CN114834589A

CN114834589A - Marine heat-insulation signal storage cabin

Info

Publication number: CN114834589A
Application number: CN202210631408.3A
Authority: CN
Inventors: 陈威; 包燕旭; 李晓彬; 乐京霞; 宋召军; 张琦; 王才能; 王志平; 朱春晓; 滕清湖
Original assignee: Wuhan University of Technology WUT
Current assignee: Wuhan University of Technology WUT
Priority date: 2022-06-06
Filing date: 2022-06-06
Publication date: 2022-08-02

Abstract

The invention relates to the technical field of information storage devices, in particular to a heat insulation signal storage cabin for a ship; the inner core frame is arranged in the shell by arranging the shell, the inner core frame, the information storage module and the heat insulation module; an information storage cavity is arranged in the inner core frame, and the information storage module is fixed in the information storage cavity; the heat insulation module is arranged between the inner walls of the inner core frame and the shell, the heat insulation module is through a first heat insulation layer, a heat absorption layer and a second heat insulation layer which are arranged from inside to outside according to the sequence, the second heat insulation layer can separate high heat generated outside to a certain extent, partial heat which penetrates through the second heat insulation layer can be absorbed through the heat absorption layer, the first heat insulation layer can further separate heat, the signal storage bin is further provided with a heat conduction module, when the temperature of the inner core frame rises, the heat conduction module can conduct the heat of the inner core frame to the heat absorption layer, the temperature of the inner core frame is further reduced, and efficient protection of the information storage module is achieved.

Description

Marine heat-insulation signal storage cabin

Technical Field

The invention relates to the technical field of information storage devices, in particular to a heat insulation signal storage cabin for a ship.

Background

The signal storage cabin is mainly used on the ship, and can be recycled for various equipment for recycling and storing navigation data and the like of the ship when the ship body suffers from irreparable damage, so that the damage state of the ship at that time can be conveniently known, and subsequent rescue and ship body improvement work can be conveniently carried out.

The signal storage cabin is used for recovering ship data, so that stored information in the signal storage cabin needs to be effectively protected, and when a ship body has serious accidents such as fire, explosion and the like, external high temperature can be effectively isolated, and the storage unit of the storage cabin is prevented from being damaged by the external high temperature.

The memory cell is generally installed in the signal storage intracavity of storage cabin, the inside through at the casing of current marine storage cabin sets up heat-proof device, can prevent heat entering signal storage chamber to a certain extent, still there is few part heat to see through heat-proof device and enters into the signal storage intracavity, because heat-proof effect of heat-proof device, the heat that leads to entering signal storage intracavity can't in time be discharged, the heat is constantly gathering in the signal storage intracavity, finally lead to the temperature rise in signal storage chamber, cause the damage to the memory cell.

Disclosure of Invention

The invention aims to overcome the technical defects, provides a marine heat insulation signal storage cabin and solves the technical problems that the temperature of a signal storage cavity is increased and a storage unit is easily damaged because the heat in the signal storage cavity cannot be discharged in time by the marine signal storage cabin in the prior art.

In order to achieve the above technical object, an aspect of the present invention provides a marine heat-insulated signal storage compartment, including:

a housing;

the inner core frame is arranged inside the shell, and an information storage cavity is arranged inside the inner core frame;

the information storage module is fixed in the information storage cavity, is electrically connected with the ship and is used for storing the navigation information of the ship;

the heat insulation module is arranged between the inner core frame and the inner wall of the shell and comprises a first heat insulation layer, a heat absorption layer and a second heat insulation layer which are sequentially arranged from inside to outside, the first heat insulation layer is attached to the outer side face of the inner core frame, the second heat insulation layer is used for blocking heat penetrating through the shell, the heat absorption layer is used for absorbing heat penetrating through the second heat insulation layer, and the first heat insulation layer is used for blocking heat absorbed by the heat absorption layer;

the heat conduction module is fixed in the first heat insulation layer, one end of the heat conduction module is connected with the inner core frame, and the other end of the heat conduction module is connected with the heat absorption layer and used for guiding heat of the inner core frame to the heat absorption layer.

Optionally, the heat absorbing layer includes a base frame and a heat accumulator, the base frame surrounds the surface of the first heat insulating layer, a heat absorbing cavity is arranged inside the first heat insulating layer, the heat accumulator is arranged in each heat absorbing cavity, and the heat accumulator is used for absorbing heat of the base frame to reduce the temperature of the base frame.

