CN216374889U - Probe loading device for marine surveying and mapping unmanned ship - Google Patents

Abstract

The utility model discloses a probe loading device for an unmanned ship for ocean surveying and mapping, and relates to the relevant technical field of ocean surveying and mapping. The utility model comprises an instrument shell, a top plate and a probe shell, wherein the probe shell is fixed with the instrument shell through an external thread cylinder, seal sleeves are fixed at the centers of the top and the bottom of the top plate, a soft seal ring is fixed at the bottom of the top plate, and a mounting frame is fixed at the lower part of the inner wall of the instrument shell above the external thread cylinder. By arranging the instrument shell, the top disc and the probe shell, the problems that the existing probe loading device for the marine surveying and mapping unmanned ship is poor in sealing performance and the probe movement is easy to interfere with the surveying and mapping precision of the instrument are solved, the circuit sealing performance of the probe loading device is better, the probe and the instrument are separated, and the interference of the probe movement on an operation instrument is reduced.

Description

Probe loading device for marine surveying and mapping unmanned ship

Technical Field

The utility model belongs to the technical field related to marine surveying and mapping, and particularly relates to a probe loading device for an unmanned ship for marine surveying and mapping.

Background

The measurement and the chart work of making up of marine water and seabed for the object carry out, mainly include the sea channel and measure, ocean geodetic survey, seabed topography survey, ocean thematic survey, and the chart of navigating sea, seabed topography, the work such as various ocean thematic charts and ocean atlas, the marine climate and the uncertainty of water change, therefore the survey and drawing danger of ocean is great, the personnel's safety of survey and drawing can be guaranteed better to use unmanned ship survey and drawing, the ocean survey and drawing need be surveyed through surveying and drawing instrument, surveying and drawing instrument installs surveying and drawing instrument on unmanned ship through loading device, but it still has following drawback in the in-service use:

1. when the existing probe loading device for the marine surveying and mapping unmanned ship is used, water seepage easily occurs when a line of an instrument enters a carrying device, and the instrument is damaged;

2. when the existing probe loading device for the marine surveying and mapping unmanned ship is used, only the probe can be independently installed, and when the existing probe loading device works, the probe is easy to move to damage an instrument.

Therefore, the existing probe loading device for the marine surveying and mapping unmanned ship cannot meet the requirements in practical use, so that an improved technology is urgently needed in the market to solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a probe loading device for an ocean surveying and mapping unmanned ship, which solves the problems that the existing probe loading device for the ocean surveying and mapping unmanned ship is not enough in sealing performance and a probe is easy to interfere with surveying and mapping precision of an instrument due to the fact that the probe moves by arranging an instrument shell, a top disc and a probe shell.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model relates to a probe loading device for an offshore surveying and mapping unmanned ship, which comprises an instrument shell, a top plate and a probe shell, wherein the probe shell is fixed with the instrument shell through an external thread cylinder, seal sleeves are fixed at the centers of the top and the bottom of the top plate, a soft seal ring is fixed at the bottom of the top plate, a mounting frame is fixed at the lower part of the inner wall of the instrument shell above the external thread cylinder, an instrument is installed in the probe loading device through the mounting frame in the instrument shell, the top of the instrument shell is sealed through the top plate, a moving space of the probe is provided below the probe shell and the mounting frame in the instrument shell, and a circuit inserted on the top plate is sealed through the seal sleeves on the top plate.

Further, the screw has been seted up to the top annular array of instrument shell, the top dish top outside annular array link up soft sealing washer and has seted up the jack, it has the bolt to peg graft in the jack, and the bottom of bolt inserts in jack and screw in screw, through bolt in the top dish and the screw threaded connection and the fastening in the instrument shell, fixes instrument shell and top dish.

Further, the internal thread has been seted up to the instrument shell inner wall of mounting bracket below, the top of probe shell is fixed with an external screw thread section of thick bamboo, the instrument shell passes through the internal thread and is fixed with an external screw thread section of thick bamboo, and the mounting bracket passes through internal thread and an external screw thread section of thick bamboo threaded connection, and is fixed with probe shell and mounting bracket.

