阅读说明：本技术 一种尾翼可调式拟态高防海底沉积物温度探测器 (Tail-adjustable mimicry high-prevention submarine sediment temperature detector ) 是由 李恒杰 于 2019-10-21 设计创作，主要内容包括：本发明提供一种尾翼可调式拟态高防海底沉积物温度探测器,其结构包括拟态高防探测装置、软框、重力砂条、可调节尾翼、折叠背护板、接收机构、中接板,拟态高防探测装置通过嵌入的方式安装在软框内部,重力砂条固定安装在软框底部,可调节尾翼设于中接板顶端,接收机构通过嵌入的方式安装在中接板正端面,本发明在未知海域中进行探测时,通过纤维定型机构的形变动力源释放,能够令展定机构卷曲形成筒装探测结构,即使被撕咬,在拟态防护探测机构反击的同时具有较强韧性的软框能够保护主体不产生形变,即使遭到破坏难以完成回收,也能够顺利抵达海床,并在内部电源的持续供给下能够持续性的完成有效数据的采集。(The invention provides a tail-adjustable mimic high-protection submarine sediment temperature detector which structurally comprises a mimic high-protection detection device, a soft frame, a gravity sand strip, an adjustable tail, a folding back protection plate, a receiving mechanism and a middle connection plate, wherein the mimic high-protection detection device is installed inside the soft frame in an embedded mode, the gravity sand strip is fixedly installed at the bottom of the soft frame, the adjustable tail wing is arranged at the top end of the intermediate connection plate, and the receiving mechanism is arranged on the positive end surface of the intermediate connection plate in an embedded mode, the fiber shaping mechanism can be curled to form a cylinder-packed detection structure by releasing the deformation power source of the fiber shaping mechanism, even if the body is bitten, the soft frame with stronger toughness can protect the body from deformation while the mimicry protection detection mechanism counterattacks, even if the damage is caused and the recovery is difficult to complete, the seabed can be reached smoothly, and effective data can be continuously acquired under the continuous supply of an internal power supply.)

1. The utility model provides a submarine sediment temperature detector is prevented to mimicry height with adjustable fin, its structure includes mimicry height and prevents detection device (1), soft frame (2), gravity sand bar (3), adjustable fin (4), folding back of the body backplate (5), receiving mechanism (6), fishplate bar (7), its characterized in that:

the mimicry high-defense detection device (1) is installed inside the soft frame (2) in an embedding mode, the gravity sand strip (3) is fixedly installed at the bottom of the soft frame (2), the adjustable tail wing (4) is arranged at the top end of the middle connection plate (7), the receiving mechanism (6) is installed on the positive end face of the middle connection plate (7) in an embedding mode, and the folding back protection plate (5) is movably connected with the middle connection plate (7);

the mimicry high-protection detection device (1) comprises a separation row interface (q1), a mimicry protection detection mechanism (q2), a forward-connected waterproof guard sheet (q3), a sub-belt (q4), a middle-connected ridge strip (q5) and an unfolding and fixing mechanism (q6), wherein the unfolding and fixing mechanism (q6) is arranged at the bottom of the separation row interface (q1), the mimicry protection detection mechanism (q2) is movably mounted on the forward-connected waterproof guard sheet (q3), the sub-belt (q4) is fixedly mounted at the left side and the right side of the middle-connected ridge strip (q5) respectively, and the forward-connected waterproof guard sheet (q3) is fixedly connected with a soft frame (2).

2. The tail adjustable mimicry high protection seafloor sediment temperature detector of claim 1, wherein: adjustable fin (4) are including rotor seat (41), side and are drawn spacing (42), pivot (43), stick up area (44), soft area cover (45), buoyancy fin (46), install inside rotor seat (41) through the mode of embedding buoyancy fin (46), side is drawn spacing (42) and is installed inside soft area cover (45) through the mode of embedding, stick up area (44) and pivot (43) fixed connection together.

3. The tail adjustable mimicry high protection seafloor sediment temperature detector of claim 1, wherein: mimicry protection detection mechanism (q2) includes mimicry scale (q21), interior sheath (q22), waterproof bottom cover (q23), connecting band (q24), detecting head (q25), mimicry scale (q21) and connecting band (q24) fixed connection together, inside waterproof bottom cover (q23) was installed through the mode of embedding in detecting head (q25), interior protection chamber (q22) and mimicry scale (q21) structure as an organic whole.