Optionally, the bed frame includes metal heat conduction frame and polystyrene heat insulation frame, the medial surface of metal heat conduction frame with the surface laminating of first insulating layer, polystyrene heat insulation frame enclose in lateral surface one side of metal heat conduction frame and with the second insulating layer is close to the one side laminating of metal heat conduction frame, the heat absorption chamber is located metal heat conduction frame with between the heat insulation frame.

Optionally, a plurality of metal connecting plates arranged at included angles are connected between the metal heat conducting frame and the polystyrene heat insulating frame, and the heat accumulator is arranged between each metal connecting plate and attached to the metal connecting plates.

Optionally, the heat conducting module includes a plurality of metal heat conducting rings, each metal heat conducting ring is fixed to the first heat insulating layer at intervals, one end of each metal heat conducting ring extends to the information storage cavity, and the other end of each metal heat conducting ring penetrates through the first heat insulating layer and is connected to the metal heat conducting frame.

Optionally, the thermal mass is paraffin.

Optionally, the second heat insulation layer comprises an inner carbon fiber layer, a middle foaming layer and an outer carbon fiber layer which are sequentially arranged from outside to outside, the inner carbon fiber layer is attached to the surface of the heat absorption layer, and the outer carbon fiber layer is attached to the inner side surface of the shell.

Optionally, the first insulation layer comprises insulation cotton.

Optionally, the casing includes base and bottom open-ended epitheca, the lower extreme of epitheca is fixed with the flange, the base lid is located the bottom opening part of epitheca and with flange fixed connection, the lower extreme terminal surface of epitheca is provided with and encloses the fit the bottom open-ended of epitheca meets water inflation adhesive tape, meet water inflation adhesive tape with the surface sealing laminating of upper cover.

Optionally, the base includes fixed plate and rubber backing plate, the fixed plate be fixed in on the flange and with meet the laminating of water inflation adhesive tape, the upper surface of rubber backing plate is provided with a plurality of intervals and is provided with antidetonation arch, each antidetonation arch all is fixed in the lower surface of fixed plate, the inside of rubber backing plate is provided with the inhaling of a plurality of intervals settings and shakes the hole.

Compared with the prior art, the marine heat insulation signal storage cabin provided by the invention has the beneficial effects that: the inner core frame is arranged in the shell by arranging the shell, the inner core frame, the information storage module and the heat insulation module; an information storage cavity is arranged in the inner core frame, and the information storage module is fixed in the information storage cavity, is electrically connected with the ship and can store the navigation information of the ship; the heat insulation module is arranged between the inner walls of the inner core frame and the shell, the heat insulation module is provided with a first heat insulation layer, a heat absorption layer and a second heat insulation layer which are sequentially arranged from inside to outside, the second heat insulation layer can insulate high heat generated outside to a certain extent, partial heat penetrating through the second heat insulation layer can be absorbed through the heat absorption layer, the first heat insulation layer can further insulate the heat, the heat is further prevented from entering the inner core frame, high-efficiency heat insulation of the information storage module is achieved, the signal storage bin is further provided with a heat conduction module, if a small part of heat penetrates through the inner core frame to cause the temperature of the inner core frame to rise, the heat conduction module can conduct the heat of the inner core frame to the heat absorption layer, the temperature of the inner core frame is reduced, and high-efficiency protection of the information storage module is achieved.

Drawings

Fig. 1 is a schematic structural diagram of a marine heat-insulating signal storage compartment according to an embodiment of the present invention.

Fig. 2 is a partially enlarged view of a portion a in fig. 1.

Fig. 3 is a cross-sectional view of a thermally insulated signal storage compartment for a ship according to an embodiment of the present invention.

Fig. 4 is a partially enlarged view of a portion a in fig. 3.

Fig. 5 is a cross-sectional view of a heat absorbing layer of a marine insulated signal storage compartment according to an embodiment of the present invention.

