CN212150085U - Data acquisition device structure for high-voltage transmission line defects - Google Patents

Abstract

The utility model discloses a data acquisition device structure for defects of a high-voltage transmission line, which comprises a shell, wherein a damping plate is arranged in the shell, a placing groove is arranged on the upper side surface of the damping plate, the inner part of the placing groove is fixedly connected with an acquisition device main body, a cover plate is covered on the upper side surface of the shell, four corners of the lower side surface of the damping plate are fixedly connected with supporting springs, and four corners of the upper side surface of the damping plate are fixedly connected with pressure springs, when the cover plate is opened, the main body of the collecting device is fixed in the shell through the supporting mechanism, so that the main body of the collecting device does not shake when a user presses a display screen of the main body of the collecting device, and is convenient for the user to use and operate, and under the closed state of apron, under the effect of supporting spring and pressure spring, make the collection system main part have the shock attenuation effect on the shock attenuation board, be convenient for accomodate and transport, prevent that the collection system main part from receiving damage when acutely shaking.

Description

Data acquisition device structure for high-voltage transmission line defects

Technical Field

The utility model relates to a high tension transmission line gathers technical field, specifically is a data acquisition device structure of high tension transmission line defect.

Background

At present, in order to monitor the state of key component equipment of a high-voltage transmission line tower in time and process related emergencies, video monitoring equipment is installed at key points and dangerous points of a line by a plurality of operation units, a manager receives and transmits signals of defects of the high-voltage transmission line through an acquisition device, the conventional common acquisition device lacks a protection device, a user can store the acquisition device in a tool box after using the device, and therefore the acquisition device is easily damaged by violent vibration in transportation, and then the defect detection progress of the high-voltage transmission line is influenced, so that a data acquisition device structure of the defects of the high-voltage transmission line is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a data acquisition device structure of high tension transmission line defect to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a data acquisition device structure of high tension transmission line defect, includes the casing, the inside of casing is equipped with the shock attenuation board, the side of going up of shock attenuation board is opened there is the standing groove, the inside fixedly connected with collection system main part of standing groove, the side of going up of casing is covered with the apron, the equal fixedly connected with supporting spring in downside four corners of shock attenuation board, just the equal fixedly connected with pressure spring in side four corners of going up of shock attenuation board.

Preferably, the inside of casing is equipped with supporting mechanism, supporting mechanism includes the slide, slide sliding connection just is located the below of damper plate in the inside of casing, the first wedge of the equal fixedly connected with in slide rear end both sides, the back lateral wall of first wedge is connected with the rear wall of casing through the extension spring, the top of first wedge is connected with the second wedge, the rear end fixedly connected with clamp plate of apron, the clamp plate activity is pressed on the last lateral wall of second wedge, supporting mechanism still includes a plurality of first sloping blocks and a plurality of second sloping blocks, and a plurality of first sloping blocks fixed connection are on the lower lateral wall of damper plate, and a plurality of second sloping block fixed connection are on the last lateral wall of slide, and a plurality of first sloping blocks and a plurality of second sloping blocks are with the form sliding connection of one-to-one.

Preferably, a clamping groove is formed in the upper side wall of the second wedge-shaped block, and the end portion of the pressing plate is movably clamped inside the clamping groove.

Preferably, the side wall of the placing groove is fixedly connected with a pressing block, and a silica gel gasket is arranged between the pressing block and the collecting device body.

Preferably, the front side wall of the shell and the front side wall of the cover plate are both fixedly connected with magnets.

Preferably, an electric storage device is disposed inside a rear side of the housing, and a charging port is disposed on a rear side wall of the housing.

Preferably, a receiving groove is formed in a rear side wall of the housing, and an antenna for receiving a wireless signal is rotatably connected to the inside of the receiving groove.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses under the state that the apron was opened, it is fixed that the collection system main part passes through supporting mechanism in the inside of casing, when the person of facilitating the use used the collection system main part (for example when pressing the display screen of collection system main part), the collection system main part does not take place to rock, convenient to use person uses the operation then, and under the closed state of apron, under the effect of supporting spring and pressure spring, make the collection system main part have the shock attenuation effect on the shock attenuation board, be convenient for accomodate and transport, prevent that the collection system main part from receiving damage when acutely shaking.

