CN206218176U - Microminiature submarine - Google Patents

Abstract

The utility model provides a miniature submarine. The body of the boat includes a sealed bottom ballast tank and a sealed top buoyancy tank. The ballast tank is provided with an inner cavity to accommodate batteries, fuel tanks and diesel generators. It is connected with the buoyancy chamber on the top through the sealed line pipe; the buoyancy chamber on the top is provided with an inner cavity to accommodate electronic equipment, and the electronic equipment is connected to the diesel generator and/or battery through the cable arranged in the line pipe; the submarine The front part of the hull is provided with an upwardly extending mast, and the mast is provided with a weather detection mechanism. The weather detection mechanism is connected to the electronic equipment through the cables in the sealed line pipeline; The rocket launcher includes a sealed launch chamber, and the top of the launch chamber is provided with an openable airtight door, and the bottom of the sealed launch chamber is fixed in the ballast tank and runs through the top wall of the ballast tank in the vertical direction And the buoyancy chamber to protrude from the hull of the submarine.

Description

miniature submarine

technical field

The utility model relates to the technical field of machinery, in particular to a miniature submarine.

Background technique

At present, there are three commonly used current measurement methods: buoy drift current measurement method, fixed-point current measurement method and walking current measurement method.

Among them, the buoy drift method is a traditional ocean current measurement method, which must make the buoy move with the ocean current, and then calculate the velocity and direction of the ocean current by recording the space-time position of the buoy. The key to this method is to determine the buoy's position at different times, usually using radio, acoustic or satellite positioning technology to track drifting buoys to measure ocean currents.

The fixed-point measurement method is currently the most commonly used method of ocean current measurement. It is to install the current measurement equipment (current meter) on an anchored ship, buoy, submersible buoy or offshore platform, so as to measure the ocean current at a certain position in the ocean for a long time. Measurement. Measuring the ocean current while the ship is sailing can not only save time and improve efficiency, but also can observe multi-layer ocean current at the same time. This measurement method is called the sailing current measurement method. The realization and popularization of this flow measurement method benefited from the advent and development of the Acoustic Doppler Current Profiler (ADCP). At present, most oceanographic survey ships are equipped with ADCP. In addition, ocean circulation can be estimated from the mean sea level data measured by satellite altimeters. The most direct way is to subtract the geoid to obtain the dynamic height, and then use the geostrophic balance equation to calculate ocean circulation. This approach yields only large-scale ocean dynamics.

Due to the shortcomings of the above-mentioned ocean current measurement methods in the design of observation schemes and the performance of observation equipment, the current measurement of ocean currents has certain limitations in terms of rapid, real-time, and large-scale measurement of ocean currents. The disadvantage of the buoy drift method is that the buoy can only follow the current to measure along the direction of the ocean current. If you need to obtain the ocean current data in the adjacent sea area, you need to release another buoy, and the buoy generally cannot be recovered. The fixed-point measurement method can only be used for fixed-point observation, and the measurement error is large when the current is small; because it is difficult for ships or buoys to anchor in the deep sea, it is difficult to obtain current data in the deep sea using this method. ADCP instruments are expensive, and are generally equipped on oceanographic survey ships. The cost of use is relatively high, and due to the limitation of transducer installation location and measurement frequency, there is a certain blind area in ocean current measurement (from the sea surface to 30-40cm below the sea surface).

Utility model content

Aiming at the problems existing in the prior art, the technical problem to be solved by the utility model is to provide a micro-submarine capable of measuring the flow velocity and flow direction of the surface ocean current in a fast, real-time, and large-scale ocean current environment.

In order to solve the above problems, the embodiment of the utility model proposes a miniature submarine, including: a submarine hull, wherein the hull includes a sealed bottom ballast tank and a sealed top buoyancy tank, the ballast tank A hollow inner chamber is provided to accommodate batteries, fuel tanks, and diesel generators, and is connected to the buoyancy chamber on the top through a sealed line pipeline; the buoyancy chamber on the top is provided with an inner hollow chamber to accommodate electronic equipment , the electronic device is connected to the diesel generator and/or the storage battery through a cable arranged in the pipeline;