Fig. 6 is a cross-sectional view of a second insulation layer of the marine insulated signal storage compartment according to an embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

10-shell 11-upper shell 12-base

20-inner core frame 21-information storage cavity 30-information storage module

40-heat insulation module 41-first heat insulation layer 42-heat absorption layer

43-second heat insulation layer 50-heat conduction module 51-metal heat conduction ring

111-flange 112-water-swelling adhesive tape 113-cable socket

121-fixing plate 122-rubber backing plate 411-heat insulation cotton

421-base frame 422-heat absorption cavity 423-connecting plate

431-inner carbon fiber layer 432-middle foaming layer 433-outer carbon fiber layer

1221-anti-seismic protrusion 1222-shock-absorbing hole 4211-metal heat-conducting frame

4212-polystyrene insulating frame.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The invention provides a heat insulation signal storage cabin for a ship, which comprises a shell 10, an inner core frame 20, an information storage module 30, a heat insulation module 40 and a heat conduction module 50, wherein the shell is provided with a heat insulation signal storage cavity; the inner core frame 20 is arranged inside the shell 10; an information storage cavity 21 is arranged inside the inner core frame 20, and an information storage module 30 is fixed in the information storage cavity 21, electrically connected with the ship and used for storing the navigation information of the ship; the heat insulation module 40 is arranged between the inner core frame 20 and the inner wall of the shell 10, the heat insulation module 40 comprises a first heat insulation layer 41, a heat absorption layer 42 and a second heat insulation layer 43 which are sequentially arranged from inside to outside, the first heat insulation layer 41 is attached to the outer side surface of the inner core frame 20, the second heat insulation layer 43 is used for blocking heat penetrating through the shell 10, the heat absorption layer 42 is used for absorbing heat penetrating through the second heat insulation layer 43, and the first heat insulation layer 41 is used for blocking heat absorbed by the heat absorption layer 42; the heat conducting module 50 is fixed in the first heat insulating layer 41, one end of the heat conducting module 50 is connected with the inner core frame 20, and the other end of the heat conducting module 50 is connected with the heat absorbing layer 42, so as to guide the heat of the inner core frame 20 to the heat absorbing layer 42.

Specifically, by providing the housing 10, the core frame 20, the information storage module 30, and the heat insulation module 40, the core frame 20 is provided inside the housing 10; an information storage cavity 21 is arranged in the inner core frame 20, and an information storage module 30 is fixed in the information storage cavity 21 and electrically connected with the ship and can be used for storing the navigation information of the ship; the heat insulation module 40 is arranged between the inner core frame 20 and the inner wall of the shell 10, the heat insulation module 40 is provided with a first heat insulation layer 41, a heat absorption layer 42 and a second heat insulation layer 43 in sequence from inside to outside, the second heat insulation layer 43 can insulate high heat generated outside to a certain extent, part of heat penetrating through the second heat insulation layer 43 can be absorbed through the heat absorption layer 42, the first heat insulation layer 41 can insulate the heat further, the heat is further prevented from entering the inner core frame 20, efficient heat insulation of the information storage module 30 is realized, and as the signal storage bin is further provided with the heat conduction module 50, if a small amount of heat still passes through the inner core frame 20 to cause temperature rise of the inner core frame 20, the heat conduction module 50 can conduct the heat of the inner core frame 20 to the heat absorption layer 42, so that the temperature of the inner core frame 20 is reduced, and efficient protection of the information storage module 30 is realized.

In this embodiment, a cable is disposed on the information storage module 30, a cable socket 113 is disposed on the surface of the housing 10, one end of the cable is connected to the information storage module 30, the other end of the cable is connected to the cable socket 113, and the cable socket 113 is used for connecting a signal output device of a ship body.

In this embodiment, the casing 10 includes a base 12 and an upper casing 11 with an opening at the bottom, a flange 111 is fixed at the lower end of the upper casing 11, the base 12 covers the opening at the bottom of the upper casing 11 and is fixedly connected with the flange 111, a water-swelling adhesive tape 112 enclosing the opening at the bottom of the upper casing 11 is arranged on the lower end surface of the upper casing 11, and the water-swelling adhesive tape 112 is attached to the surface of the upper casing in a sealing manner. Specifically, flange 111 can realize the firm connection of base 12 and upper shell 11, base 12 can be dismantled be fixed in with the hull on and through locking mechanism and hull locking, when the great disaster takes place for the hull, locking mechanism starts by oneself, make base 12 and hull separate, through set up water-swelling adhesive tape 112 between the lower extreme terminal surface of upper shell 11 and base 12, if the water gets into between the lower extreme terminal surface of upper shell 11 and the base 12 with water-swelling adhesive tape 112 contact, can make water-swelling adhesive tape 112 take place to expand, effectively prevent that moisture from getting into inside the casing 10.

