CN215812621U - Self-powered monitoring equipment - Google Patents

Abstract

The utility model relates to the technical field of environmental monitoring, and provides self-powered monitoring equipment, which comprises: the monitoring device comprises a monitoring device body and a solar charging device, wherein the monitoring device body comprises a shell provided with a first outer side wall and a rechargeable battery module arranged in the shell; the solar charging device comprises a first unfolding part provided with a solar panel; offer the groove of accomodating that is used for accomodating solar panel on the shell, first expansion portion swing joint is on first lateral wall, and first expansion portion is arranged in breaking away from solar panel from accomodating the groove. The solar charging device solves the energy supply problem of the monitoring equipment, so that the monitoring equipment can continuously and stably work even in remote areas with harsh environment and rare line erection, and the solar charging device can be accommodated in the monitoring equipment, thereby being beneficial to the storage and transportation of the monitoring equipment.

Description

Self-powered monitoring equipment

Technical Field

The utility model relates to the technical field of environmental monitoring, in particular to self-powered monitoring equipment.

Background

The environmental monitoring refers to an action of determining the environmental quality (or the pollution level) or the change trend of the geographic characteristics thereof by measuring the representative value of the factors affecting the environmental quality or the geographic characteristics of the environment. For example, the method tracks the change of the environmental quality and determines the environmental quality level by detecting the content and the discharge of various substances which have influences on human beings and the environment, and provides a foundation and guarantee for the work of environmental management, pollution treatment and the like. For another example, geological deformation information is obtained in real time through monitoring of geographical characteristics of the environment such as earth surface displacement change, soil moisture content or soil pressure and the like, and data monitoring is carried out through a background, so that the purpose of early warning, prevention and control of geological disasters is achieved. In short, understanding the environmental level and monitoring the environment are the prerequisite for developing all the environmental works.

In the related art, various monitoring devices are installed and deployed in places far away from people living or municipal infrastructure, even most of the monitoring devices are located in severe environments such as severe cold and high altitude, the monitoring period is generally long, for example, the monitoring for geological disaster early warning needs to be carried out for a long time, and because the regions generally have no facilities such as municipal circuit erection and the like, the environmental severity does not allow workers to enter the regions frequently to replace battery devices.

Therefore, how to ensure stable energy supply of the monitoring equipment is a problem which needs to be solved urgently.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide self-powered monitoring equipment to solve the problem that the monitoring equipment is inconvenient to power.

In order to achieve the purpose, the utility model provides the following technical scheme: a self-powered monitoring device, comprising:

the monitoring device comprises a monitoring device body, a control device and a control module, wherein the monitoring device body comprises a shell provided with a first outer side wall and a rechargeable battery module arranged in the shell;

the solar charging device comprises a first unfolding part provided with a solar panel;

wherein, offer on the shell and be used for taking in solar panel's storage groove, first expansion swing joint in on the first lateral wall, first expansion is used for with solar panel follow take in the groove breaks away from.

Preferably, still include the telescoping device, the shell includes first casing and sets up the second casing in first casing bottom, first expansion portion sets up on the first casing, the telescoping device is fixed inside the second casing and with first casing bottom is connected, the telescoping device is used for driving first casing rises or descends, so that first expansion portion follows it breaks away from to accomodate the groove.

Preferably, the solar panel comprises a solar panel limiting part, and the solar panel limiting part is fixed to the edge of the accommodating groove.

Preferably, first lateral wall is located first casing, first expansion portion includes swing joint and is in mounting bracket and both ends on the first lateral wall are connected respectively the mounting bracket with first extension spring on the first lateral wall, solar panel swing joint is in on the mounting bracket.

Preferably, still include the second portion of expanding, the second expand the portion including respectively with the fixed second extension spring of mounting bracket and third extension spring, solar panel sets up two, two solar panel passes through respectively the second extension spring with the symmetry pin joint of third extension spring is in on the mounting bracket.

Preferably, the mounting bracket is provided with a pin joint frame used for installing the solar panel, the solar panel is provided with a pin joint sleeve corresponding to the pin joint frame, and the solar panel is sleeved on the pin joint sleeve so as to enable the solar panel to be connected with the mounting bracket in a pivoted mode.