4. The tail adjustable mimicry high protection seafloor sediment temperature detector of claim 1, wherein: exhibition is decided mechanism (q6) and is including crisscross opening (q61), fibre design mechanism (q62), stable spout (q63), flexible exhibition cover (q64), flexible exhibition cover (q64) internal surface tail end position is fixed and is equipped with stable spout (q63), fibre design mechanism (q62) are installed inside flexible exhibition cover (q64) through the mode of embedding, crisscross opening (q61) and crisscross opening (q61) are the integral structure.

5. The tail adjustable mimicry high protection seafloor sediment temperature detector as claimed in claim 4, wherein: the fiber shaping mechanism (q62) comprises a fiber layer (q621), a soft spacer bush (q622), a lock catch ring (q623) and an inner curved strip (q624), wherein the inner curved strip (q624) is installed inside the soft spacer bush (q622) in an embedding mode, the soft spacer bush (q622) is arranged in the middle of the fiber layer (q621), and the lock catch ring (q623) is fixedly connected with the inner curved strip (q 624).

6. The tail adjustable mimicry high protection seafloor sediment temperature detector of claim 1, wherein: the receiving mechanism (6) comprises a connecting rod (aa1), a storage battery (aa2) and a sealing piece (aa3), the connecting rod (aa1) is welded with the storage battery (aa2), and the storage battery (aa2) is arranged on the back of the sealing piece (aa 3).

Technical Field

The invention belongs to the field of temperature instruments and meters, and particularly relates to an empennage-adjustable mimicry high-protection submarine sediment temperature detector.

Background

In the marine exploration and scientific research work, when an unknown sea area is explored, instruments are mostly adopted for early-stage data acquisition for safety consideration, so that a basic data parameter model is established, when seabed sediment is explored, temperature detecting instruments are mostly used, needle-shaped detectors belong to common instruments, can freely adjust the angle direction, and penetrate into the seabed sediment when falling.

Based on the above description, the inventor finds that the existing tail-adjustable mimicry high-protection submarine sediment temperature detector mainly has the following defects, such as:

since large-volume marine organisms exist in unknown sea areas and sometimes the sea bed is deep, the probe is easy to attract the attention of the marine organisms in the process of sinking, the detection needle of the needle-shaped probe is fragile, the probe is extremely easy to damage in the case of sweeping or collision and biting, and the probe can impact on a sea bed reef when being inserted into the sea bed, so that the probe is easy to break, and effective data acquisition is difficult.

Disclosure of Invention

In order to solve the technical problems, the invention provides a tail-adjustable mimicry submarine sediment temperature detector, which aims to solve the problems that in the prior art, due to the fact that large-volume marine organisms exist in unknown sea areas and sometimes under the condition that the sea bed is deep, the detector is easy to attract the attention of the marine organisms in the sea in the sinking process, a detection needle of a needle-shaped detector is fragile, the detector is extremely easy to damage due to sweeping or collision and biting, and when the needle-shaped detector is inserted into the sea bed, the needle-shaped detector can impact on a seabed reef to easily break the detection head, so that effective data are difficult to acquire.

Aiming at the defects of the prior art, the invention discloses a purpose and an effect of a tail-adjustable mimicry high-protection submarine sediment temperature detector, which are achieved by the following specific technical means: the utility model provides a submarine sediment temperature detector is prevented to mimicry height with adjustable fin, its structure includes mimicry height and prevents detection device, soft frame, gravity sand, adjustable fin, folding back of the body backplate, receiving mechanism, fishplate bar, mimicry height is prevented that detection device installs inside soft frame through the mode of embedding, gravity sand fixed mounting is in soft frame bottom, fishplate bar top is located to adjustable fin, receiving mechanism installs at fishplate bar positive terminal surface through the mode of embedding, folding back of the body backplate is in the same place with fishplate bar swing joint.

The mimicry high-protection detection device comprises a separation row interface, a mimicry protection detection mechanism, a forward connection waterproof protection sheet, sub-belts, a middle ridge strip and a spreading mechanism, wherein the spreading mechanism is arranged at the bottom of the separation row interface, the mimicry protection detection mechanism is movably arranged on the forward connection waterproof protection sheet, the sub-belts are respectively and fixedly arranged at the left side and the right side of the middle ridge strip, and the forward connection waterproof protection sheet is fixedly connected with a soft frame.

As preferred, adjustable fin includes rotor seat, side and leads spacing, pivot, sticks up area, soft area cover, buoyancy fin, the buoyancy fin is installed inside the rotor seat through the mode of embedding, the side is led spacing and is installed inside soft area cover through the mode of embedding, stick up area and pivot fixed connection together, the side is led spacing and can be released the pivot when the side direction is pulled, and then sticks up the area and can be drawn it and carry out the rotating, and at the rotor seat that loses the binding power, through the linkage rotation, can make the buoyancy fin towards the top to under the influence of aquatic suspending power, the buoyancy fin can float roll-off rotor seat, forms the operating condition who expandes completely.