The rear part of the submarine is provided with a propeller, a horizontal rudder, and a vertical rudder, the propeller is connected to the battery, and the horizontal rudder and the vertical rudder are connected to the electronic equipment in the buoyancy chamber; A mast extending upwards is provided at the front of the mast, and a weather detection mechanism is provided on the mast, and the weather detection mechanism is connected to the electronic equipment through a cable in a sealed line duct; A rocket launcher extending vertically, the rocket launcher includes a sealed launch chamber, the top of which is provided with an openable airtight door, and the bottom of the sealed launch chamber is fixed in the ballast compartment inside and vertically through the top wall of the ballast tank and the buoyancy tank to protrude from the hull of the submarine;

Wherein, the rear part of the submarine is also provided with a sealed casing protruding from the hull, and an antenna is arranged in the casing, and the antenna is connected to the electronic equipment through a cable passing through the sealed line duct.

Further, the top wall of the buoyancy chamber is provided with an openable and closable sealed hatch.

Further, the enclosure is also provided with a suction and exhaust pipe, and the suction and exhaust pipe protrudes from the top of the enclosure.

Further, ballast is provided at the front and rear of the ballast tank.

Further, the electronic equipment includes a submarine control system for controlling the operation of the miniature submarine, a meteorological data processing system for controlling the meteorological detection mechanism to perform meteorological detection, and a rocket for controlling the operation of the rocket launching device. Control System.

Further, the electronic equipment also includes a remote communication system, the remote communication system is connected to the remote server through the antenna of the enclosure to send the measurement data to the remote server, and receives control instructions sent by the remote server to control the miniature submarine running.

Further, the remote communication system includes a satellite positioning device and a satellite communication device, wherein the sampling frequency of the satellite positioning device is 10 Hz, and the communication frequency of the satellite communication device is 1 Hz.

Further, the micro-submarine carries a temperature-depth conductivity sensor CTD, an up-looking acoustic Doppler profiler ADCP and a down-looking acoustic Doppler profiler ADCP as measurement equipment, and the CTD is installed on the head of the micro-miniature submarine, and the CTD Measure the seawater temperature and conductivity profile. ADCP is a broadband ADCP configured with four-beam oblique orthogonal JANUS. It is equipped with two sets of ADCP installed front and rear. One set is an upward-looking ADCP for measuring the ocean current profile above the vehicle; the other set For downward looking ADCP, it measures the ocean current profile under the vehicle, and also has the function of measuring the speed of the vehicle, that is, it has the function of tracking the bottom and measuring the height of the bottom; the measurement of the trapezoidal profile is carried out on the set route, including the level of the water surface Navigation, submerged navigation, underwater horizontal navigation, floating navigation, use ADCP to measure the current profile and water depth changes during the navigation.

Further, during the voyage of the miniature submarine, the CTD measurement interval is 5 minutes, each acquisition time is not less than 60 s, and the sampling rate is 16-24 Hz.

Further, the sampling rate of the ADCP is 1 Hz.

The beneficial effects of the above-mentioned technical solution of the utility model are as follows: the above-mentioned technical solution proposes a miniature submarine, which can take into account both economy and practicability, simple structure, safe and reliable, good maintainability, low cost and small volume. The micro-submarine proposed by the above-mentioned technical scheme can carry maritime detection equipment to navigate and launch independently, save manpower, reduce costs and risks, and expand the detection range.

Description of drawings

Fig. 1 is the structural representation of the miniature submarine of the utility model embodiment.

detailed description

In order to make the technical problems, technical solutions and advantages to be solved by the utility model clearer, the following will describe in detail with reference to the drawings and specific embodiments.

In order to solve the above-mentioned problems, the utility model embodiment proposes a kind of miniature submarine, comprising: including: the submarine hull, wherein the hull includes a sealed bottom ballast tank 13 and a sealed top buoyancy tank 7, so The ballast tank is provided with an inner hollow cavity to accommodate the storage battery 4, the fuel tank 5, and the diesel generator 6, and is connected with the buoyancy cabin 7 at the top through a sealed line pipeline; the buoyancy cabin 7 at the top is provided with an inner cavity Empty inner cavity to accommodate electronic equipment 8, said electronic equipment 8 is connected to said diesel generator 6 and/or storage battery 4 through a cable arranged in the line duct;

