CN115003133B

CN115003133B - Terminal data acquisition device applied to intelligent energy management control system

Info

Publication number: CN115003133B
Application number: CN202210809083.3A
Authority: CN
Inventors: 陈志坚; 孙浩; 吉小恒; 吴永琴
Original assignee: China Energy Engineering Group Guangdong Electric Power Design Institute Co Ltd
Current assignee: China Energy Engineering Group Guangdong Electric Power Design Institute Co Ltd
Priority date: 2022-07-11
Filing date: 2022-07-11
Publication date: 2023-09-12
Anticipated expiration: 2042-07-11
Also published as: CN115003133A

Abstract

The invention discloses a terminal data acquisition device applied to an intelligent energy management control system, which comprises a shell, wherein a top cover is covered at an opening at the top of the shell, a bottom plate is arranged at the bottom of the shell, and the bottom surface of the shell is fixedly connected with the top surface of the bottom plate by utilizing two convex blocks. According to the invention, the connecting rod is driven by the inner side end of the movable rod at the front side part to move in the process of limiting the plate to move in the movable groove, the connecting rod at the front side part drives the second bracket at the front side part to move by using the inclined plate, when the second bracket moves synchronously with the connecting rod at the front side part, the rack at the bottom of the inner side of the second bracket is meshed with the gear at the inner side of the cylindrical block, so that the whole cylindrical block rotates, the cylindrical block rotates clockwise under the meshing fit of the rack at the front side part and the gear, the cylindrical block drives the heat dissipation fan to rotate clockwise in the shell by using the rotary rod, and the heat inside the shell is conveniently discharged through the heat dissipation groove by using the effect of the clockwise rotation of the two heat dissipation fans, so that the heat dissipation effect of the whole shell is improved.

Description

Terminal data acquisition device applied to intelligent energy management control system

Technical Field

The invention belongs to the technical field of data acquisition devices, and particularly relates to a terminal data acquisition device applied to an intelligent energy management control system.

Background

The energy management control system helps industrial production enterprises to reasonably plan and utilize energy while expanding production, reduces energy consumption of unit products and improves economic benefits. Along with the development of the internet of things, the internet of things technology is combined with an energy management control system, and various information sensors are utilized, so that the management of the energy management control system is facilitated.

The existing data acquisition device is generally installed in a shell, a top cover is generally installed outside the existing data acquisition device, heat can be generated when the data acquisition device works, heat dissipation of the data acquisition device is generally achieved through the arrangement of a heat dissipation net, but the heat dissipation efficiency of the heat dissipation net is low, heat in the shell cannot be quickly discharged, and the service life of the data acquisition device is influenced.

Therefore, it is necessary to solve the above problems by providing a terminal data acquisition device for an intelligent energy management control system.

Disclosure of Invention

In view of the above problems, the present invention provides a terminal data acquisition device applied to an intelligent energy management control system, so as to solve the problems set forth in the background art.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a be applied to wisdom energy management control system's terminal data acquisition device, includes the casing, casing open-top lid has put the top cap, the casing bottom is provided with the bottom plate, and the bottom surface of casing utilizes two lugs and bottom plate top surface fixed connection, the top surface side all around of bottom plate is provided with the ring limit, the inside of casing is provided with the standing groove, and the inside collection system body that is provided with of standing groove, and the standing groove both ends all are provided with heat abstractor, and two heat abstractors correspond collection system body both sides respectively, the both ends of casing all are provided with the curb plate, and the front and back both sides of casing all are provided with to board, and correspond to be connected to the side of board with a plurality of rubber strips, curb plate and to board medial surface all do not contact with the casing lateral surface, and correspond to be connected to board medial surface bottom with the casing bottom through buffer.

Further, the side plate and the plate are made of elastic rubber materials, the side plate and the plate are annularly wrapped on the outer side face of the shell by a plurality of rubber strips, the side plate and the plate are located on the inner side of the annular edge of the bottom plate, and the outer side face of the side plate and the outer side face of the plate are not in contact with the inner side face of the annular edge.

Further, heat abstractor includes a plurality of blades and bull stick, bull stick inboard end circumference side fixedly connected with a plurality of blades, and the heat dissipation fan that a plurality of blades formed corresponds with collection system body side, the both sides end bottom of casing is provided with the logical groove that corresponds with the bull stick, bull stick through hole groove, and the both sides end bottom of casing all is provided with a plurality of equidistance and sets up the heat dissipation groove side by side, the heat dissipation fan corresponds the setting with the heat dissipation groove.