Optionally, the base 12 includes a fixing plate 121 and a rubber pad 122, the fixing plate 121 is fixed on the flange 111 and attached to the water-swellable adhesive tape 112, the upper surface of the rubber pad 122 is provided with a plurality of shock-resistant protrusions 1221 at intervals, each shock-resistant protrusion 1221 is fixed on the lower surface of the fixing plate 121, and the inside of the rubber pad 122 is provided with a plurality of shock-absorbing holes 1222 at intervals. Specifically, the shock-resistant protrusions 1221 may provide a buffer to lateral vibration force acting on the housing 10 when the hull vibrates, to reduce impact of the lateral vibration on the housing 10, and the shock-absorbing holes 1222 may provide a buffer to longitudinal vibration force acting on the housing 10 when the hull vibrates longitudinally, to reduce impact of the longitudinal vibration on the housing 10, to reduce damage to the signal storage compartment when the hull vibrates.

Optionally, the heat absorbing layer 42 includes a base frame 421 and a heat accumulator (not shown), the base frame 421 surrounds the surface of the first heat insulating layer 41, a heat absorbing cavity 422 is disposed inside the first heat insulating layer 41, the heat accumulator is disposed in each heat absorbing cavity 422, and the heat accumulator is configured to absorb heat of the base frame 421 to reduce the temperature of the base frame 421. Specifically, the stability of the base surface can be effectively reduced by the heat absorption effect of the heat accumulator on the base frame 421, and the heat transfer from the base frame 421 to the first heat insulation layer 41 is further reduced.

In this embodiment, the heat storage body may be any low-temperature phase-change heat storage substance with large heat storage amount, small temperature fluctuation, and good chemical stability, such as fluoride, sulfate, paraffin, and the like.

It will be appreciated that the end of the thermal module 50 adjacent the heat sink 42 may be coupled to a base or to a thermal mass.

Optionally, the base frame 421 includes a metal heat conduction frame 4211 and a polystyrene heat insulation frame 4212, an inner side surface of the metal heat conduction frame 4211 is attached to a surface of the first heat insulation layer 41, the polystyrene heat insulation frame 4212 surrounds one side of an outer side surface of the metal heat conduction frame 4211 and is attached to one surface, close to the metal heat conduction frame 4211, of the second heat insulation layer 43, and the heat absorption cavity 422 is located between the metal heat conduction frame 4211 and the heat insulation frame. Specifically, the polystyrene heat insulation frame 4212 has high strength and good heat insulation performance, and can effectively block heat, and the metal heat conduction frame 4211 has high strength and high heat conduction performance, and can better guide heat close to the first heat insulation layer 41 to the heat accumulator, so as to reduce the temperature of the first heat insulation layer 41.

Optionally, a plurality of metal connecting plates 423 arranged at an included angle are connected between the metal heat conducting frame 4211 and the polystyrene heat insulating frame 4212, and a heat accumulator is arranged between each metal connecting plate 423 and attached to each metal connecting plate 423. Specifically, the metal connecting plate 423 may effectively bear the heat accumulator while reinforcing the connection between the metal heat conducting frame 4211 and the polystyrene heat insulating frame 4212, and may facilitate guiding the metal heat conducting frame 4211 and the polystyrene heat insulating frame 4212 to the heat accumulator.

Optionally, the heat conducting module 50 includes a plurality of metal heat conducting rings 51, each metal heat conducting ring 51 is fixed on the first heat insulating layer 41 at intervals, one end of each metal heat conducting ring 51 extends to the information storage cavity 21, and the other end of each metal heat conducting ring 51 passes through the first heat insulating layer 41 and is connected to the metal heat conducting frame 4211.

Optionally, the thermal mass is paraffin. Specifically, the heat conducting module 50 is provided with the plurality of metal heat conducting rings 51, so that the temperature of the inner core frame 20 can be quickly guided to the metal heat conducting frame 4211, and the inner core frame 20 can be quickly cooled.

