CN114513143A

CN114513143A - Power transmission floating frame structure for ocean temperature difference power generation

Info

Publication number: CN114513143A
Application number: CN202210117153.9A
Authority: CN
Inventors: 彭景平; 陈凤云; 葛云征; 刘蕾; 刘伟民
Original assignee: First Institute of Oceanography MNR
Current assignee: First Institute of Oceanography MNR
Priority date: 2022-02-08
Filing date: 2022-02-08
Publication date: 2022-05-17

Abstract

The invention provides an electric power conveying floating frame structure for ocean temperature difference power generation. Electric power transportation floating frame structure for ocean thermoelectric power generation includes: a floating base; a support structure disposed on the top of the floating base, the support structure including a connection fixedly mounted on the top of the floating base. The invention provides an electric power transmission floating frame structure for ocean temperature difference power generation, which mainly provides support for a support plate through the support structure, so that the support plate can be stably installed on an electric power transmission cable, meanwhile, the telescopic operation of a telescopic rod and a positioning clamping block can be realized through the arrangement of an adjusting assembly, so that the support structure can be quickly locked and unlocked, the assembly for controlling the telescopic operation and the assembly for controlling the rotation are arranged together, the traditional separate independent use mode is changed, when the support structure is unfolded or folded, only the rotating piece needs to be rotated and adjusted, and the operation is very simple and convenient.

Description

Electric power transportation floating frame structure for ocean temperature difference power generation

Technical Field

The invention relates to the field of ocean temperature difference power generation, in particular to an electric power conveying floating frame structure for ocean temperature difference power generation.

Background

The ocean temperature difference power generation is to utilize the temperature difference between the shallow layer and the deep layer of the seawater and different heat sources of temperature and cold, and generate power through a heat exchanger and a turbine, in the existing ocean temperature difference power generation system, the source of heat energy is the warm seawater on the ocean surface, and the power generation method basically has two types: one is to evaporate the working fluid with low boiling point in a closed circulating system by utilizing warm seawater; the other is that warm sea water itself boils in a vacuum chamber.

In the ocean power generation system, the power generated by the generator needs to be transmitted to the outside, and when the power is transmitted, the floating frame is generally used for supporting and fixing the power transmission cable, so that the power transmission cable can be kept in a fixed state on the sea.

Among the correlation technique, to part electric power transmission floating frame structure, generally constitute by floating base and supporting mechanism, and for the convenience transport floating frame structure, make it can adapt to different user demands, traditional supporting mechanism can set up to scalable and rotate folding form, fold it when transporting, because realize that flexible and folding relevant subassembly is the part setting and independent use more, this makes when launching or contracting supporting mechanism, need operate two kinds of subassemblies respectively, could accomplish whole supporting mechanism shrink and folding, convenient inadequately when the operation, the spent time is longer, if the electric power transmission floating frame structure quantity that needs the operation simultaneously is more, then can lead to work speed slowly, holistic work load is great.

Therefore, it is necessary to provide an electric power transportation floating frame structure for ocean temperature difference power generation to solve the above technical problems.

Disclosure of Invention

The invention provides an electric power conveying floating frame structure for ocean temperature difference power generation, and solves the problems that a supporting mechanism is inconvenient to retract and fold and complicated to operate.

In order to solve the technical problem, the invention provides an electric power transportation floating frame structure for ocean temperature difference power generation, which comprises:

a floating base;

the supporting structure is arranged at the top of the floating base and comprises a connecting seat fixedly arranged at the top of the floating base, a connecting column is connected to the connecting seat in a rotating mode, a telescopic rod is connected to the connecting column in a sliding mode, an adjusting component used for controlling the telescopic rod to stretch is arranged on the connecting column, and auxiliary supporting components used for providing auxiliary support for the outer portion of the connecting column are arranged on two sides of the outer portion of the connecting column;

the adjusting component comprises an adjusting rotating piece and a threaded rod, wherein the adjusting rotating piece is rotated below the connecting column, the threaded rod is vertically rotated inside the connecting column, the outside of the threaded rod is in threaded connection with the inside of the telescopic rod, one end of the adjusting rotating piece is fixedly connected with bevel gears outside the threaded rod, the bevel gears are meshed with the outside of the bevel gears, the bottom end of the threaded rod is in threaded connection with a positioning fixture block, and the bottom of the positioning fixture block is clamped on the inner side of the connecting seat.