Preferably, the mimicry protection detection mechanism comprises a mimicry squama, an inner protection cavity, a waterproof bottom sleeve, a connecting belt and a detection head, wherein the mimicry squama is fixedly connected with the connecting belt, the detection head is installed in the waterproof bottom sleeve in an embedded mode, the inner protection cavity and the mimicry squama are of an integrated structure, the mimicry squama can be unfolded and tilted after the detector enters water, the outer ring part of the mimicry squama is made of stainless steel materials and has high hardness, and if the detector is attacked by fishes in water, the detector can be passively impacted and attacked by the high-hardness mimicry squama of the outer ring part so as to be repelled, and the detector can be effectively protected.

As preferred, exhibition establishment of institution is including crisscross opening, fibre design mechanism, stable spout, flexible exhibition nipple internal surface tail end rigidity is equipped with stable spout, fibre design mechanism installs inside flexible exhibition nipple through the mode of embedding, crisscross opening and crisscross opening structure as an organic whole, stable spout can be after retrieving the detector, resume earlier slice with it in needs, need expand the back with it by force, it is spacing with it through two stable spouts, can accomplish the setting after it is drained moisture.

Preferably, the fiber shaping mechanism comprises a fiber layer, a soft spacer bush, a lock catch ring and an inner curved strip, the inner curved strip is installed inside the soft spacer bush in an embedded mode, the soft spacer bush is arranged in the middle of the fiber layer, and the lock catch ring is fixedly connected with the inner curved strip.

Preferably, the receiving mechanism comprises a connecting rod, a storage battery and a sealing sheet, the connecting rod is welded with the storage battery, and the storage battery is arranged on the back of the sealing sheet.

Compared with the prior art, the invention has the following advantagesAdvantageous effects：

When the dynamic simulation protection detection mechanism is used for detecting in an unknown sea area, the dynamic simulation protection detection mechanism can expand and deform by absorbing seawater when placed into water, can be curled to form a cylindrical detection structure by releasing a deformation power source of the fiber shaping mechanism, can expand and simultaneously adjust the extension of an empennage, can realize passive counterattack even if being disturbed by marine organisms in the sinking process, can protect a main body from deformation by the flexible frame with high toughness while being counterattack by the dynamic simulation protection detection mechanism even if being bitten, can smoothly reach the sea bed even if being damaged and difficult to recover, and can continuously finish effective data acquisition under the continuous supply of an internal power supply.

Drawings

FIG. 1 is a schematic front structural view of a simulated high-protection submarine sediment temperature detector with an adjustable tail wing.

FIG. 2 is a schematic diagram of the back structure of a simulated high-protection submarine sediment temperature detector with an adjustable tail wing.

FIG. 3 is a schematic view of an elevational section structure of a mimic high-protection detection device A of the fin-adjustable mimic high-protection submarine sediment temperature detector of the invention.

Fig. 4 is a detailed internal structure diagram of the adjustable tail wing.

FIG. 5 is a schematic diagram of the internal structure of the mimicry protection detection mechanism.

Fig. 6 is a detailed structural diagram of the inside of the setting mechanism.

Fig. 7 is a schematic diagram of the internal structure of the fiber shaping mechanism.

Fig. 8 is a schematic diagram showing the internal structure of the receiving mechanism in detail.

In the figure: the dynamic high-protection detection device comprises a dynamic high-protection detection device-1, a soft frame-2, a gravity sand strip-3, an adjustable empennage-4, a folding back protection plate-5, a receiving mechanism-6, a middle connection plate-7, a separation row interface-q 1, a dynamic protection detection mechanism-q 2, a positive connection waterproof protection sheet-q 3, a sub-belt-q 4, a middle ridge dividing strip-q 5, an expansion mechanism-q 6, a rotor wing seat-41, a side traction limiting strip-42, a rotating shaft-43, a warping belt-44, a soft belt sleeve-45, a buoyancy empennage-46, a dynamic squama-q 21, an inner cavity-q 22, a waterproof bottom sleeve-q 23, a connection belt-q 24, a probe head-q 25, a through opening staggered-q 61, a fiber shaping mechanism-q 62, a stable chute-q 63, a flexible expansion sleeve-q 64, a fiber layer-q 621, A soft spacer-q 622, a lock catch ring-q 623, an inner curved strip-q 624, a connecting rod-aa 1, a storage battery-aa 2 and a sealing piece-aa 3.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.