The rear part of the submarine is provided with a propeller 1, a horizontal rudder 2, and a vertical rudder 3, the propeller 1 is connected to the battery 4, and the horizontal rudder 2 and the vertical rudder 3 are connected to the electronic components in the buoyancy chamber. Equipment; the front part of the submarine hull is provided with an upwardly extending mast, and the mast is provided with a weather detection mechanism. The weather detection mechanism 12 is connected to the electronic equipment through a cable in a sealed line duct; it also includes setting The rocket launcher 9 that extends vertically in the middle part of the submarine hull, the rocket launcher 9 includes a sealed launch chamber, and the top of the launch chamber is provided with an openable sealed hatch, and the sealed launch chamber The bottom of the ballast tank is fixed in the ballast tank and vertically penetrates the ballast tank top wall and the buoyancy tank to extend out of the submarine hull;

Wherein the rear part of the submarine is also provided with a sealed enclosure 10 protruding from the hull, and the enclosure 10 is provided with an antenna 11, and the antenna 11 is connected to the electronic equipment through a cable in the sealed line duct 8.

Further, the top wall of the buoyancy chamber is provided with an openable and closable sealed hatch.

Further, the enclosure is also provided with a suction and exhaust pipe, and the suction and exhaust pipe protrudes from the top of the enclosure.

Further, ballast 14 is provided at the front and rear of the ballast tank 13 .

Further, the electronic equipment includes a submarine control system for controlling the operation of the miniature submarine, a meteorological data processing system for controlling the meteorological detection mechanism to perform meteorological detection, and a rocket for controlling the operation of the rocket launching device. Control System.

Further, the electronic equipment also includes a remote communication system, the remote communication system is connected to the remote server through the antenna of the enclosure to send the measurement data to the remote server, and receives control instructions sent by the remote server to control the miniature submarine running.

Further, the remote communication system includes a satellite positioning device and a satellite communication device, wherein the sampling frequency of the satellite positioning device is 10 Hz, and the communication frequency of the satellite communication device is 1 Hz.

Further, the micro-submarine carries a temperature-depth conductivity sensor CTD, an up-looking acoustic Doppler profiler ADCP and a down-looking acoustic Doppler profiler ADCP as measurement equipment, and the CTD is installed on the head of the micro-miniature submarine, and the CTD Measure the seawater temperature and conductivity profile. ADCP is a broadband ADCP configured with four-beam oblique orthogonal JANUS. It is equipped with two sets of ADCP installed front and rear. One set is an upward-looking ADCP for measuring the ocean current profile above the vehicle; the other set For downward looking ADCP, it measures the ocean current profile under the vehicle, and also has the function of measuring the speed of the vehicle, that is, it has the function of tracking the bottom and measuring the height of the bottom; the measurement of the trapezoidal profile is carried out on the set route, including the level of the water surface Navigation, submerged navigation, underwater horizontal navigation, floating navigation, use ADCP to measure the current profile and water depth changes during the navigation.

Further, during the voyage of the miniature submarine, the CTD measurement interval is 5 minutes, each acquisition time is not less than 60 s, and the sampling rate is 16-24 Hz.

Further, the sampling rate of the ADCP is 1 Hz.

The miniature submarine in the embodiment of the utility model is a long-distance, long-duration and self-driving atmospheric ocean observation platform working under complex sea conditions. The carrier platform is about 9 meters long, 1.95m high, with a full-load displacement of about 6 tons, a speed of 10 knots, a design sailing time of 4 days, and a maximum range of 1500km. In order to reduce the impact of sway on the observation of meteorological and hydrological elements and the impact of wind resistance, only the observation platform and communication equipment of the unmanned vessel are above the water surface, and the other parts are below the water surface, using a semi-submersible navigation method. The unmanned boat is equipped with a satellite positioning device and a satellite communication system. The satellite positioning sampling frequency is 10Hz, and the satellite communication frequency is 1Hz. The cycle of wave motion is generally between three seconds and more than ten seconds. As long as the satellite positioning sampling time is long enough to exceed one or several wave cycles, the impact of the reciprocating motion of waves can be minimized. The ground control station can be controlled by program or remote control, so that the unmanned boat floats on the sea surface in a set way in the designated sea area. By analyzing the position movement information of the unmanned boat within the specified time, the current velocity and direction information can be obtained, and The ocean current observation results can be transmitted to the ground control station in real time.

When working, the fuel tank placed at the bottom of the ballast tank first pumps diesel into the generator at the tail of the ballast tank to generate electricity, and then charges the battery through the charger. Steering can be achieved with the action of the rudder surface. After the semi-submersible self-navigating marine detection equipment carrier platform travels to the predetermined waters, the ship-borne miniature ship-borne meteorological detection rocket system test device is used to launch sounding rockets to complete the predetermined scientific research tasks.