Further, the mounting bracket includes solid fixed ring and support frame, gu fixed ring fixes on the inner wall of instrument shell, gu fixed ring is fixed with the support frame, the support frame that the instrument will be installed through solid fixed ring to the mounting bracket is installed in the instrument shell.

Furthermore, a wire hole is formed in the center of the top disc in a penetrating mode, hanging lugs are symmetrically fixed to the top of the top disc, the top disc is connected with a circuit of the instrument through the wire hole in an inserting mode, and the marine surveying and mapping unmanned ship is installed together through the hanging lugs.

Furthermore, an opening is formed in the bottom of the probe shell, a lens is fixed in the opening, and the probe shell penetrates out of and penetrates into light through the lens.

The utility model has the following beneficial effects:

1. the utility model solves the problem of insufficient sealing performance of the existing probe loading device for the marine surveying and mapping unmanned ship by arranging the instrument shell and the top plate, the top plate arranged on the instrument shell is used for splicing the circuit of the instrument, the circuit is led into the device, the sealing sleeve is tightly extruded on the circuit under the pressure of water, and the circuit is sealed by the sealing sleeves above and below the contact part of the top plate and the circuit, so that the water is prevented from entering the device, the device is damaged, and the safety of the device in the surveying and mapping process is improved.

2. The utility model solves the problem that the probe movement of the existing probe loading device for the marine surveying and mapping unmanned ship is easy to interfere with the surveying and mapping precision of the instrument by arranging the instrument shell, the top plate and the probe shell.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a perspective view of an assembly structure of the present invention;

FIG. 2 is a perspective view of the instrument housing construction of the present invention;

FIG. 3 is a perspective view of a mounting bracket configuration within the instrument housing of the present invention;

FIG. 4 is a perspective view of the top plate structure of the present invention;

FIG. 5 is a perspective view of a probe housing structure of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

100. an instrument housing; 101. an internal thread; 102. a screw hole; 103. a mounting frame; 1031. a fixing ring; 1032. a support frame; 200. a top tray; 201. a soft seal ring; 202. a jack; 203. a bolt; 204. a wire hole; 205. sealing sleeves; 206. hanging a lug; 300. a probe housing; 301. an opening; 302. a lens; 303. an externally threaded barrel.

Detailed Description

The technical solution in 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.

Referring to fig. 1 to 5, the present invention is a probe loading device for an unmanned marine surveying and mapping, including an instrument housing 100, a top plate 200, and a probe housing 300, wherein the probe housing 300 is fixed to the instrument housing 100 by an external thread cylinder 303, the probe housing 300 provides an underwater movement space for a probe, the operation body of the surveying and mapping instrument is installed in the instrument shell 100 through a structure in the instrument shell, the centers of the top and the bottom of the top plate 200 are both fixed with sealing sleeves 205, the top plate 200 seals a line passing through the top plate 200 through the sealing sleeves 205 to prevent water from permeating into the utility model under pressure, the bottom of the top plate 200 is fixed with a soft sealing ring 201, after the top plate 200 is connected and fastened with the instrument shell 100 through a bolt 203, the gap between the top plate 200 and the instrument housing 100 is sealed, the mounting frame 103 is fixed to the lower portion of the inner wall of the instrument housing 100 above the externally threaded barrel 303, and the instrument to be used is mounted and supported in the instrument housing 100 by the mounting frame 103.

