CN110606179A - Low-speed navigation telescopic anti-current board of deep-sea large-scale manned carrier - Google Patents

Abstract

A low-speed sailing telescopic anti-flow plate of a large deep sea manned carrier comprises a pressure-resistant shell, wherein the pressure-resistant shell is provided with a light shell, a hole is formed in the light shell, a fixed wing is arranged in the hole in a matched mode, a wing hole is formed in the fixed wing, a first-stage telescopic wing is arranged in the wing hole of the fixed wing, and a first-stage distance measuring device is arranged between the inner surface of the fixed wing and the outer surface of the first-stage telescopic wing; the primary telescopic wing is also internally provided with a wing hole, the bottom of the primary telescopic wing is also fixed with a sealing plate with a hole, the secondary telescopic wing is arranged in the wing hole of the primary telescopic wing, and a secondary distance measuring device is arranged between the inner surface of the primary telescopic wing and the outer surface of the secondary telescopic wing; the pressure casing is fixed with a main base, the main base is fixed with a hydraulic cylinder, a primary rod is installed in the inner cavity of the hydraulic cylinder, the inner cavity is formed in the middle of the primary rod, a secondary rod is installed in the inner cavity, the primary rod penetrates through the sealing plate with the hole, the top end of the secondary rod is hinged with a big lug plate, and the big lug plate is fixed with the low end of the secondary telescopic wing. The work is reliable.

Description

Low-speed navigation telescopic anti-current board of deep-sea large-scale manned carrier

Technical Field

The invention relates to the technical field of current-resisting plates, in particular to a telescopic current-resisting plate for low-speed navigation of a deep-sea large-scale manned carrier.

Background

Currently, the design of the stabilizer of a large deep sea manned vehicle generally takes the resistance performance of high-speed sailing, stability and maneuverability, the size limit requirement of port entering and exiting, and the possibility of winding collision under complex working conditions as main design bases, the projected area of the stabilizer is relatively small, and the size of the stabilizer does not exceed the size of a main body as much as possible or slightly exceeds the size of the main body, and the design has the following typical problems: the design of the small projection area stabilizing wing leads to insufficient anti-current capability of the submersible during low-speed navigation and the risk of uncontrollable wave following and current following when large ocean currents occur. For the transverse ocean current with the same flow speed, the resultant velocity inflow angle formed when the submersible is sailed at the low sailing speed is larger, and the resultant velocity inflow angle formed when the submersible is sailed at the high sailing speed is smaller. A larger deflection angle will result in a larger disturbance force, which can only be resisted by the provision of a larger area of the tail stabilizer. However, the design of the span length of the stabilizing wing is limited, and the effect of increasing the chord length is not obvious, so that the problem of weak current-resisting capability of the submersible in low-speed sailing is brought. When the submersible adopts larger extension to form larger stable wing area, the maneuverability of the submersible is seriously weakened, the operation capability is influenced, and the navigation resistance is increased.

Disclosure of Invention

The applicant provides a low-speed sailing telescopic flow resisting plate for the large-scale deep-sea manned carrier aiming at the defects in the prior art, so that the working condition requirements of high-speed sailing of the large-scale deep-sea manned carrier, such as maneuverability, port entering and exiting size limitation and the like are met, and the requirement of low-speed sailing stability is met.

The technical scheme adopted by the invention is as follows:

a low-speed sailing telescopic flow resisting plate of a large deep sea manned carrier comprises a pressure-resistant shell, wherein a light shell is supported and installed on the pressure-resistant shell through a plurality of reinforcing ribs at intervals, a hole is formed in the light shell, a fixed wing is installed in the hole in a matched mode, a wing hole is formed in the fixed wing, a first-stage telescopic wing is installed in the wing hole of the fixed wing, and a first-stage distance measuring device is installed between the inner surface of the fixed wing and the outer surface of the first-stage telescopic wing; the primary telescopic wing is also internally provided with a wing hole, the bottom of the primary telescopic wing is also fixed with a sealing plate with a hole, the secondary telescopic wing is arranged in the wing hole of the primary telescopic wing, and a secondary distance measuring device is arranged between the inner surface of the primary telescopic wing and the outer surface of the secondary telescopic wing; the pressure-resistant casing is fixed with a main base, the main base is fixed with a hydraulic cylinder, a primary rod is installed in an inner cavity of the hydraulic cylinder, an inner cavity is formed in the middle of the primary rod, a secondary rod is installed in the inner cavity, the top end of the primary rod penetrates through a sealing plate with holes, the top end of the secondary rod is hinged with a big lug plate, and the big lug plate is fixed with the lower end of a secondary telescopic wing.