The foregoing is a preferred embodiment of the present utility model, and it should be pointed out that for those of ordinary skill in the art, some improvements and modifications can be made without departing from the principle of the present utility model. Retouching should also be regarded as the scope of protection of the present utility model.

Claims (10)

1. A kind of miniature submarine, it is characterized in that, comprises: submarine hull, wherein said hull comprises the ballast compartment of the bottom of sealing and the buoyancy compartment of the top of sealing, and said ballast compartment is provided with inner hollow The cavity is used to accommodate batteries, fuel tanks, and diesel generators, and is connected to the buoyancy chamber on the top through a sealed line pipeline; the buoyancy chamber on the top is provided with an inner cavity to accommodate electronic equipment, and the electronic equipment passes through The cables arranged in the line duct are connected to the diesel generator and/or the storage battery; The rear part of the submarine is provided with a propeller, a horizontal rudder, and a vertical rudder, the propeller is connected to the battery, and the horizontal rudder and the vertical rudder are connected to the electronic equipment in the buoyancy chamber; A mast extending upwards is provided at the front of the mast, and a weather detection mechanism is provided on the mast, and the weather detection mechanism is connected to the electronic equipment through a cable in a sealed line duct; A rocket launcher extending vertically, the rocket launcher includes a sealed launch chamber, the top of which is provided with an openable airtight door, and the bottom of the sealed launch chamber is fixed in the ballast compartment inside and vertically through the top wall of the ballast tank and the buoyancy tank to protrude from the hull of the submarine; Wherein, the rear part of the submarine is also provided with a sealed casing protruding from the hull, and an antenna is arranged in the casing, and the antenna is connected to the electronic equipment through a cable passing through the sealed line duct. 2. The miniature submarine according to claim 1, characterized in that, the top wall of the buoyancy chamber is provided with an openable and closable sealed hatch. 3. The miniature submarine according to claim 1, wherein a suction and exhaust pipe is also provided in the enclosure, and the suction and exhaust pipe protrudes from the enclosure top from the enclosure. 4. The miniature submarine according to claim 1, wherein ballast is provided at the front and rear of the ballast tank. 5. The micro-submarine according to claim 1, wherein the electronic equipment includes a submarine control system for controlling the work of the micro-submarine, a meteorological data for controlling the meteorological detection mechanism to carry out meteorological detection A processing system, a rocket control system for controlling the operation of the rocket launching device. 6. The miniature submarine according to claim 5, wherein the electronic equipment also includes a telecommunication system, the telecommunication system connects the remote server through the antenna of the casing to send the measurement data to the remote server, and The control instruction sent by the remote server is received to control the operation of the miniature submarine. 7. The miniature submarine according to claim 6, wherein the remote communication system comprises a satellite positioning device and a satellite communication device, wherein the sampling frequency of the satellite positioning device is 10 Hz, and the communication frequency of the satellite communication device is 1 Hz. 8. The micro-submarine according to claim 1, wherein the micro-submarine carries a temperature-depth conductivity sensor CTD, an upper-looking acoustic Doppler profiler ADCP and a lower-looking acoustic Doppler profiler ADCP as Measuring equipment, CTD is installed on the head of the micro-submarine, CTD measures the seawater temperature and conductivity profile, ADCP is a broadband ADCP configured with four-beam oblique orthogonal JANUS, and is equipped with two sets of front and rear ADCPs, one set is an upward-looking ADCP , used to measure the current profile above the vehicle; the other set is downward looking ADCP, which measures the current profile below the vehicle, and also has the function of measuring the speed of the vehicle, that is, it has the function of tracking the bottom and measuring the height of the bottom; The trapezoidal profile measurement is carried out on the set route, including horizontal navigation on the water surface, diving navigation, underwater horizontal navigation, and floating navigation. ADCP is used to measure the current profile and water depth changes during the navigation. 9. The micro-submarine according to claim 8, wherein, during the voyage of the micro-submarine, the measurement time interval of the CTD is 5 minutes, each collection time is not less than 60s, and the sampling rate is 16. ~24Hz. 10. The miniature submarine according to claim 8, wherein the sampling rate of the ADCP is 1 Hz.