As shown in fig. 1, 2, 3 and 5, the top ring array of the instrument shell 100 is provided with screw holes 102, the ring array on the outer side of the top disk 200 penetrates through the soft seal ring 201 and is provided with an insertion hole 202, a bolt 203 is inserted into the insertion hole 202, the bottom end of the bolt 203 is inserted into the insertion hole 202 and screwed into the screw hole 102, and the top disk 200 is fixed above the instrument shell 100 after being screwed;

an internal thread 101 is formed in the inner wall of the instrument shell 100 below the mounting rack 103, an external thread barrel 303 is fixed to the top of the probe shell 300, the instrument shell 100 is fixed to the external thread barrel 303 through the internal thread 101, and the probe shell 300 is in threaded connection with the internal thread 101 in the instrument shell 100 through the external thread barrel 303 to fix the instrument shell 100 and the probe shell 300;

the mounting rack 103 comprises a fixing ring 1031 and a support frame 1032, the fixing ring 1031 is fixed on the inner wall of the instrument housing 100, the support frame 1032 is fixed on the fixing ring 1031, the support frame 1032 is connected with the mounting rack 103 through the fixing ring 1031, and the instrument to be mounted is supported on the upper part of the interior of the instrument housing 100 through the support frame 1032;

an opening 301 is formed in the bottom of the probe shell 300, a lens 302 is fixed in the opening 301, light emitted by a probe in the probe shell 300 is transmitted out of the probe shell 300 through the lens 302, and external light is transmitted into the probe shell 300 through the lens 302;

before use, the mounting frame 103 in the instrument shell 100 is used for mounting an instrument main body arithmetic device to be mounted in the instrument shell 100, then the probe is mounted in the instrument shell 100 below the mounting frame 103, and in use, the probe moves in the instrument shell 100 and the probe shell 300 below the mounting frame 103.

As shown in fig. 1-4, a wire hole 204 is formed through the center of the top plate 200, the top plate 200 is inserted with an external circuit of an instrument through the wire hole 204, lugs 206 are symmetrically fixed on the top of the top plate 200, and the lugs 206 provide the installation position of the unmanned surveying and mapping ship;

during installation, the instrument wiring passes through the gland 205 at the top of the top plate 200, then through the wire hole 204 in the top plate 200, through the gland 205 at the bottom of the top plate 200, into the instrument housing 100, and connects to the instrument installed in the instrument housing 100.

The above are only preferred embodiments of the present invention, and the present invention is not limited thereto, and any modification, equivalent replacement, and improvement made to the technical solutions described in the above embodiments, and to some of the technical features thereof, are included in the scope of the present invention.

Claims (6)

1. A probe loading device for an oceanographic unmanned ship, which comprises an instrument shell (100), a top plate (200) and a probe shell (300), and is characterized in that: the probe shell (300) is fixed with the instrument shell (100) through an external thread cylinder (303), the top and the bottom center of the top plate (200) are both fixed with a sealing sleeve (205), the bottom of the top plate (200) is fixed with a soft sealing ring (201), and the lower part of the inner wall of the instrument shell (100) above the external thread cylinder (303) is fixed with a mounting rack (103).

2. The probe loading device for the unmanned marine surveying and mapping at sea according to claim 1, wherein the annular array at the top of the instrument shell (100) is provided with screw holes (102), the annular array at the outer side of the top plate (200) is provided with insertion holes (202) penetrating through the soft sealing ring (201), the insertion holes (202) are inserted with bolts (203), and the bottom ends of the bolts (203) are inserted into the insertion holes (202) and screwed into the screw holes (102).

3. The probe loading device for the marine surveying and mapping unmanned ship according to claim 1, wherein an inner wall of the instrument shell (100) below the mounting frame (103) is provided with an internal thread (101), an external thread cylinder (303) is fixed to the top of the probe shell (300), and the instrument shell (100) is fixed to the external thread cylinder (303) through the internal thread (101).

4. The probe loading device for the marine surveying unmanned ship according to claim 1, wherein the mounting frame (103) comprises a fixing ring (1031) and a support frame (1032), the fixing ring (1031) is fixed on an inner wall of the instrument housing (100), and the support frame (1032) is fixed on the fixing ring (1031).

5. The probe loading device for the marine surveying and mapping unmanned ship according to claim 1, wherein a wire hole (204) is formed through the center of the top plate (200), and lugs (206) are symmetrically fixed on the top of the top plate (200).

6. The probe loading device for the marine surveying and mapping unmanned ship according to claim 1, wherein an opening (301) is opened at the bottom of the probe shell (300), and a lens (302) is fixed in the opening (301).

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