The further technical scheme is as follows:

the upper part of the first-level rod is further fixed with a horizontal base, small ear plates are symmetrically arranged on the upper surface of the horizontal base through a supporting device, the tops of the two small ear plates are planes, and the planes are fixed with sealing plates with holes.

And in a normal state, the top surfaces of the fixed wing, the primary telescopic wing and the secondary telescopic wing are flush.

The cross sections of the fixed wing, the primary telescopic wing and the secondary telescopic wing are the same in shape.

The heights of the fixed wings, the primary telescopic wings and the secondary telescopic wings are gradually reduced from large to small.

The invention has the following beneficial effects:

the invention has compact and reasonable structure and convenient operation, and can conveniently complete the extending and retracting actions of the telescopic wings through the ingenious layout of the fixed wings and the telescopic wings, thereby automatically controlling the transverse projection area of the carrier and meeting the requirements of the carrier on performance under different navigation working conditions; when the aircraft is sailed at a high speed, the telescopic wings retract into the fixed wings, so that the resistance performance requirement and the maneuverability requirement during sailing are met; when the vehicle sails at a low speed, the telescopic wings extend out, so that the transverse projection area is increased, and the sailing stability of the vehicle is improved; the device has simple structure, reliable function and obvious effect, and can be widely applied to large-scale deep-sea manned carriers or submarines.

The invention effectively solves the contradiction problems that the working conditions of the large manned carrier in deep sea such as high-speed navigation, port entering and exiting and the like in the prior art require that the stabilizing wing is as short as possible and has as small an area as possible, and the working conditions of the large manned carrier in deep sea such as maneuverability, port entering and exiting size limitation and the like are required to be as large as possible and have as large an area as possible, thereby not only meeting the working condition requirements of high-speed navigation, port entering and exiting size limitation and the like of the large manned carrier in.

Meanwhile, the invention has the following advantages:

1) when the navigation speed is higher, the navigation stability is better, and the area of the tail stabilizing wing can be properly reduced, so that the resistance in high-speed navigation can be reduced.

2) The multi-layer variable-area telescopic structure can automatically adjust the area of the stable wing according to the size of ocean current, namely, the area can be adjusted as required.

3) The operation of the device can realize automation without increasing the control difficulty.

4) The device has simple structure, reliable function and obvious effect.

5) The device can improve the anti-flow capacity of the underwater vehicle with lower cost, and is also suitable for surface ships.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a half sectional view of the present invention.

Fig. 3 is a front view (full sectional view, working state is initial position) of the present invention.

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

Fig. 5 is a top view of the present invention.

Fig. 6 is a schematic view of the present invention in an operating state (extended intermediate state of the telescopic wing).

Fig. 7 is a schematic view of the present invention in an operating state (a final state of extension wing extension).

Wherein: 101. a pressure-resistant housing; 102. a light housing; 103. reinforcing ribs; 2. a fixed wing; 3. a first stage telescopic wing; 4. a second stage telescopic wing; 5. a primary ranging device; 6. a secondary ranging device; 7. a hydraulic cylinder; 8. a primary lever; 9. a secondary lever;

301. a sealing plate with holes;

701. a main base;

801. a small ear plate; 802. a horizontal base; 803. a support device;

901. a big ear plate.

Detailed Description

The following describes embodiments of the present invention with reference to the drawings.