Preferably, the monitoring device further comprises a supporting device connected with the monitoring device body and used for supporting the monitoring device body.

Preferably, the supporting device includes a supporting leg movably received on the housing and a supporting member connected to the supporting leg and generating a pressing action on the supporting leg and the housing.

Preferably, the housing is provided with a first limiting part corresponding to the supporting leg, and the supporting leg is accommodated in the first limiting part and enclosed outside the housing.

The solar charging device solves the energy supply problem of the monitoring equipment, so that the monitoring equipment can continuously and stably work even in remote areas with harsh environment and rare line erection, and the solar charging device can be accommodated in the monitoring equipment, thereby being beneficial to the storage and transportation of the monitoring equipment.

Drawings

FIG. 1 is a cross-sectional view from one perspective of a self-powered monitoring device of the present invention;

FIG. 2 is an exploded view of a self-powered monitoring device of the present invention;

FIG. 3 is an enlarged view taken at A in FIG. 2;

FIG. 4 is an exploded view of the support device of the present invention;

FIG. 5 is an enlarged view of FIG. 4 at B;

FIG. 6 is a schematic view of the support device of the present invention fixed to the housing;

FIG. 7 is an enlarged view at C of FIG. 6;

FIG. 8 is an exploded view of the solar charging device of the present invention;

FIG. 9 is a schematic diagram of a self-powered monitoring device in a standby state according to the present invention;

FIG. 10 is a schematic view of a self-powered monitoring device according to the present invention in an extended position.

Reference numerals:

10. monitoring the equipment body; 20. a signal transceiver; 30. a telescoping device; 301. a telescopic rod; 302. a drive assembly; 3021. a drive assembly fixing plate; 40. a support device; 101. a housing; 41. supporting legs; 410. a support plate; 411. reinforcing ribs; 42. a support member; 422. a torsion spring; 4210. a first fixed seat; 4211. fixing the pile; 42110. a fixing hole; 4212. connecting the upper cover; 4213. connecting a lower cover; 412. a second fixed seat; 4221. a first leg; 4222. a second leg; 4223. a connecting portion; 4224. a fixing ring; 51. a first outer side wall; 52. a protective cover; 53. a fixed cylinder; 54. the telescopic rod is connected with the plate; 500. a control main board; 60. a first limit piece; 70. a battery module; 80. a solar charging device; 800. a solar panel; 81. a first unfolding portion; 1011. a receiving groove; 88. a solar panel limiting part; 810. a mounting frame; 811. a first tension spring; 82. a second development part; 820. a second tension spring; 821. a third tension spring; 823. mounting a rod; 824. a pin joint frame; 888. a pin joint sleeve; 100. sensor module.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the 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 application.

As shown in fig. 1-10, the present embodiment provides a self-powered monitoring device, comprising: the monitoring device comprises a monitoring device body 10 and a solar charging device 80, wherein the monitoring device body 10 comprises a shell 101 provided with a first outer side wall 51 and a rechargeable battery module 70 arranged in the shell 101; the solar charging device 80 includes a first expansion portion 81 provided with a solar panel 800 and charging modules respectively connected with the solar panel 800 and the battery module 70; the housing 101 is provided with a receiving groove 1011 for receiving the solar panel 800, the first extending portion 81 is movably connected to the first outer sidewall 51, and the first extending portion 81 is used for separating the solar panel 800 from the receiving groove 1011. Alternatively, the triggering manner for disengaging the first unfolding portion 81 from the receiving groove 1011 may be that an electromagnetic switch is disposed between the first unfolding portion 81 and the monitoring apparatus body 10, and the electromagnetic switch is controlled to be turned on at a specific condition or a specific time point by a remote control or a time delay chip, so as to release the solar panel 800 located in the receiving groove 1011. Optionally, two sets of solar charging devices 80 are disposed, and the two sets of solar charging devices 80 are oppositely disposed on the first outer side wall 51.