Drawings

Fig. 1 is a schematic view of the overall closed structure of the present invention;

fig. 2 is a schematic view I of the overall opening structure of the present invention;

fig. 3 is a schematic view II of the overall opening structure of the present invention;

fig. 4 is a cross-sectional view of the housing, the damper plate, the slide plate, the first swash block, and the second swash block of the present invention;

FIG. 5 is a cross-sectional view I of the housing, the damper plate, the slide plate, and the cover plate of the present invention;

fig. 6 is an enlarged view of fig. 5 a according to the present invention;

FIG. 7 is a sectional view II of the housing, the damper plate, the slide plate, and the cover plate of the present invention;

fig. 8 is an enlarged view of fig. 7 at B;

fig. 9 is an exploded view of the overall structure of the present invention;

fig. 10 is an explosion diagram of the main body of the collecting device, the placing groove, the pressing block and the silica gel gasket;

fig. 11 is an exploded view of the first and second wedge blocks, the slide plate and the shock absorbing plate of the present invention;

fig. 12 is a schematic structural view of the housing, the slide plate and the second sloping block of the present invention;

fig. 13 is a schematic diagram of the structure of the plug of the present invention.

In the figure: 1. the shell, 2, the shock attenuation board, 3, the standing groove, 4, the collection system main part, 5, the apron, 6, supporting spring, 7, the pressure spring, 8, supporting mechanism, 801, slide, 802, first wedge, 803, extension spring, 804, second wedge, 805, clamp plate, 806, first sloping block, 807, second sloping block, 9, the draw-in groove, 10, the briquetting, 11, the silica gel gasket, 12, magnet, 13, power storage device, 14, the mouth that charges, 15, accomodate the groove, 16, the antenna, 17, the backing plate, 18, the plug.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-13, the present invention provides a technical solution: a data acquisition device structure for defects of a high-voltage transmission line comprises a shell 1, as shown in figure 12, the shell 1 is composed of an upper shell and a lower shell, the upper shell can be clamped on the upper side of the lower shell, and in order to ensure the stability of connection between the upper shell and the lower shell, the upper shell and the lower shell are clamped and fixed through bolts, a damping plate 2 is arranged inside the shell 1, a placing groove 3 is formed in the upper side surface of the damping plate 2, an acquisition device main body 4 is fixedly connected inside the placing groove 3, the acquisition device main body 4 is a contact type device (namely touch screen operation), a touch display screen is arranged on the upper side surface of the acquisition device main body 4, a user can operate the acquisition device main body 4 by pressing the touch display screen, the acquisition device main body 4 can perform wireless receiving and transmitting effects on the defect signals of the high-voltage transmission line, the size of the placing groove 3 is matched with the size of, the upper side surface of the shell 1 is covered with a cover plate 5, after the cover plate 5 is closed, the interior of the shell 1 can be sealed, the collection device main body 4 is protected, the collection device main body 4 is prevented from being damaged by collision, and then the collection device main body 4 is prevented from dust, the four corners of the lower side surface of the damping plate 2 are fixedly connected with supporting springs 6, the four corners of the upper side surface of the damping plate 2 are fixedly connected with compression springs 7, the damping plate 2 is suspended in the shell 1 under the interaction of the supporting springs 6 and the compression springs 7, when the device is impacted or vibrated at a certain distance, the supporting springs 6 and the compression springs 7 play a role in damping the damping plate 2, so that the collection device main body 4 is effectively prevented from being damaged, a user can conveniently store and transport the collection device, in addition, a backing plate 17 is sleeved on the compression springs 7 on the same side, after the upper shell is clamped on the lower shell, the upper side surface of the backing plate 17 is abutted against, and then the compression spring 7 exerts downward elastic pressure on the damping plate 2.

In order to fix the collecting device main body 4 inside the casing 1 when the cover plate 5 is opened and facilitate the user to use the collecting device main body 4 (for example, when the display screen of the collecting device main body 4 is pressed), the collecting device main body 4 does not shake, and in order to enable the collecting device main body 4 to have a damping effect inside the casing 1 when the cover plate 5 is closed, specifically, a supporting mechanism 8 is disposed inside the casing 1, the supporting mechanism 8 includes a sliding plate 801, the sliding plate 801 is slidably connected inside the casing 1 and located below the damping plate 2, both sides of the rear end of the sliding plate 801 are fixedly connected with a first wedge block 802, the rear side wall of the first wedge block 802 is connected with the rear side wall of the casing 1 through a tension spring 803, the tension spring 803 has a pulling force to the first wedge block 802 and the sliding plate 801, and in a state without an acting force, the first wedge-shaped block 802 and the second wedge-shaped block 804 are in a state shown in fig. 6, the second wedge-shaped block 804 is connected above the first wedge-shaped block 802, as shown in fig. 6, a contact surface of the first wedge-shaped block 802 and the second wedge-shaped block 804 is an inclined surface, when the second wedge-shaped block 804 slides downwards, the first wedge-shaped block 802 is pressed by the second wedge-shaped block 804 and slides forwards against a pulling force of the tension spring 803, the rear end of the cover plate 5 is fixedly connected with a pressing plate 805, the pressing plate 805 movably presses an upper side wall of the second wedge-shaped block 804, the supporting mechanism 8 further comprises a plurality of first inclined blocks 806 and a plurality of second inclined blocks 807, the plurality of first inclined blocks 806 are fixedly connected to a lower side wall of the damper plate 2, the plurality of second inclined blocks 807 are fixedly connected to an upper side wall of the sliding plate 801, and the plurality of first inclined blocks 806 are slidably connected to the plurality of second inclined blocks 807 in a one-to-one manner, as shown in fig., when the cover plate 5 is closed, the first inclined block 806 is not in contact with the second inclined block 807, and the damping plate 2 can play a damping role on the acquisition device main body 4, as shown in fig. 7, when the cover plate 5 is opened, the first inclined block 806 is in contact with the second inclined block 807, and the damping plate 2 is supported by the inclined block 806 and the second inclined block 807, so that the acquisition device main body 4 is fixed, and a user can conveniently operate without shaking;