As shown in fig. 1-7, the low-speed sailing retractable flow-resisting plate for the deep sea large-scale manned vehicle of the embodiment includes a pressure-resistant casing 101, a light casing 102 is supported and mounted on the pressure-resistant casing 101 through a plurality of spaced reinforcing ribs 103, a hole is formed in the light casing 102, a fixed wing 2 is mounted in the hole in a matching manner, a wing hole is formed in the fixed wing 2, a first-stage retractable wing 3 is mounted in the wing hole of the fixed wing 2, and a first-stage distance measuring device 5 is mounted between the inner surface of the fixed wing 2 and the outer surface of the first-stage retractable wing 3; the primary telescopic wing 3 is also internally provided with a wing hole, the bottom of the primary telescopic wing 3 is also fixed with a sealing plate 301 with a hole, the secondary telescopic wing 4 is arranged in the wing hole of the primary telescopic wing 3, and a secondary distance measuring device 6 is arranged between the inner surface of the primary telescopic wing 3 and the outer surface of the secondary telescopic wing 4; be fixed with a main base 701 on the pressure casing 101, be fixed with pneumatic cylinder 7 on the main base 701, primary rod 8 is installed to the inner chamber of pneumatic cylinder 7, and primary rod 8 middle part is provided with the inner chamber, installs second grade pole 9 in the inner chamber, and foraminiferous shrouding 301 is passed on 8 tops of primary rod, and the top of second grade pole 9 articulates there is big otic placode 901, and big otic placode 901 is fixed with the low side of the flexible wing 4 of second grade.

The upper part of the primary rod 8 is also fixed with a horizontal base 802, the upper surface of the horizontal base 802 is symmetrically provided with small ear plates 801 through a supporting device 803, the tops of the two small ear plates 801 are planes, and the planes are fixed with the perforated closing plate 301.

In a normal state, the top surfaces of the fixed wing 2, the first-stage telescopic wing 3 and the second-stage telescopic wing 4 are flush.

The cross-sectional shapes of the fixed wing 2, the primary telescopic wing 3 and the secondary telescopic wing 4 are the same.

The heights of the fixed wing 2, the primary telescopic wing 3 and the secondary telescopic wing 4 are gradually reduced from large to small.

The invention has the following specific structure and functions:

the pressure-resistant casing 101 is supported and installed with a light casing 102 through three spaced reinforcing ribs 103, the light casing 102 is provided with holes, fixed wings 2 are fixedly installed in the holes, wing holes are formed in the fixed wings 2, a first-stage telescopic wing 3 is arranged in the wing holes of the fixed wings 2, the first-stage telescopic wing 3 is also provided with wing holes, and a hole-containing sealing plate 301 is fixed at the bottom of the first-stage telescopic wing 3; the secondary telescopic wing 4 is arranged in a wing hole of the primary telescopic wing 3. The outer surface of the first-stage telescopic wing 3 is matched with the inner surface of the wing hole of the fixed wing 2, and the first-stage telescopic wing 3 can be ensured to telescopically slide up and down along the inner surface of the wing hole of the fixed wing 2; the outer surface of the second-stage telescopic wing 4 is matched with the inner surface of the wing hole of the first-stage telescopic wing 3, and the second-stage telescopic wing 4 can be ensured to be stretched and slid up and down along the inner surface of the wing hole of the first-stage telescopic wing 3. The top ends of the fixed wing 2, the primary telescopic wing 3 and the secondary telescopic wing 4 are flush in a normal state. The primary distance measuring device 5 is arranged on the inner surface of the fixed wing 2 and the outer surface of the primary telescopic wing 3 and is used for measuring the telescopic distance of the primary telescopic wing 3 along the fixed wing 2; the secondary distance measuring device 6 is arranged on the inner surface of the primary telescopic wing 3 and the outer surface of the secondary telescopic wing 4 and measures the telescopic distance of the secondary telescopic wing 4 relative to the primary telescopic wing 3.

The main base 701 is disposed under the stationary vane 2 and fixed to the main body structure. The hydraulic cylinder 7 is fixed to the main base 701. The primary rod 8 is arranged in the inner cavity of the hydraulic cylinder body 7 and can move up and down along the axis of the hydraulic cylinder body 7 under the action of hydraulic pressure; the secondary rod 9 is arranged in the inner cavity of the primary rod 8, the top end of the secondary rod extends out of the round hole with the hole sealing plate 301, and the secondary rod 9 can move up and down along the axis of the primary rod 8 under the action of hydraulic pressure. The horizontal base 802 is fixedly arranged at a position slightly lower than the top end of the primary rod 8, the two small ear plates 801 are arranged at two sides of the primary rod 8 through the supporting device 803, the bottom end is hinged with the horizontal base 802, and the top end is fixedly connected with the perforated closing plate 301. The bottom of the big ear plate 901 is hinged with the top end of the second-stage rod 9, and the top of the big ear plate is fixedly connected with the bottom end of the second-stage telescopic wing 4 and used for pushing the second-stage telescopic wing 4 to stretch.