Further, buffer includes three underframe, and the crisscross correspondence of three underframe and two lugs is fixed in the casing bottom surface, the both sides face of underframe all is provided with the bar groove, both ends all run through around the underframe and are provided with the movable rod, movable rod outside end and to inboard bottom fixed connection of the face bottom, the movable rod inboard end is in the movable storehouse of underframe inside, and movable rod inboard end and movable storehouse sliding fit, the spring has been cup jointed on the movable rod surface, and the spring is in the underframe outside, and the spring both ends respectively with underframe lateral surface and to inboard laminating of face.

Further, limiting plates are arranged on two sides of the bottom of the shell, connecting frames are fixedly connected to the inner side faces of the limiting plates, the inner ends of the connecting frames are located in the movable bin, the inner ends of the connecting frames are movably sleeved on the surface of the movable rod, the two connecting frames are correspondingly matched with the two end parts of the strip groove respectively, and the bottom frame utilizes the strip groove to limit the limiting plates of the end parts of the connecting frames.

Further, the surface of limiting plate is provided with the movable groove, and the movable groove both ends all run through and are provided with the connecting rod, two connecting rods and two movable rods one-to-one, connecting rod inboard end passes through movable groove and strip groove and movable rod inboard end fixed connection, and two equal fixedly connected with swash plate of connecting rod outside ends, and two swash plates set up with the central line symmetry of casing.

Further, heat abstractor still includes first support and second support, and first support and second support's whole appearance all sets up to U type structure, and first support and second support set up relatively, and first support and second support correspond the cooperation with two swash plate tops respectively, the end connection department of first support and the end connection department of second support respectively with the lateral surface and the medial surface fixed connection on two swash plate tops, bull stick outside end fixedly connected with cylinder piece, and the cylinder piece runs through the middle part of first support and second support in proper order.

Further, the inside top of first support and the inside bottom of second support all are provided with the rack, and the cylinder piece surface is provided with respectively with the rack of first support and second support correspond complex gear, the inside bottom of first support and the inside top of second support all are provided with the spout, and gear and spout sliding fit.

Further, a plurality of leak holes are formed in the bottom of the surface of the side plate, and the leak holes correspond to the heat dissipation grooves one by one.

The invention has the technical effects and advantages that:

1. according to the invention, the connecting rod is driven by the inner side end of the movable rod at the front side part to move in the process of limiting the plate to move in the movable groove, the connecting rod at the front side part drives the second bracket at the front side part to move by using the inclined plate, when the second bracket moves synchronously with the connecting rod at the front side part, the rack at the bottom of the inner side of the second bracket is meshed with the gear at the inner side of the cylindrical block, so that the whole cylindrical block rotates, the cylindrical block rotates clockwise under the meshing fit of the rack at the front side part and the gear, the cylindrical block drives the heat dissipation fan to rotate clockwise in the shell by using the rotary rod, and the heat inside the shell is conveniently discharged through the heat dissipation groove by using the effect of the clockwise rotation of the two heat dissipation fans, so that the heat dissipation effect of the whole shell is improved.

2. After the impact force of the parts on the plates is eliminated, the springs on the front side and the rear side rebound, the plates on the front side and the rear side are far away from the shell, the two movable rods respectively drive the two inclined plates to be separated from each other by using the connecting rods, the two inclined plates respectively drive the first bracket and the second bracket to be separated from each other, the first bracket respectively drives the two gears on the surface of the cylindrical block to rotate anticlockwise by using the rack on the top of the inner side and the rack on the bottom of the inner side by using the rack on the bottom of the inner side, the cylindrical block drives the heat dissipation fan to rotate anticlockwise by using the rotating rod, the heat dissipation fan rotates anticlockwise conveniently to introduce external air into the shell through the heat dissipation groove, and the clockwise and anticlockwise rotation of the heat dissipation fan is utilized to ensure the air circulation in the whole shell, so that the heat dissipation effect of the whole shell is further improved.