when the device is used, the cover plate 5 is opened, in the opening process of the cover plate 5, the pressing plate 805 rotates along with the cover plate 5, then the lower end of the pressing plate 805 presses the second wedge-shaped block 804 to slide downwards, and then the second wedge-shaped block 804 slides downwards to press the first wedge-shaped block 802 to slide forwards, so that the sliding plate 801 can slide forwards, and thus the first inclined block 806 and the second inclined block 807 can slide to the states shown in fig. 6-7, so that the damping plate 2 and the collecting device main body 4 are jacked upwards and fixed, and therefore when the device is used (namely when a touch screen on the collecting device main body 4 is pressed), the collecting device main body 4 cannot shake in the shell 1, and operation of a user is facilitated; after the use is finished, the cover plate 5 is closed, then the pressure on the second wedge-shaped block 804 is gradually cancelled after the pressing plate 805 rotates reversely, so that the first wedge-shaped block 802 and the sliding plate 801 slide backwards to the state shown in fig. 6 through the pulling force of the tension spring 803 (at this time, the second wedge-shaped block 804 is pushed backwards and reset by the first wedge-shaped block 802), then the first inclined block 806 and the second inclined block 807 slide to the state shown in fig. 4, at this time, the damping plate 2 is suspended inside the shell 1 under the interaction of the supporting spring 6 and the compression spring 7, when the device is impacted or vibrated at a distance, the supporting spring 6 and the compression spring 7 play a damping role on the damping plate 2, therefore, the collection device body 4 is effectively prevented from being damaged, and the collection and transportation are convenient for a user.

As shown in fig. 6 to 8, in order to effectively fix the cover plate 5 after being opened and prevent the cover plate 5 from closing by itself, specifically, the upper sidewall of the second wedge-shaped block 804 is provided with a clamping groove 9, the end of the pressing plate 805 is movably clamped inside the clamping groove 9, when the cover plate 5 is opened, the end of the pressing plate 805 is clamped inside the clamping groove 9, at this time, the cover plate 5 can be fixed, and the supporting mechanism 8 is fixed, and as shown in fig. 7, the opening rotation angle of the cover plate 5 is greater than 90 degrees, so that the cover plate 5 can be prevented from closing by itself, the stability of the opened cover plate 5 is increased, in addition, the end of the pressing plate 805 is spherical, the clamping groove 9 is shaped like a hemisphere, and thus when the user pulls the cover plate 5 forward, the pressing plate 805 and the clamping groove 9 can be quickly.

As shown in fig. 10, in order to fix the collecting device main body 4 inside the placing groove 3, specifically, a pressing block 10 is fixedly connected to the side wall of the placing groove 3, a silica gel gasket 11 is provided between the pressing block 10 and the collecting device main body 4, after the collecting device main body 4 is placed on the placing groove 3, the pressing block 10 is fixed to the side wall of the placing groove 3 through a bolt, at this time, the silica gel gasket 11 between the pressing block 10 and the collecting device main body 4 is extruded and deformed by the pressing block 10 and the collecting device main body 4, and the collecting device is fixedly connected inside the placing groove 3 in a clamping manner through the rebound effect of the silica gel gasket 11.

Specifically, all fixedly connected with magnet 12 on the preceding lateral wall of casing 1 and the preceding lateral wall of apron 5, after apron 5 is closed, two magnet 12 on casing 1 and the apron 5 can adsorb each other, can make apron 5 fix under the closed condition then.

In order to improve the power endurance of the acquisition device main body 4 and ensure sufficient power, specifically, a power storage device 13 is arranged inside the rear side of the casing 1, a charging port 14 is arranged on the rear side wall of the casing 1, a battery compartment is arranged inside the rear side of the casing 1, the power storage device 13 is installed inside the battery compartment, the power storage device 13 is electrically connected with the acquisition device main body 4 through a lead, the power storage device 13 is charged through the charging port 14, and then the power storage device 13 is conveniently and timely supplemented with electric energy.