Optionally, the second thermal insulation layer 43 includes an inner carbon fiber layer 431, an intermediate foaming layer 432 and an outer carbon fiber layer 433 which are sequentially arranged from the outside to the inside, the inner carbon fiber layer 431 is attached to the surface of the heat absorption layer 42, and the outer carbon fiber layer 433 is attached to the inner side surface of the casing 10. Specifically, the inner carbon fiber layer 431 and the outer carbon fiber layer 433 can effectively reinforce the strength of the second thermal insulation layer 43, prevent the second thermal insulation layer 43 from being damaged by external impact, and the middle foaming layer 432 can effectively block external heat.

Optionally, the first insulation layer 41 comprises insulation cotton 411. Specifically, the heat insulation cotton 411 is a novel nontoxic, harmless and pollution-free heat insulation material prepared from high-purity clay clinker, alumina powder, silica powder, chrome quartz sand and other raw materials, has a good heat insulation characteristic, and can effectively prevent heat from entering the inner core frame 20.

The above-described embodiments of the present invention should not be construed as limiting the scope of the present invention. Any other corresponding changes and modifications made according to the technical idea of the present invention should be included in the protection scope of the claims of the present invention.

Claims

1. A thermally insulated signal storage compartment for a ship, comprising:

a housing;

2. The marine insulated signal storage compartment of claim 1, wherein the heat absorbing layer comprises a base frame and a heat storage body, the base frame surrounds a surface of the first insulating layer, a heat absorbing cavity is disposed inside the first insulating layer, the heat storage body is disposed in each heat absorbing cavity, and the heat storage body is configured to absorb heat from the base frame to reduce the temperature of the base frame.

3. The marine thermal insulation signal storage compartment according to claim 2, wherein the base frame comprises a metal heat conduction frame and a polystyrene heat insulation frame, an inner side surface of the metal heat conduction frame is attached to a surface of the first thermal insulation layer, the polystyrene heat insulation frame surrounds one side of the outer side surface of the metal heat conduction frame and is attached to one surface, close to the metal heat conduction frame, of the second thermal insulation layer, and the heat absorption cavity is located between the metal heat conduction frame and the heat insulation frame.

4. The marine insulated signal storage compartment of claim 3, wherein a plurality of metal connecting plates are connected between the metal heat-conducting frame and the polystyrene heat-insulating frame, the metal connecting plates being arranged at an included angle, and the heat accumulator is arranged between the metal connecting plates and attached to the metal connecting plates.

5. The thermally insulated signal storage compartment of claim 3, wherein the thermally conductive module comprises a plurality of metal thermally conductive rings, each of the metal thermally conductive rings is fixed to the first thermally insulating layer at intervals, one end of each of the metal thermally conductive rings extends to the information storage cavity, and the other end of each of the metal thermally conductive rings passes through the first thermally insulating layer and is connected to the metal thermally conductive frame.

6. The thermally insulated signal storage capsule of claim 2, wherein the thermal mass is paraffin.

7. The marine thermal insulation signal storage cabin according to any one of claims 1 to 6, wherein the second thermal insulation layer comprises an inner carbon fiber layer, an intermediate foaming layer and an outer carbon fiber layer which are arranged in sequence from outside to outside, the inner carbon fiber layer is attached to the surface of the heat absorbing layer, and the outer carbon fiber layer is attached to the inner side surface of the shell.

8. The thermally insulated signal storage compartment of any of claims 1 to 6, wherein the first thermally insulating layer comprises thermal cotton.

9. The marine heat-insulating signal storage cabin according to any one of claims 1 to 6, wherein the casing includes a base and an upper casing with an opening at the bottom, a flange is fixed to a lower end of the upper casing, the base is covered at the opening at the bottom of the upper casing and is fixedly connected with the flange, a water-swelling adhesive tape is arranged on an end face of the lower end of the upper casing and surrounds the opening at the bottom of the upper casing, and the water-swelling adhesive tape is sealed and attached to a surface of the upper casing.

10. The marine heat-insulating signal storage cabin according to claim 9, wherein the base comprises a fixing plate and a rubber base plate, the fixing plate is fixed on the flange and attached to the water-swelling adhesive tape, a plurality of shock-resistant protrusions are arranged on the upper surface of the rubber base plate at intervals and fixed on the lower surface of the fixing plate, and a plurality of shock-absorbing holes are arranged in the rubber base plate at intervals.