The invention can adjust the requirements of the large deep sea manned carrier on the performance thereof under different sailing conditions, has higher requirements on the resistance performance and the carrier maneuverability during high-speed sailing, and is in a contraction state as shown in figures 2 and 3, namely the top ends of the first-stage telescopic wing 3 and the second-stage telescopic wing 4 are flush with the top end of the fixed wing 2. The specific implementation when the vehicle is turned from high speed to low speed is as follows:

in the environment with ocean currents, when a large deep sea manned carrier changes from a high-speed sailing state to a low-speed sailing state, the included angle between the sailing direction of the carrier and the flow direction of ocean currents and the ocean current speed can be measured through the flow direction and the flow speed sensors carried by the carrier, the requirement for the stability of the carrier is calculated through the sailing speed of the carrier, and the required area of a stabilizing wing is calculated according to the required stability. Then, under the action and the control of hydraulic pressure, the primary rod 8 extends out of the hydraulic cylinder 7 and drives the horizontal base 802 to move together, the horizontal base 802 pushes the two small lug plates 801 to move, the two small lug plates 801 push the perforated sealing plate 301 to move, and the perforated sealing plate 301 pushes the primary telescopic wing 3 to extend out of the fixed wing 2, so that the area of the stabilizing wing is increased. Before the primary telescopic wing 3 does not reach the telescopic stroke, the secondary rod 9 moves synchronously with the primary rod 8, namely the two rods are relatively static. At this time, the second-stage rod 9 drives the big ear plate 901 to move together when moving, and pushes the second-stage telescopic wing 4 and the first-stage telescopic wing 3 to move synchronously in the same direction. In the process of extending the first-stage telescopic wing 3, the extending distance of the first-stage telescopic wing 3 relative to the fixed wing 2 is measured by the first-stage distance measuring device 5 at any moment, and the transverse projection sectional area of the stabilizing wing is fed back to the carrier to calculate whether the transverse projection sectional area meets the stability requirement, and if the low-speed navigation stability requirement of the carrier is met, the hydraulic pressure is controlled to stop the telescopic wing to continue extending.

If the wing area of the first-stage telescopic wing 3 still cannot meet the stability requirement of low-speed navigation of the large deep-sea manned carrier after reaching the extension stroke as shown in fig. 6, the extension function of the second-stage telescopic wing 4 is started, and the wing area is further increased as shown in the figure. Because the first-level telescopic wing 3 reaches the extension stroke, the first-level rod 8, the horizontal base 802, the two small ear plates 801, the perforated sealing plate 301 and the first-level telescopic wing 3 are all in a static state, as shown in fig. 6, at the moment, under the hydraulic control, the second-level rod 9 starts to move to extend out the first-level rod 8 and drive the big ear plate 901 to move, and the big ear plate 901 pushes the second-level telescopic wing 4 to extend out the wing hole of the first-level telescopic wing 3, so that the whole area of the stabilizing wing is continuously increased, as shown in fig. 7, until the requirement of navigation stability is met. In the process of extending the second-stage telescopic wing 4, the sliding-out distance of the second-stage telescopic wing 4 relative to the first-stage telescopic wing 3 is measured through the second-stage distance measuring device 6 at any moment, and whether the increase of the transverse projection sectional area of the carrier meets the requirement on stability is calculated.

When the carrier changes from low-speed navigation to high-speed navigation, the requirements on the rapidity and the maneuverability of the carrier are high, and at the moment, the area of the wing needs to be reduced, the resistance of the wing needs to be reduced, and the maneuverability is increased. The retraction of the telescopic wings is opposite to the extension described above.