3. When the external part impacts on the front side part of the pair of plates, the pair of plates drive the movable rod to synchronously move in the process of approaching the shell, the inner side end of the movable rod moves in the movable bin of the bottom frame, the movable rod gradually enters the movable bin, and the pair of plates are matched with the bottom frame so as to squeeze the springs, and the spring of the front side part is used for absorbing part of impact force of the part of the pair of plates; when the cylinder piece clockwise turn, the clockwise turn's cylinder piece utilizes the rack of outside gear drive first support to remove, first support and second support are close to each other this moment, when first support removed, the swash plate of first support utilization back lateral part and connecting rod drive the movable rod inboard end of back lateral part at the inside activity of movable storehouse, the inboard end of two movable rods is close gradually in the inside movable storehouse this moment, and the movable rod of back lateral part pulling back lateral part is close to the casing to the board, thereby the board of back lateral part extrudees the spring of back lateral part with the underframe cooperation, utilize the dual elasticity effect of front and back both sides spring, further improve the buffering effect to the board, prevent external parts's impact force to the casing surface through the impact to the board.

4. When the external part impacts on the side plate, the elastic force of the side plate can absorb part of impact force, the side plate gradually approaches the shell under the action of the impact force of the part, the side plate extrudes the rubber strips on the side edge of the plate in the process of approaching the shell, the bottom frame limits the position of the plate by utilizing the movable rod, the impact force of the side plate can be prevented from moving through the rubber strips, the residual impact force of the side plate is absorbed by utilizing the rubber strips, the impact force of the part is prevented from impacting the outer side surface of the shell, and after the impact force of the side plate is eliminated, the rubber strips and the elastic force of the side plate restore the side plate to the original state, so that the protection effect of the shell is achieved.

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 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 is a schematic view showing the overall structure of the outer part of the housing according to the embodiment of the present invention;

FIG. 2 shows a schematic view of the internal components of a housing according to an embodiment of the present invention;

FIG. 3 is a schematic view showing the structure of a buffer device at the bottom of a housing according to an embodiment of the present invention;

FIG. 4 shows an enlarged view of the structure of portion A in FIG. 2 in accordance with an embodiment of the present invention;

in the figure: 1. a housing; 2. a top cover; 3. a bottom plate; 4. a bump; 5. a ring edge; 6. a placement groove; 7. a side plate; 8. a plate is arranged; 9. a rubber strip; 10. a blade; 11. a rotating rod; 12. a through groove; 13. a heat sink; 14. a bottom frame; 15. a strip groove; 16. a movable rod; 17. a movable bin; 18. a spring; 19. a limiting plate; 20. a connecting frame; 21. a movable groove; 22. a connecting rod; 23. a sloping plate; 24. a first bracket; 25. a second bracket; 26. a cylindrical block; 27. a rack; 28. a gear; 29. a chute; 30. and (5) a leak hole.

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 invention provides a terminal data acquisition device applied to an intelligent energy management control system, as shown in fig. 1-2, the terminal data acquisition device comprises a shell 1, a top cover 2 is covered at the top opening of the shell 1, a bottom plate 3 is arranged at the bottom of the shell 1, the bottom surface of the shell 1 is fixedly connected with the top surface of the bottom plate 3 by utilizing two convex blocks 4, annular edges 5 are arranged on the peripheral side edges of the top surface of the bottom plate 3, a placing groove 6 is arranged in the shell 1, an acquisition device body is arranged in the placing groove 6, heat dissipation devices are arranged at two ends of the placing groove 6, the two heat dissipation devices respectively correspond to two sides of the acquisition device body, side plates 7 are arranged at two ends of the shell 1, a pair of plates 8 are arranged at the front side and the rear side of the shell 1, the side edges of the pair of plates 8 are correspondingly connected with the side edges of the side plates 7 by utilizing a plurality of rubber strips 9, the inner side surfaces of the side plates 7 and 8 are not contacted with the outer side surfaces of the shell 1, and the inner side surfaces of the pair of plates 8 are correspondingly connected with the bottom of the shell 1 by utilizing buffer devices. Opening top cap 2, placing whole collection system body in the standing groove 6 center department of casing 1, and collection system body both sides correspond the setting with the heat dissipation fan respectively, then put top cap 2 lid in the open top department of casing 1, collection system body passes through heat dissipation groove 13 discharge of heat that produces in the course of the work, avoids the inside high temperature of casing 1.