Preferably, the inside of spliced pole seted up with the activity groove of telescopic link adaptation, just the outside of telescopic link with the inside sliding connection in activity groove, the inside of telescopic link be provided with the thread groove of threaded rod adaptation.

Preferably, the upper part and the lower part of the outer part of the threaded rod are respectively provided with threads with opposite threads, the outer part of the positioning fixture block is in sliding connection with the inner part of the connecting column, and the bottom of the inner side of the connecting seat is provided with a positioning groove matched with the positioning fixture block.

Preferably, the adjusting rotating member is composed of a knob and a connecting rod, and one end of the adjusting rotating member extends from the outside of the connecting column to the inside of the connecting column.

Preferably, a plurality of supporting plates for fixedly supporting the power transmission line are fixedly arranged outside the telescopic rod, and a plurality of fixing parts connected with the outside of the power transmission line are arranged on two sides of the top of each supporting plate.

Preferably, the auxiliary supporting assembly comprises a rotating rod which rotates outside the connecting column, a movable clamping rod is connected to the rotating rod in a sliding mode, and a supporting spring is sleeved outside the movable clamping rod.

Preferably, the both sides at floating base top all seted up with the card hole of activity kelly adaptation, the bottom joint of activity kelly in the card hole, and work as the activity kelly to when the inside shrink of dwang, make supporting spring is extruded.

Preferably, a plurality of spread grooves have been seted up to the outside top of telescopic link, the centre joint of backup pad in the spread groove, the joint hole has all been seted up to the both sides of backup pad bottom, it is right to set up with a plurality of being used for on the telescopic link the fixed knot structure of backup pad bottom joint.

Preferably, the fixed structure comprises a limiting rod vertically and fixedly installed inside the telescopic rod, a moving part is sleeved outside the limiting rod, and two sides of the moving part respectively extend to two sides of the outside of the telescopic rod.

Preferably, the equal fixed mounting in both sides at moving part top has the joint axle, the outside joint of joint axle in the joint is downthehole, the outside of gag lever post cup joints elastic component.

Compared with the prior art, the electric power transportation floating frame structure for ocean temperature difference power generation provided by the invention has the following beneficial effects:

the invention provides an electric power transmission floating frame structure for ocean temperature difference power generation, which mainly provides support for a support plate through the support structure, so that the support plate can be stably installed on an electric power transmission cable, meanwhile, the telescopic operation of a telescopic rod and a positioning clamping block can be simultaneously realized through the arrangement of an adjusting assembly, so that the support structure can be quickly locked and unlocked, the assembly for controlling the telescopic operation and the assembly for controlling the rotation are arranged together, the traditional separate independent use mode is changed, when the support structure is unfolded or folded, only the rotating member needs to be rotated and adjusted, the operation is very simple and convenient, the operation time is greatly shortened, when a large batch of electric power transmission floating frame structures are operated, the working speed is higher, the efficiency is higher, and the workload of workers is greatly reduced;

simultaneously, set up supplementary supporting component through the both sides in the spliced pole outside for further increase the support fixed action to the spliced pole outside, make the spliced pole more stable with floating the pedestal connection, when installing and dismantling it, only need through the pulling activity kelly can, the operation is got up very simply.