First, the primary rod 8, the horizontal base 802, the two small ear plates 801, the apertured cover plate 301, and the primary telescopic fin 3 are all in a stationary state with respect to the stationary fin 2. At this time, under the hydraulic control, the secondary rod 9 retracts toward the inner cavity of the primary rod 8, and drives the big lug plate 901 to retract together, and the big lug plate 901 drives the secondary telescopic wing 4 to retract toward the wing hole of the primary telescopic wing 3. When the top end of the secondary telescopic wing 4 is flush with the top end of the primary telescopic wing 3, the secondary rod 9 stops moving and stops the big lug plate 901 and the secondary telescopic wing 4, and meanwhile, under the hydraulic action, the secondary rod 9 is locked in the inner cavity of the primary rod 8, as shown in fig. 3. If the stabilizer wing area still meets the high speed sailing maneuverability requirements, the stabilizer wing area needs to be reduced continuously. At this time, under the hydraulic control, the primary rod 8 starts to retract into the hydraulic cylinder 7, the primary rod 8 drives the horizontal base 802 to retract, the horizontal base 802 drives the two small ear plates 801 to retract, and the small ear plates 801 drive the perforated sealing plate 301 and the primary telescopic wing 3 to retract into the wing holes of the fixed wing 2 until the top end of the primary telescopic wing 3 is flush with the top end of the fixed wing 2, as shown in fig. 2 and 3. At this time, because the secondary rod 9 is locked in the inner cavity of the primary rod 8, the secondary rod 9, the big ear plate 901 and the secondary telescopic wing 4 can synchronously move at the same speed and the same direction along with the movement of the primary rod 8. The two-stage telescopic wings are retracted into the wing holes of the fixed wing 2, so that the area of the stable wing of the carrier during high-speed navigation is reduced, the navigation resistance is reduced, and the maneuverability is improved.

The above description is intended to be illustrative and not restrictive, and the scope of the invention is defined by the appended claims, which may be modified in any manner within the scope of the invention.

Claims (5)

1. The utility model provides a scalable anti flow board of large-scale manned carrier low-speed navigation in deep sea which characterized in that: the pressure-resistant casing is characterized by comprising a pressure-resistant casing (101), wherein a light casing (102) is supported and installed on the pressure-resistant casing (101) through a plurality of reinforcing ribs (103) at intervals, a hole is formed in the light casing (102), a fixed wing (2) is installed in the hole in a matched mode, a wing hole is formed in the fixed wing (2), a first-stage telescopic wing (3) is installed in the wing hole of the fixed wing (2), and a first-stage distance measuring device (5) is installed between the inner surface of the fixed wing (2) and the outer surface of the first-stage telescopic wing (3); wing holes are also formed in the primary telescopic wing (3), a sealing plate (301) with holes is further fixed at the bottom of the primary telescopic wing (3), the secondary telescopic wing (4) is installed in the wing holes of the primary telescopic wing (3), and a secondary distance measuring device (6) is installed between the inner surface of the primary telescopic wing (3) and the outer surface of the secondary telescopic wing (4); the pressure casing (101) is fixed with a main base (701), a hydraulic cylinder (7) is fixed on the main base (701), a primary rod (8) is installed in an inner cavity of the hydraulic cylinder (7), an inner cavity is formed in the middle of the primary rod (8), a secondary rod (9) is installed in the inner cavity, the top end of the primary rod (8) penetrates through the sealing plate with holes (301), the top end of the secondary rod (9) is hinged with a big lug plate (901), and the big lug plate (901) is fixed with the lower end of the secondary telescopic wing (4).

2. The deep sea large-sized manned vehicle low speed sailing retractable current resisting plate according to claim 1, characterized in that: the upper portion of the first-level rod (8) is further fixed with a horizontal base (802), the upper surface of the horizontal base (802) is symmetrically provided with small ear plates (801) through a supporting device (803), the tops of the two small ear plates (801) are planes, and the planes are fixed with the sealing plate (301) with holes.

3. The deep sea large-sized manned vehicle low speed sailing retractable current resisting plate according to claim 1, characterized in that: and in a normal state, the top surfaces of the fixed wing (2), the primary telescopic wing (3) and the secondary telescopic wing (4) are flush.

4. The deep sea large-sized manned vehicle low speed sailing retractable current resisting plate according to claim 1, characterized in that: the cross sections of the fixed wing (2), the primary telescopic wing (3) and the secondary telescopic wing (4) are the same in shape.

5. The deep sea large-sized manned vehicle low speed sailing retractable current resisting plate according to claim 1, characterized in that: the heights of the fixed wing (2), the primary telescopic wing (3) and the secondary telescopic wing (4) are gradually reduced from large to small.