In fig. 1-3, the side plate 7 and the plate 8 are made of elastic rubber materials, the side plate 7 and the plate 8 are annularly wrapped on the outer side surface of the shell 1 by using a plurality of rubber strips 9, the side plate 7 and the plate 8 are all positioned on the inner side of the annular edge 5 of the bottom plate 3, and neither the outer side surface of the side plate 7 nor the outer side surface of the plate 8 is in contact with the inner side surface of the annular edge 5. When external parts impact on the side plate 7, the elasticity of the side plate 7 can absorb part of impact force, the side plate 7 is gradually close to the shell 1 under the action of the impact force of the parts, the side plate 7 extrudes the rubber strip 9 on the side edge of the plate 8 in the process of being close to the shell 1, the bottom frame 14 limits the position of the plate 8 by utilizing the movable rod 16, the impact force of the side plate 7 can be prevented from being transmitted to the rubber strip 9 to enable the plate 8 to move, the residual impact force of the side plate 7 is absorbed by utilizing the rubber strip 9, the impact force of the parts is prevented from being impacted on the outer side surface of the shell 1, after the impact force of the side plate 7 is eliminated, the rubber strip 9 and the elasticity of the side plate 7 enable the side plate 7 to restore to the original state, and the protection effect on the shell 1 is achieved. The curb plate 7 is being close to the in-process of casing 1, and curb plate 7 itself can be with outside air through radiating groove 13 infusion to casing 1 inside, and the inside air of casing 1 opposite side radiating groove 13 entering casing 1 is discharged again this moment to improve the inside exhaust effect of casing 1, conveniently improve the radiating effect of casing 1.

In fig. 2, the heat dissipating device includes a plurality of blades 10 and a rotating rod 11, the circumferential side surface of the inner side end of the rotating rod 11 is fixedly connected with a plurality of blades 10, and a heat dissipating fan formed by the plurality of blades 10 corresponds to the side end of the collecting device body, through grooves 12 corresponding to the rotating rod 11 are arranged at the bottoms of the two side ends of the shell 1, the rotating rod 11 penetrates through the through grooves 12, a plurality of heat dissipating grooves 13 which are equidistantly arranged in parallel are arranged at the bottoms of the two side ends of the shell 1, and the heat dissipating fan corresponds to the heat dissipating grooves 13. The heat dissipation fan corresponds with the heat dissipation groove 13, and when the heat dissipation fan clockwise rotation, the convenience is through the inside gaseous discharge of heat dissipation groove 13 with casing 1, improves the radiating effect of whole casing 1, and when the heat dissipation fan anticlockwise rotation, the convenience is through inside the outside air lets in casing 1 of heat dissipation groove 13, guarantees the inside gas circulation of casing 1, further strengthens the radiating effect of casing 1.

In fig. 3, the buffering device comprises three bottom frames 14, the three bottom frames 14 and the two protruding blocks 4 are fixed on the bottom surface of the shell 1 in a staggered and corresponding mode, strip grooves 15 are formed in two side surfaces of the bottom frames 14, movable rods 16 are arranged in a penetrating mode at the front end and the rear end of the bottom frames 14, the outer side ends of the movable rods 16 are fixedly connected with the bottoms of the inner side surfaces of the plates 8, the inner side ends of the movable rods 16 are located inside movable bins 17 of the bottom frames 14, the inner side ends of the movable rods 16 are in sliding fit with the movable bins 17, springs 18 are sleeved on the surfaces of the movable rods 16, the springs 18 are located on the outer sides of the bottom frames 14, and the two ends of the springs 18 are respectively attached to the outer side surfaces of the bottom frames 14 and the inner side surfaces of the plates 8. When external components impact on the front-side plate 8, the plate 8 drives the movable rod 16 to synchronously move in the process of approaching the shell 1, the inner side end of the movable rod 16 moves in the movable bin 17 of the bottom frame 14, the movable rod 16 gradually enters the movable bin 17, the plate 8 is matched with the bottom frame 14 so as to squeeze the spring 18, and the spring 18 on the front side is utilized to absorb part of impact force of the components on the plate 8. When the cylindrical block 26 rotates clockwise, the clockwise rotating cylindrical block 26 drives the rack 27 of the first bracket 24 to move by using the outer gear 28, at this time, the first bracket 24 and the second bracket 25 are close to each other, when the first bracket 24 moves, the first bracket 24 drives the inner ends of the movable rods 16 at the rear side to move in the movable bin 17 by using the inclined plate 23 and the connecting rod 22 at the rear side, at this time, the inner ends of the two movable rods 16 are gradually close to each other in the movable bin 17, the movable rods 16 at the rear side pull the plate 8 at the rear side to be close to the shell 1, the plate 8 at the rear side is matched with the bottom frame 14 to squeeze the springs 18 at the rear side, and the buffer effect of the plate 8 is further improved by using the double elastic effect of the springs 18 at the front side and the rear side, so that the impact force of external components is prevented from being impacted on the surface of the shell 1 by the plate 8.