Drawings

Fig. 1 is a schematic structural view of a first embodiment of an electric power transportation floating frame structure for ocean temperature difference power generation provided by the invention;

FIG. 2 is a schematic structural diagram of the exterior of an electric power transportation floating frame structure for ocean temperature difference power generation provided by the invention;

FIG. 3 is a cross-sectional view taken along plane A-A of FIG. 2;

FIG. 4 is an enlarged view of portion A of FIG. 3;

FIG. 5 is a schematic view of the interior of the auxiliary support structure shown in FIG. 2;

FIG. 6 is a schematic structural view of a second embodiment of the electric power transportation floating frame structure for ocean temperature difference power generation according to the present invention;

fig. 7 is a schematic structural view of a partial position inside the telescopic rod shown in fig. 6.

Reference numerals in the figures

1. A floating base;

2. a support structure;

21. the device comprises a connecting seat 22, a connecting column 23, a telescopic rod 24, an adjusting component 25 and an auxiliary supporting component;

241. an adjusting rotating piece 242, a threaded rod 243, a bevel gear 244 and a positioning fixture block;

251. a rotating rod 252, a movable clamping rod 253 and a supporting spring;

3. a support plate;

4. connecting grooves;

5. a clamping hole;

6. a fixed structure;

61. the limiting rod 62, the movable piece 63, the clamping shaft 64 and the elastic piece.

Detailed Description

The invention is further described with reference to the following figures and embodiments.

First embodiment

Referring to fig. 1, fig. 2, fig. 3, fig. 4 and fig. 5, in which fig. 1 is a schematic structural view of a first embodiment of an electric power transportation floating frame structure for ocean temperature difference power generation according to the present invention; FIG. 2 is a schematic structural diagram of the exterior of an electric power transportation floating frame structure for ocean temperature difference power generation provided by the invention; FIG. 3 is a cross-sectional view taken along plane A-A of FIG. 2; FIG. 4 is an enlarged view of portion A of FIG. 3; fig. 5 is a schematic structural view of the inside of the auxiliary support structure shown in fig. 2. Electric power transportation floating frame structure for ocean thermoelectric power generation includes:

a floating base 1;

the supporting structure 2 is arranged at the top of the floating base 1, the supporting structure 2 comprises a connecting seat 21 fixedly mounted at the top of the floating base 1, a connecting column 22 is rotatably connected to the connecting seat 21, a telescopic rod 23 is slidably connected to the connecting column 22, an adjusting component 24 used for controlling the telescopic rod 23 to stretch and retract is arranged on the connecting column 22, and auxiliary supporting components 25 used for providing auxiliary support for the outer part of the connecting column 22 are arranged on two sides of the outer part of the connecting column 22;

the inboard bottom with spliced pole 22 of connecting seat 21 rotates to be connected, provides stable support for spliced pole 22, makes it rotate at showy base 1 top, and telescopic link 23 slides through the movable groove cooperation with spliced pole 22 inside and its adaptation, plays limiting displacement to telescopic link 23 for telescopic link 23 can be on spliced pole 22 vertical direction remove.

The adjusting assembly 24 comprises an adjusting rotating member 241 which rotates below the connecting column 22 and a threaded rod 242 which vertically rotates inside the connecting column 22, the outer portion of the threaded rod 242 is in threaded connection with the inner portion of the telescopic rod 23, bevel gears 243 are fixedly mounted at one end of the adjusting rotating member 241 and the outer portion of the threaded rod 242, the outer portions of the two bevel gears 243 are meshed, a positioning fixture block 244 is in threaded connection with the bottom end of the threaded rod 242, and the bottom of the positioning fixture block 244 is clamped on the inner side of the connecting seat 21.

Threaded rod 242 comprises the upper and lower two sections body of rod that have opposite screw, and threaded rod 242 upper segment screw and the inside thread groove adaptation of telescopic link 23 set up, threaded rod 242 lower section then sets up with the inside thread groove adaptation of location fixture block 244, rotate through threaded rod 242, can make telescopic link 23 and location fixture block 244 move in vertical direction respectively in opposite directions, and then realize driving location fixture block 244 and telescopic link 23 synchronous, two bevel gears 243 cooperate the use, adjust revolving part 241 through rotating externally, make two bevel gears 243 rotate simultaneously, and drive threaded rod 242 and rotate.