As shown in fig. 1-2, it is preferable that the telescopic device 30 is further included, the housing 101 includes a first housing and a second housing disposed at the bottom of the first housing, the first unfolding portion 81 is disposed on the first housing, the telescopic device 30 is fixed inside the second housing and connected to the bottom of the first housing, and the telescopic device 30 is configured to drive the first housing to ascend or descend, so that the first unfolding portion 81 is detached from the receiving groove 1011. Optionally, the telescopic device 30 comprises a telescopic rod 301 and a driving assembly 302 connected to the telescopic rod 301. The monitoring device body 10 further comprises a control main board 500 arranged in the first shell and a signal transceiver 20 connected with the control main board 500 and the battery module 70, the second shell is of a hollow sleeve-shaped structure with an upper opening and a lower opening, the first shell comprises a fixed cylinder 53 of a hollow cylinder structure with a lower opening and a protective cover 52 packaged at the top of the fixed cylinder 53, the control main board 500 is fixed in the fixed cylinder 53, and the signal transceiver 20 is fixed at the top of the fixed cylinder 53 and packaged and fixed by the protective cover 52. The bottom of the fixed cylinder 53 is packaged with an expansion link connecting plate 54, and the expansion link connecting plate 54 is used for connecting the expansion link 301 and enabling the first housing fixed on the expansion link 301, the control main board 500 packaged in the first housing, and the signal transceiver 20 to ascend or descend under the driving of the expansion link 301.

As shown in fig. 1 to 10, it is preferable that a solar panel position limiting member 88 is further included, and the solar panel position limiting member 88 is fixed to the edge of the receiving groove 1011. First lateral wall 51 is located first casing, and first expansion portion 81 includes mounting bracket 810 and the first extension spring 811 that both ends are connected respectively on mounting bracket 810 and first lateral wall 51 on swing joint on first lateral wall 51, and solar panel 800 swing joint is on mounting bracket 810. Optionally, a mounting rod 823 is fixed to the mounting frame 810, a pull ring is arranged on the mounting rod 823, one end of the first tension spring 811 is fixed to the first outer side wall 51, and the other end of the first tension spring is fixed to the pull ring.

As shown in fig. 1 to 8, it is preferable that the solar panel further includes a second extending portion 82, the second extending portion 82 includes a second extension spring 820 and a third extension spring 821 fixed to the mounting bracket 810, respectively, two solar panels 800 are provided, and the two solar panels 800 are symmetrically pivoted to the mounting bracket 810 through the second extension spring 820 and the third extension spring 821, respectively. The mounting rack 810 is provided with a pivot frame 824 for mounting the solar panel 800, the solar panel 800 is provided with a pivot sleeve 888 corresponding to the pivot frame 824, and the solar panel 800 is sleeved on the pivot sleeve 888 to pivotally connect the solar panel 800 and the mounting rack 810. When this monitoring facilities is in standby state, insert the groove 1011 of accomodating after laminating two solar panel 800 each other, make two solar panel 800 imbed in the shell 101, and make solar panel locating part 88 support and press outside the mounting bracket 810, start when this monitoring facilities, the telescoping device 30 drives first casing part and rises and when making the lower edge of mounting bracket 810 be higher than the top of solar panel locating part 88, the mounting bracket 810 will expand and will take in the solar panel 800 in the shell 101 and take out from accomodating the groove 1011 under the effect of first extension spring 811. When the solar panel 800 is completely released from the receiving groove 1011, the second and third tension springs 820 and 821 unfold the two solar panels 800 in a horizontal state.