In fig. 3, two sides of the bottom of the housing 1 are respectively provided with a limiting plate 19, the inner side surface of the limiting plate 19 is fixedly connected with a connecting frame 20, the inner side end of the connecting frame 20 is positioned inside the movable bin 17, the inner side end of the connecting frame 20 is movably sleeved on the surface of the movable rod 16, the two connecting frames 20 are respectively correspondingly matched with the two end parts of the strip groove 15, and the bottom frame 14 utilizes the strip groove 15 to limit the limiting plate 19 at the end part of the connecting frame 20. The limiting plate 19 is sleeved at the inner side ends of the two movable rods 16 by the connecting frame 20, when the inner side ends of the movable rods 16 move in the movable bin 17, the limiting plate 19 is limited by the strip groove 15 of the bottom frame 14 by the connecting frame 20, so that the stability of the limiting plate 19 is ensured, and the stable effect of the movable rods 16 moving in the movable bin 17 is ensured by the connecting frame 20 and the bottom frame 14.

In fig. 3, the surface of the limiting plate 19 is provided with a movable slot 21, two ends of the movable slot 21 are respectively provided with a connecting rod 22 in a penetrating manner, two connecting rods 22 are in one-to-one correspondence with two movable rods 16, the inner ends of the connecting rods 22 are fixedly connected with the inner ends of the movable rods 16 through the movable slot 21 and the strip slot 15, the outer ends of the two connecting rods 22 are respectively fixedly connected with an inclined plate 23, and the two inclined plates 23 are symmetrically arranged with the center line of the shell 1. When the movable rod 16 is utilized to drive the connecting rod 22 to move inside the movable groove 21 to the plate 8, the strip groove 15 of the bottom frame 14 can limit the inner side end of the connecting rod 22, the movable groove 21 of the limiting plate 19 limits the outer side part of the connecting rod 22, the connecting rod 22 can drive the inclined plate 23 to stably move, the connecting rod 22 is prevented from generating larger fluctuation in the moving process, and the stability of the first bracket 24 and the second bracket 25 in the moving process is further ensured.

In fig. 3 and 4, the heat dissipation device further includes a first bracket 24 and a second bracket 25, the overall shapes of the first bracket 24 and the second bracket 25 are all set to be U-shaped structures, the first bracket 24 and the second bracket 25 are oppositely arranged, the first bracket 24 and the second bracket 25 are respectively matched with the top ends of the two inclined plates 23 correspondingly, the end connection part of the first bracket 24 and the end connection part of the second bracket 25 are respectively fixedly connected with the outer side surfaces and the inner side surfaces of the top ends of the two inclined plates 23, the outer side ends of the rotating rods 11 are fixedly connected with cylindrical blocks 26, and the cylindrical blocks 26 sequentially penetrate through the middle parts of the first bracket 24 and the second bracket 25. After the impact force of the component pair on the plate 8 is eliminated, the spring 18 on the front side and the rear side rebounds, the plate 8 on the front side and the rear side are far away from the shell 1, the two movable rods 16 respectively drive the two inclined plates 23 to be separated from each other by utilizing the connecting rods 22, the two inclined plates 23 respectively drive the first bracket 24 and the second bracket 25 to be far away from each other, the first bracket 24 respectively drives the two gears 28 on the surface of the cylindrical block 26 to rotate anticlockwise by utilizing the rack 27 on the top of the inner side and the rack 27 on the bottom of the second bracket 25 respectively, the cylindrical block 26 drives the heat dissipation fan to rotate anticlockwise by utilizing the rotating rod 11, the heat dissipation fan rotates anticlockwise conveniently to introduce external air into the shell 1 through the heat dissipation grooves 13, and the clockwise and anticlockwise rotation of the heat dissipation fan is utilized to ensure the air circulation inside the whole shell 1, so that the heat dissipation effect of the whole shell 1 is further improved.

