of any one of claims 1 to 7.

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