The inside of spliced pole 22 seted up with the activity groove of telescopic link 23 adaptation, just the outside of telescopic link 23 with the inside sliding connection in activity groove, the inside of telescopic link 23 be provided with the thread groove of threaded rod 242 adaptation.

The upper part and the lower part of the outer part of the threaded rod 242 are respectively provided with threads with opposite threads, the outer part of the positioning fixture block 244 is slidably connected with the inner part of the connecting column 22, and the bottom of the inner side of the connecting seat 21 is provided with a positioning groove matched with the positioning fixture block 244.

Through with the joint of location fixture block 244 in the constant head tank, mainly used plays the fixed action to spliced pole 22 bottom for spliced pole 22 can keep vertical direction stable connection with connecting seat 21, avoids spliced pole 22 to rotate, makes its vertical fixed state who keeps stable.

The adjusting rotating member 241 is composed of a knob and a connecting rod, and one end of the adjusting rotating member 241 extends from the outside of the connecting column 22 to the inside of the connecting column 22.

A plurality of supporting plates 3 for fixedly supporting the power transmission line are fixedly arranged outside the telescopic rod 23, and a plurality of fixing parts connected with the outside of the power transmission line are arranged on two sides of the top of each supporting plate 3.

The supporting plates 3 are sequentially distributed above the outer portion of the telescopic rod 23 from top to bottom and are mainly used for connecting the conveying cables and providing fixing and supporting for the outer portion of the conveying cables.

The auxiliary stay subassembly 25 including rotate in the outside dwang 251 of spliced pole 22, sliding connection has activity kelly 252 on the dwang 251, supporting spring 253 has been cup jointed to the outside of activity kelly 252, float the both sides at base 1 top all seted up with the card hole of activity kelly 252 adaptation, the bottom joint of activity kelly 252 in the card hole, and work as activity kelly 252 to during the inside shrink of dwang 251, make supporting spring 253 is extruded.

Two auxiliary stay subassemblies 25 are located the front and back both sides of spliced pole 22 respectively, a stability for increasing spliced pole 22 outside, inside being provided with the flexible groove with activity kelly 252 adaptation in dwang 251, it is flexible at its inside to make activity kelly 252, supporting spring 253 is located between activity kelly 252 and the dwang 251, mainly for activity kelly 252 provides elasticity support, inside shrink to dwang 251 at activity kelly 252, can extrude this supporting spring 253 shrink, through with activity kelly 252 bottom and card hole joint, make whole auxiliary stay subassembly 25 and float base 1 remain stable connection, and then play effective support fixed action to spliced pole 22.

The working principle of the electric power conveying floating frame structure for ocean temperature difference power generation provided by the invention is as follows:

when the power transmission floating frame structure needs to be retracted, folded and moved, the rotating piece 241 is rotated to enable the two bevel gears 243 to rotate, the threaded rod 242 can rotate, the threaded rod 242 rotates to respectively drive the telescopic rod 23 to be retracted downwards into the connecting column 22, the positioning fixture block 244 is retracted upwards to the bottom of the connecting column 22, the bottom of the positioning fixture block is separated from the positioning groove in the inner side of the connecting seat 21 until the telescopic rod 23 is fully retracted into the connecting column 22, the rotating piece 241 is rotated and adjusted to finish the retracting operation of the telescopic rod 23;

then, the movable clamping rod 252 is pulled to be contracted towards the inside of the rotating rod 251, the top end of the movable clamping rod 252 can simultaneously extrude the supporting spring 253 to be contracted, finally, the bottom end of the movable clamping rod 252 is separated from the clamping hole in the top of the floating base 1, then, the rotating rod 251 can be rotated to be attached to the connecting column 22, the operation is repeated on the other auxiliary supporting assembly 25, the two auxiliary supporting assemblies 25 are contracted, at the moment, the connecting column 22 is not fixed, the connecting column 22 can be rotated to be attached to the top of the floating base 1, and the contraction and folding operation on the supporting structure 2 is completed;