In fig. 4, racks 27 are disposed at the inner top of the first bracket 24 and the inner bottom of the second bracket 25, and gears 28 correspondingly matched with the racks 27 of the first bracket 24 and the second bracket 25 are disposed on the surface of the cylindrical block 26, and sliding grooves 29 are disposed at the inner bottom of the first bracket 24 and the inner top of the second bracket 25, and the gears 28 are slidably matched with the sliding grooves 29. The inner side end of the movable rod 16 at the front side drives the connecting rod 22 to move in the movable groove 21 by the limiting plate 19, the connecting rod 22 at the front side drives the second bracket 25 at the front side to move by the inclined plate 23, when the second bracket 25 moves synchronously with the connecting rod 22 at the front side, at the moment, the sliding groove 29 at the inner side top of the second bracket 25 slides on the surface of the gear 28 at the inner side of the cylindrical block 26, meanwhile, the rack 27 at the inner side bottom of the second bracket 25 is meshed with the gear 28 at the inner side of the cylindrical block 26, so that the whole cylindrical block 26 rotates, the cylindrical block 26 rotates clockwise under the meshing cooperation of the rack 27 at the front side and the gear 28, the cylindrical block 26 drives the heat dissipation fan to rotate clockwise in the shell 1 by the rotary rod 11, and hot air in the shell 1 is conveniently discharged through the heat dissipation groove 13 by the effect of the clockwise rotation of the two heat dissipation fans, so that the heat dissipation effect of the whole shell 1 is improved.

In fig. 1 and 3, a plurality of holes 30 are provided at the bottom of the surface of the side plate 7, and the holes 30 are in one-to-one correspondence with the heat dissipation grooves 13. When the heat inside the shell 1 is discharged through the heat dissipation groove 13, the heat between the side plate 7 and the plate 8 is discharged through the leakage holes 30, so that the heat inside the shell 1 can be conveniently kept away from the inside of the shell 1, and the heat emitted by the shell 1 is prevented from encircling the outer side face of the shell 1.

The working principle of the invention is as follows:

referring to the attached drawings 1-4 of the specification, the top cover 2 is opened, the whole collecting device body is placed at the center of the placing groove 6 of the shell 1, two sides of the collecting device body are respectively and correspondingly provided with the radiating fans, then the top cover 2 is covered at the top opening of the shell 1, and heat generated by the collecting device body in the working process is discharged through the radiating groove 13, so that the temperature inside the shell 1 is prevented from being too high.

When external parts impact on the side plate 7, the elasticity of the side plate 7 can absorb part of impact force, the side plate 7 is gradually close to the shell 1 under the action of the impact force of the parts, the side plate 7 extrudes the rubber strip 9 on the side edge of the plate 8 in the process of being close to the shell 1, the bottom frame 14 limits the position of the plate 8 by utilizing the movable rod 16, the impact force of the side plate 7 can be prevented from being transmitted to the rubber strip 9 to enable the plate 8 to move, the residual impact force of the side plate 7 is absorbed by utilizing the rubber strip 9, the impact force of the parts is prevented from being impacted on the outer side surface of the shell 1, after the impact force of the side plate 7 is eliminated, the rubber strip 9 and the elasticity of the side plate 7 enable the side plate 7 to restore to the original state, and the protection effect on the shell 1 is achieved.

The curb plate 7 is being close to the in-process of casing 1, and curb plate 7 itself can be with outside air through radiating groove 13 infusion to casing 1 inside, and the inside air of casing 1 opposite side radiating groove 13 entering casing 1 is discharged again this moment to improve the inside exhaust effect of casing 1, conveniently improve the radiating effect of casing 1.