In order to improve the capability of the main body 4 of the acquisition device for receiving and transmitting wireless signals and ensure smooth signals, specifically, the rear side wall of the shell 1 is provided with an accommodating groove 15, an antenna 16 for receiving wireless signals is rotatably connected inside the accommodating groove 15, the antenna 16 belonging to an external device is of an optional structure and does not influence the use, as shown in fig. 2-3, when the device operates, the antenna 16 is opened from the inside of the accommodating groove 15, then the antenna 16 can ensure smooth signal receiving and transmitting, when the device is accommodated, the antenna 16 is accommodated inside the accommodating groove 15, the volume of the device can be reduced, in addition, the antenna 16 can have elasticity, so that the length of the antenna 16 can be increased, for example, the antenna 16 of a radio, the main body 4 of the acquisition device is electrically connected with the antenna 16, and a plug 18 can be arranged in the placing groove 3 under the condition that the antenna 16 is installed, the plug 18 is electrically connected with the antenna 16, and when the device is installed as shown in fig. 13, the antenna jack on the side surface of the acquisition device body 4 is connected with the plug 18, and then the device is installed in a clamping mode.

The main body 4 of the collecting device is a module for calculating, processing and transmitting data in the existing product, and the structure and principle of the collecting device are not described in detail.

The working principle is as follows: during initial installation, the acquisition device main body 4 is placed inside the placing groove 3, then the pressing block 10 is fixed on the side wall of the placing groove 3 through the bolt, then the silica gel gasket 11 on the pressing block 10 deforms to enable the acquisition device main body 4 to be fixed inside the placing groove 3, then the upper shell and the lower shell of the shell 1 are installed through the bolt, and then the acquisition device main body 4 is fixed inside the shell 1; under the state that apron 5 was opened, collection system main part 4 was fixed through supporting mechanism 8 in the inside of casing 1, and when convenient to use person used collection system main part 4 (for example when pressing the display screen of collection system main part 4), collection system main part 4 did not take place to rock, and under the closed state of apron 5, under the effect of support spring 6 and pressure spring 7, made collection system main part 4 have the shock attenuation effect on shock attenuation board 2.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a data acquisition device structure of high tension transmission line defect, includes casing (1), its characterized in that: the inside of casing (1) is equipped with shock attenuation board (2), the side of going up of shock attenuation board (2) is opened has standing groove (3), the inside fixedly connected with collection system main part (4) of standing groove (3), the side of going up of casing (1) is covered apron (5), the equal fixedly connected with in downside four corners support spring (6) of shock attenuation board (2), just the equal fixedly connected with in side four corners pressure spring (7) of going up of shock attenuation board (2).

2. The data acquisition device structure of the high-voltage transmission line defect according to claim 1, characterized in that: the inside of casing (1) is equipped with supporting mechanism (8), supporting mechanism (8) includes slide plate (801), slide plate (801) sliding connection just is located the below of damper plate (2) in the inside of casing (1), the equal fixedly connected with first wedge (802) in slide plate (801) rear end both sides, the back lateral wall of first wedge (802) is connected with the back lateral wall of casing (1) through extension spring (803), the top of first wedge (802) is connected with second wedge (804), the rear end fixedly connected with clamp plate (805) of apron (5), on the last lateral wall of second wedge (804) is pressed in the activity of clamp plate (805), supporting mechanism (8) still include a plurality of first sloping blocks (806) and a plurality of second sloping blocks (807), a plurality of first sloping blocks (806) fixed connection is on the lower lateral wall of damper plate (2), the second inclined blocks (807) are fixedly connected to the upper side wall of the sliding plate (801), and the first inclined blocks (806) are in one-to-one corresponding sliding connection with the second inclined blocks (807).

3. The data acquisition device structure of the high-voltage transmission line defect according to claim 2, characterized in that: a clamping groove (9) is formed in the upper side wall of the second wedge-shaped block (804), and the end portion of the pressing plate (805) is movably clamped inside the clamping groove (9).

4. The data acquisition device structure of the high-voltage transmission line defect according to claim 1, characterized in that: fixedly connected with briquetting (10) on the lateral wall of standing groove (3), be equipped with silica gel gasket (11) between briquetting (10) and collection system main part (4).

5. The data acquisition device structure of the high-voltage transmission line defect according to claim 1, characterized in that: and the front side wall of the shell (1) and the front side wall of the cover plate (5) are fixedly connected with magnets (12).

6. The data acquisition device structure of the high-voltage transmission line defect according to claim 1, characterized in that: an electric storage device (13) is arranged inside the rear side of the shell (1), and a charging port (14) is formed in the rear side wall of the shell (1).

7. The data acquisition device structure of the high-voltage transmission line defect according to claim 1, characterized in that: the rear side wall of the shell (1) is provided with a containing groove (15), and the inside of the containing groove (15) is rotatably connected with an antenna (16) used for receiving wireless signals.

Images