and when needs expand it, earlier through rotating spliced pole 22 to vertical state, then respectively with two activity kellies 252 bottom joint in the calorie of floating base 1 top downthehole for spliced pole 22 can keep the fixed state, later rotates to adjust commentaries on classics piece 241, makes location fixture block 244 and the inside joint of constant head tank respectively, and telescopic link 23 extends to the longest state.

by arranging the supporting structure 2, the supporting plate 3 is mainly supported, so that the supporting structure can be stably installed on an electric power transmission cable, meanwhile, by arranging the adjusting component 24, the telescopic operation on the telescopic rod 23 and the positioning fixture block 244 can be realized simultaneously, the supporting structure 2 is further quickly locked and unlocked, the telescopic control component and the rotary control component are arranged together, the traditional separated independent use mode is changed, when the supporting structure 2 is unfolded or folded, only the adjusting rotating piece 241 needs to be rotated, the operation is very simple and convenient, the operation time is greatly shortened, when a large batch of electric power transmission floating frame structures are operated, the working speed is higher, the efficiency is higher, and the workload of workers is greatly reduced;

simultaneously, set up supplementary supporting component 25 through the both sides in spliced pole 22 outside for further increase the support fixed action to spliced pole 22 outside, make spliced pole 22 and float base 1 and be connected more stably, when installing and dismantling it, only need through pulling activity kelly 252 can, the operation is got up very simply.

Second embodiment

Referring to fig. 6 and 7, a power transportation floating frame structure for ocean temperature difference power generation according to a first embodiment of the present invention, and a second embodiment of the present invention provides another power transportation floating frame structure for ocean temperature difference power generation, wherein the second embodiment does not hinder the independent implementation of the technical solution of the first embodiment.

Specifically, the invention provides another electric power transportation floating frame structure for ocean temperature difference power generation, which is characterized in that:

a plurality of spread grooves 4 have been seted up to the outside top of telescopic link 23, the middle joint of backup pad 3 in the spread groove 4, joint hole 5 has all been seted up to the both sides of 3 bottoms of backup pad, it is right to set up a plurality of being used for on the telescopic link 23 the fixed knot who connects in 3 bottoms of backup pad 6, fixed knot constructs 6 and includes vertical fixed mounting in the inside gag lever post 61 of telescopic link 23, moving part 62 has been cup jointed to the outside of gag lever post 61, just moving part 62 both sides extend respectively to the outside both sides of telescopic link 23, the equal fixed mounting in both sides at moving part 62 top has joint axle 63, the outside joint of joint axle 63 in joint hole 5, elastic component 64 is cup jointed to the outside of gag lever post 61.

The connecting groove 4 is matched with the mounting groove arranged in the middle of the supporting plate 3 and is clamped with the mounting groove in a matching way, so that the support plate 3 can be stably connected with the outer part of the connecting column 22, the middle part of the moving piece 62 is connected with the outer part of the limiting rod 61 in a sliding way, and the limiting function is mainly played on the moving piece 62, so that the moving piece 62 can stably slide on the telescopic rod 23 in the vertical direction, and the two clamping shafts 63 are respectively positioned at the left and right sides of the top of the moving part 62 and are matched with the two clamping holes 5, and through the matching clamping of the two clamping shafts, for further fixing the support plate 3 and the connecting column 22 in the front-back direction, so that the two are stably connected, the resilient member 64 primarily provides resilient support for the moveable member 62, and when the moveable member 62 moves downwardly, the bottom of the clamping device can extrude the elastic piece 64 to contract, and the clamping shaft 63 at the top of the clamping device can be stably clamped with the inside of the clamping hole 5 by means of the elasticity of the elastic piece 64;