As shown in fig. 1 to 7, it is preferable that a supporting device 40 connected to the monitoring apparatus body 10 and supporting the monitoring apparatus body 10 is further included. The supporting device 40 includes a supporting leg 41 movably received on the housing 101 and a supporting member 42 connected to the supporting leg 41 and pressing the supporting leg 41 and the housing 101. The supporting legs 41 and the supporting pieces 42 correspond to each other one by one, and multiple groups can be set as required, and the monitoring device body 10 can be stably supported and fixed by the supporting device 40 only by ensuring that the multiple groups of supporting legs 41 and the supporting pieces 42 are uniformly distributed on the casing 101. In the present embodiment, the supporting feet 41 and the supporting pieces 42 are each provided in 8 sets. The housing 101 is provided with a first stopper 60 corresponding to the supporting leg 41, and the supporting leg 41 is received in the first stopper 60 and enclosed outside the housing 101. Optionally, the supporting member 42 includes a connecting housing fixedly connected to the casing 101 and a torsion spring 422 fixed on the connecting housing, and the supporting leg 41 is pivotally connected to the connecting housing through the torsion spring 422. The connecting shell comprises an upper cover 4212 fixed with the bottom of the second shell and a lower connecting cover 4213 arranged below the upper cover 4212 and used for supporting the supporting piece 42 and the supporting legs 41, and a first fixing seat 4210 and a fixing pile 4211 are arranged on the upper cover 4212. The supporting leg 41 includes a supporting plate 410 and a reinforcing rib 411 fixed on the supporting plate 410, and the second fixing seat 412 is disposed at one end of the supporting plate 410 fixed to the connecting housing. The torsion spring 422 includes a first leg 4221 fixedly connected with the spud 4211, a second leg 4222 fixedly connected with the support plate 410, and a connecting portion 4223 for connecting the first leg 4221 and the second leg 4222; the supporting foot 41 is pivotally connected to the first fixing seat 4210 through the second fixing seat 412 and the connecting portion 4223. Optionally, the fixing pile 4211 is provided with a fixing hole 42110, the end of the first leg 4221 away from the connecting portion 4223 is provided with a fixing hook, the end of the second leg 4222 away from the connecting portion 4223 is provided with a fixing ring 4224, when the support device 40 is assembled, the fixing hook is clamped in the fixing hole 42110, the fixing ring 4224 is sleeved outside the support plate 410 and the reinforcing rib 411, and the first fixing seat 4210, the second fixing seat 412 and the connecting portion 4223 are connected in a pivoting manner through a connecting shaft. Alternatively, the triggering of the support device 40 may also be based on a similar technical principle as the deployment of the solar charging device 80 described above. Optionally, the solar panel limiting member 88 and the first limiting member 60 both adopt an "L" shaped plate structure, the limiting depth of the solar panel limiting member 88 is greater than that of the first limiting member 60, when the expansion device 30 drives the first housing to rise above the lower edge of the first limiting member 60, the supporting plate 410 will be separated from the first limiting member 60, and thereafter, the expansion device 30 continues to rise until the first extending portion 81 is separated from the solar panel limiting member 88. This arrangement allows the support device 40 to be opened first, and the solar panel 800 to be unfolded after the support step is completed. Alternatively, the supporting device 40 may also adopt other triggering manners, such as setting an electromagnetic switch between the supporting leg 41 and the monitoring device body 10, and controlling the electromagnetic switch to open under a specific condition or at a specific time point through a remote control or a time delay chip, so as to release the supporting leg 41 located in the first limiting member 60.

As shown in fig. 1-2, alternatively, the driving assembly 302 is a stepping motor, the telescopic rod 301 is a lead screw, and the lead screw is connected to an output shaft of the stepping motor and is controlled to ascend or descend by controlling the operation of the stepping motor. The battery module 70 is fixed below the driving assembly 302 and separated by a driving assembly fixing plate 3021, a bottom plate is packaged at the bottom of the battery module 70 and fixed at the top of the upper cover 4212, and an accommodating space is formed between the bottom plate and the upper cover 4212.

In another embodiment, the driving assembly 302 may also be a telescopic cylinder, and the telescopic rod 301 may be a piston rod.

Optionally, the monitoring device of the present invention may be installed in a throwing manner, for example, the monitoring device is transported above a designated throwing point by an unmanned aerial vehicle, and is thrown to the ground after being lowered to a suitable height, and then the telescopic device 30 is started by remote control, so that the support device 40 is opened and the ground grasping operation is completed, and when the monitoring device is vertically fixed on the ground surface, the solar charging device 80 is subsequently opened. Based on the requirement of throwing, the casing 101, the fixed cylinder 53, the protective cover 52, the supporting device 40 and the like are made of high-strength and drop-resistant materials.