When external components impact on the front-side plate 8, the plate 8 drives the movable rod 16 to synchronously move in the process of approaching the shell 1, the inner side end of the movable rod 16 moves in the movable bin 17 of the bottom frame 14, the movable rod 16 gradually enters the movable bin 17, the plate 8 is matched with the bottom frame 14 so as to squeeze the spring 18, and the spring 18 on the front side absorbs part of impact force of the components on the plate 8. The inner side end of the movable rod 16 at the front side drives the connecting rod 22 to move in the movable groove 21 by the limiting plate 19, the connecting rod 22 at the front side drives the second bracket 25 at the front side to move by the inclined plate 23, when the second bracket 25 moves synchronously with the connecting rod 22 at the front side, at the moment, the sliding groove 29 at the inner side top of the second bracket 25 slides on the surface of the gear 28 at the inner side of the cylindrical block 26, meanwhile, the rack 27 at the inner side bottom of the second bracket 25 is meshed with the gear 28 at the inner side of the cylindrical block 26, so that the whole cylindrical block 26 rotates, the cylindrical block 26 rotates clockwise under the meshing cooperation of the rack 27 at the front side and the gear 28, the cylindrical block 26 drives the heat dissipation fan to rotate clockwise in the shell 1 by the rotary rod 11, and hot air in the shell 1 is conveniently discharged through the heat dissipation groove 13 by the effect of the clockwise rotation of the two heat dissipation fans, so that the heat dissipation effect of the whole shell 1 is improved.

When the cylindrical block 26 rotates clockwise, the clockwise rotating cylindrical block 26 drives the rack 27 of the first bracket 24 to move by using the outer gear 28, at this time, the first bracket 24 and the second bracket 25 are close to each other, when the first bracket 24 moves, the first bracket 24 drives the inner ends of the movable rods 16 at the rear side to move in the movable bin 17 by using the inclined plate 23 and the connecting rod 22 at the rear side, at this time, the inner ends of the two movable rods 16 are gradually close to each other in the movable bin 17, the movable rods 16 at the rear side pull the plate 8 at the rear side to be close to the shell 1, the plate 8 at the rear side is matched with the bottom frame 14 to squeeze the springs 18 at the rear side, and the buffer effect of the plate 8 is further improved by using the double elastic effect of the springs 18 at the front side and the rear side, so that the impact force of external components is prevented from being impacted on the surface of the shell 1 by the plate 8.

After the impact force of the component pair on the plate 8 is eliminated, the spring 18 on the front side and the rear side rebounds, the plate 8 on the front side and the rear side are far away from the shell 1, the two movable rods 16 respectively drive the two inclined plates 23 to be separated from each other by using the connecting rod 22, the two inclined plates 23 respectively drive the first bracket 24 and the second bracket 25 to be far away from each other, the first bracket 24 respectively drives the two gears 28 on the surface of the cylindrical block 26 to rotate anticlockwise by using the rack 27 on the top of the inner side and the rack 27 on the bottom of the second bracket 25 respectively, the cylindrical block 26 drives the heat dissipation fan to rotate anticlockwise by using the rotating rod 11, the heat dissipation fan rotates anticlockwise conveniently to introduce outside air into the shell 1 through the heat dissipation groove 13, and the clockwise and anticlockwise rotation of the heat dissipation fan is utilized to ensure the air circulation inside the whole shell 1, so that the heat dissipation effect of the whole shell 1 is further improved.

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

1. Terminal data acquisition device for wisdom energy management control system, including casing (1), its characterized in that: the novel solar cell module is characterized in that a top cover (2) is covered at the top opening of the shell (1), a bottom plate (3) is arranged at the bottom of the shell (1), the bottom surface of the shell (1) is fixedly connected with the top surface of the bottom plate (3) through two convex blocks (4), a ring edge (5) is arranged on the periphery side of the top surface of the bottom plate (3), a placing groove (6) is formed in the shell (1), a collecting device body is arranged in the placing groove (6), heat dissipation devices are arranged at two ends of the placing groove (6), the two heat dissipation devices respectively correspond to two sides of the collecting device body, side plates (7) are arranged at two ends of the shell (1), plates (8) are arranged at the front side and the rear side of the shell (1), the side edges of the plates (8) are correspondingly connected with the side edges of the side plates (7) through a plurality of rubber strips (9), the inner side surfaces of the side plates (7) and the inner side surfaces of the plates (8) are not contacted with the outer side surfaces of the shell (1), and the inner side surfaces of the plates are correspondingly connected with the bottom of the shell (1) through buffer devices;