the fixing structure 6 is mainly used for fixing the position of the support plate 3, so that the support plate can be stably connected with the telescopic rod 23, free installation and disassembly between the support plate 3 and the telescopic rod 23 are realized, when the movable piece 62 is disassembled, the movable piece 62 is pressed downwards to separate the clamping shaft 63 at the top of the movable piece from the clamping hole 5, then the support plate 3 is pulled outwards, when the movable piece is assembled, the installation groove in the middle of the support plate 3 is aligned and clamped with the connecting groove 4, and finally the clamping shaft 63 is clamped with the inside of the clamping hole 5, when in installation and disassembly, the operation is very simple and convenient, the original design of the fixed supporting plate 3 is changed, the corresponding number of supporting plates 3 can be selected and installed according to the actual use requirement, simultaneously, the supporting plate 3 is convenient to maintain and replace, so that the supporting plate 3 is more flexible in use, and the waste of resources of the supporting plate 3 can be avoided.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The utility model provides an electric power transportation floating frame structure for ocean thermoelectric generation which characterized in that includes:

a floating base;

2. The electric power transportation floating frame structure for ocean temperature difference power generation according to claim 1, wherein a movable groove adapted to the telescopic rod is formed in the connecting column, the outer portion of the telescopic rod is slidably connected to the inner portion of the movable groove, and a threaded groove adapted to the threaded rod is formed in the telescopic rod.

3. The electric power transportation floating frame structure for ocean temperature difference power generation according to claim 1, wherein the upper part and the lower part of the outer part of the threaded rod are respectively provided with threads with opposite threads, the outer part of the positioning clamping block is slidably connected with the inner part of the connecting column, and the bottom of the inner side of the connecting seat is provided with a positioning groove matched with the positioning clamping block.

4. The power transportation floating frame structure for ocean thermal power generation according to claim 1, wherein the adjusting rotating member is composed of a knob and a connecting rod, and one end of the adjusting rotating member extends from the outside of the connecting column to the inside of the connecting column.

5. The power transmission floating frame structure for ocean temperature difference power generation according to claim 1, wherein a plurality of supporting plates for fixedly supporting the power transmission line are fixedly installed at the outside of the telescopic rod, and a plurality of fixing members connected with the outside of the power transmission line are installed at both sides of the top of the supporting plates.

6. The electric power transportation floating frame structure for ocean thermoelectric power generation according to claim 1, wherein the auxiliary supporting component comprises a rotating rod rotating outside the connecting column, a movable clamping rod is connected on the rotating rod in a sliding manner, and a supporting spring is sleeved outside the movable clamping rod.

7. The electric power transportation floating frame structure for ocean thermoelectric power generation according to claim 6, wherein both sides of the top of the floating base are provided with clamping holes adapted to the movable clamping rods, the bottom ends of the movable clamping rods are clamped in the clamping holes, and when the movable clamping rods contract towards the inside of the rotating rod, the supporting springs are squeezed.

8. The floating frame structure for power transmission for ocean temperature difference power generation according to claim 7, wherein a plurality of connecting grooves are formed above the outer portion of the telescopic rod, the middle of the supporting plate is clamped in the connecting grooves, clamping holes are formed in both sides of the bottom of the supporting plate, and a plurality of fixing structures for clamping the bottom of the supporting plate are arranged on the telescopic rod.

9. The electric power transportation floating frame structure for ocean temperature difference power generation according to claim 8, wherein the fixed structure comprises a limiting rod vertically and fixedly installed inside the telescopic rod, a movable member is sleeved outside the limiting rod, and two sides of the movable member respectively extend to two sides of the outside of the telescopic rod.

10. The electric power transportation floating frame structure for ocean temperature difference power generation according to claim 9, wherein clamping shafts are fixedly mounted on both sides of the top of the movable member, the outer portions of the clamping shafts are clamped in the clamping holes, and elastic members are sleeved on the outer portions of the limiting rods.