In conclusion, the solar charging device 80 is arranged, so that the energy supply problem of the monitoring equipment is solved, and the long-term stable monitoring work of the monitoring equipment is ensured. In addition, the utility model is also provided with the telescopic device 30 connected with the signal transceiver 20, so that the monitoring equipment can still adjust the height of the signal transceiver 20 through the telescopic device 30 after being installed and fixed, the effect that the better communication signal can still be kept when the overall size of the monitoring equipment is not changed but the signal is enhanced or reduced is achieved, the monitoring equipment with stable communication signal and convenient transportation is provided, and the problems that the monitoring equipment is inconvenient to transport due to the overlarge size and the communication signal is influenced due to the undersize size are effectively solved. In addition, the utility model is also provided with a supporting device 40 for keeping the monitoring equipment in an upright fixed state, which can enable the monitoring equipment thrown to the ground to be automatically righted so as to ensure that the monitoring equipment can be vertically arranged on the ground, and further, the supporting device 40 and the solar charging device 80 are both provided with storage structures, so that the monitoring equipment is stored in the detection equipment or coated on the surface of the monitoring equipment in a standby state, thereby not only playing a role of protecting the monitoring equipment, but also being beneficial to the storage and transportation of the monitoring equipment.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solutions of the present application, and not to limit the same; although the present application 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 solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not necessarily depart from the spirit and scope of the corresponding technical solutions in the embodiments of the present application.

Claims (9)

1. A self-powered monitoring device, comprising:

the monitoring device comprises a monitoring device body, a control device and a control module, wherein the monitoring device body comprises a shell provided with a first outer side wall and a rechargeable battery module arranged in the shell;

the solar charging device comprises a first expansion part provided with a solar panel and a charging module respectively connected with the solar panel and the battery module;

wherein, offer on the shell and be used for taking in solar panel's storage groove, first expansion swing joint in on the first lateral wall, first expansion is used for with solar panel follow take in the groove breaks away from.

2. The self-powered monitoring device according to claim 1, further comprising a telescopic device, wherein the housing comprises a first housing and a second housing disposed at the bottom of the first housing, the first extending portion is disposed on the first housing, the telescopic device is fixed inside the second housing and connected to the bottom of the first housing, and the telescopic device is configured to drive the first housing to ascend or descend, so that the first extending portion is separated from the accommodating groove.

3. The self-powered monitoring device according to claim 1 or 2, further comprising a solar panel limiting member fixed to an edge of the receiving groove.

4. The self-powered monitoring device of claim 2, wherein the first outer side wall is provided on the first housing, the first unfolding portion comprises a mounting frame movably connected to the first outer side wall and a first tension spring with two ends connected to the mounting frame and the first outer side wall respectively, and the solar panel is movably connected to the mounting frame.

5. The self-powered monitoring device of claim 4, further comprising a second unfolding portion, wherein the second unfolding portion comprises a second tension spring and a third tension spring which are fixed to the mounting frame respectively, the number of the solar panels is two, and the two solar panels are symmetrically pivoted on the mounting frame through the second tension spring and the third tension spring respectively.

6. The self-powered monitoring device of claim 4, wherein the mounting rack is provided with a pin joint frame for mounting the solar panel, the solar panel is provided with a pin joint sleeve corresponding to the pin joint frame, and the solar panel is sleeved on the pin joint sleeve so as to be connected with the mounting rack in a pivot mode.

7. The self-powered monitoring device of claim 1, further comprising a support device coupled to the monitoring device body and configured to support the monitoring device body.

8. The self-powered monitoring device of claim 7, wherein the supporting means comprises a supporting leg movably received in the housing and a supporting member connected to the supporting leg and pressing against the supporting leg and the housing.

9. The self-powered monitoring device of claim 8, wherein the housing is provided with a first stop member corresponding to the supporting leg, and the supporting leg is received in the first stop member and enclosed outside the housing.

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