the buffer device comprises three underframes (14), the three underframes (14) and the two convex blocks (4) are correspondingly fixed on the bottom surface of the shell (1) in a staggered mode, strip grooves (15) are formed in the two side surfaces of the underframe (14), movable rods (16) are arranged at the front end and the rear end of the underframe (14) in a penetrating mode, the outer side ends of the movable rods (16) are fixedly connected with the bottoms of the inner side surfaces of the plates (8), the inner side ends of the movable rods (16) are located in the movable bin (17) of the underframe (14), the inner side ends of the movable rods (16) are in sliding fit with the movable bin (17), springs (18) are sleeved on the surfaces of the movable rods (16), the springs (18) are located on the outer sides of the underframe (14), and the two ends of each spring (18) are respectively attached to the outer side surfaces of the underframe (14) and the inner side surfaces of the plates (8).

The heat dissipation device comprises a plurality of blades (10) and a rotating rod (11), wherein the plurality of blades (10) are fixedly connected to the circumferential side surface of the inner side end of the rotating rod (11), a heat dissipation fan formed by the plurality of blades (10) corresponds to the side end of the collecting device body, through grooves (12) corresponding to the rotating rod (11) are formed in the bottoms of the two side ends of the shell (1), the rotating rod (11) penetrates through the grooves (12), a plurality of heat dissipation grooves (13) which are equidistantly arranged in parallel are formed in the bottoms of the two side ends of the shell (1), and the heat dissipation fan corresponds to the heat dissipation grooves (13);

limiting plates (19) are arranged on two sides of the bottom of the shell (1), connecting frames (20) are fixedly connected to the inner side faces of the limiting plates (19), the inner side ends of the connecting frames (20) are positioned in the movable bin (17), the inner side ends of the connecting frames (20) are movably sleeved on the surface of the movable rod (16), the two connecting frames (20) are respectively correspondingly matched with the end parts of two ends of the strip groove (15), and the bottom frame (14) utilizes the strip groove (15) to limit the limiting plates (19) of the end parts of the connecting frames (20);

the surface of the limiting plate (19) is provided with a movable groove (21), two ends of the movable groove (21) are respectively provided with a connecting rod (22) in a penetrating mode, the two connecting rods (22) are in one-to-one correspondence with the two movable rods (16), the inner side ends of the connecting rods (22) are fixedly connected with the inner side ends of the movable rods (16) through the movable groove (21) and the strip groove (15), the outer side ends of the two connecting rods (22) are respectively fixedly connected with an inclined plate (23), and the two inclined plates (23) are symmetrically arranged by the center line of the shell (1);

the heat dissipation device further comprises a first bracket (24) and a second bracket (25), the whole appearance of the first bracket (24) and the whole appearance of the second bracket (25) are of U-shaped structures, the first bracket (24) and the second bracket (25) are oppositely arranged, the first bracket (24) and the second bracket (25) are respectively matched with the top ends of the two inclined plates (23) correspondingly, the end connection part of the first bracket (24) and the end connection part of the second bracket (25) are respectively fixedly connected with the outer side surfaces and the inner side surfaces of the top ends of the two inclined plates (23), the outer side ends of the rotating rods (11) are fixedly connected with cylindrical blocks (26), and the cylindrical blocks (26) sequentially penetrate through the middle parts of the first bracket (24) and the second bracket (25);

the inside top of first support (24) and the inside bottom of second support (25) all are provided with rack (27), and cylinder piece (26) surface be provided with respectively with rack (27) of first support (24) and second support (25) correspond complex gear (28), the inside bottom of first support (24) and the inside top of second support (25) all are provided with spout (29), and gear (28) and spout (29) sliding fit.

2. The terminal data acquisition device applied to the intelligent energy management control system according to claim 1, wherein:

curb plate (7) and to board (8) are made by elastic rubber material, and curb plate (7) and to board (8) utilize a plurality of rubber strips (9) annular parcel in casing (1) lateral surface, curb plate (7) and to board (8) all are in the ring limit (5) inboard of bottom plate (3), and curb plate (7) lateral surface and to board (8) lateral surface all do not contact with ring limit (5) medial surface.

3. The terminal data acquisition device applied to the intelligent energy management control system according to claim 1, wherein:

the bottom of the surface of the side plate (7) is provided with a plurality of leakage holes (30), and the leakage holes (30) are in one-to-one correspondence with the heat dissipation grooves (13).