CN211798643U - Power floating plate - Google Patents
Power floating plate Download PDFInfo
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- CN211798643U CN211798643U CN202020130859.5U CN202020130859U CN211798643U CN 211798643 U CN211798643 U CN 211798643U CN 202020130859 U CN202020130859 U CN 202020130859U CN 211798643 U CN211798643 U CN 211798643U
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Abstract
The utility model relates to an equipment technical field on water especially relates to a power kickboard. This power floating plate includes the shell, the shell includes: the upper plate is made of a soft material; the support frame is fixed at the bottom of the upper plate; and the lower shell is fixedly connected with the support frame. The upper plate is made of soft materials, so that the touch feeling of the upper plate is better, and the influence on the comfort level of a user due to over-hard materials is avoided; the supporting frame is used as a rigid framework, can support the upper plate, avoids the collapse of the upper plate, and simultaneously forms a containing space between the upper plate and the lower shell for arranging an electric control assembly and a water flow pipeline; through setting up the support frame, can also make things convenient for upper plate and inferior valve to connect.
Description
Technical Field
The utility model relates to an equipment technical field on water especially relates to a power kickboard.
Background
The floating plate is a prop used by swimming people for assisting swimming, floating and diving and other underwater projects. Most of floating plates can only increase buoyancy, and are provided with unpowered propellers, so that the speed of playing and running in water is low, and the functional limitations of the floating plates are large. The power propeller is added to part of the floating plate, the battery supplies power to the propeller to provide driving force, the propeller generally uses a pump or a propeller to generate driving power, so that the floating plate has advancing power, and an operator can rapidly move in water by means of the power of the floating plate.
The shell of present power kickboard adopts the plastic part to support, and the contact surface is the plastic hard surface, and the user touch sensation is not good when using, influences user's comfort level.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a power kickboard can improve the comfort level when the user uses.
To achieve the purpose, the utility model adopts the following technical proposal:
a powered float plate comprising a housing, the housing comprising:
the upper plate is a plate made of soft materials;
the support frame is fixed at the bottom of the upper plate; and
the lower casing, the lower casing with support frame fixed connection.
The support frame is fixedly connected with the upper plate in an inserting mode and/or a bonding mode;
the support frame with the inferior valve passes through joint and/or fastener fixed connection.
The supporting frame is of a thin-wall structure and is attached to the bottom of the upper plate, an installation groove is formed in the bottom of the upper plate, and the supporting frame is installed in the installation groove.
Wherein, the power kickboard still includes:
the water flow pipeline is arranged in the shell, extends along the central axis of the shell and is symmetrically arranged relative to the central axis of the shell;
and the propeller is arranged in the water flow pipeline and is used for driving water flow to be sprayed out after passing through the water flow pipeline.
Wherein the propeller comprises:
a motor; and
the output end of the motor is in transmission connection with the propeller, and the diameter of the motor is smaller than that of the propeller.
The water flow pipeline comprises a water inlet section and a water outlet section, and the area of a water inlet of the water inlet section is not less than the sum of the areas of water outlets of all the water outlet sections.
The water flow pipeline comprises a water inlet section and a water outlet section, and the cross-sectional area of the water inlet section and/or the water outlet section is gradually reduced along the water flow direction.
Wherein, the power kickboard still includes:
a seal box disposed within the housing; and
the electric control assembly is arranged in the sealing box;
the electric control assembly is electrically connected with the thruster.
Wherein, the shell is provided with a water leakage hole.
The inner wall of the shell is provided with a diversion trench, and the diversion trench is used for guiding water in the shell to the water leakage hole.
Wherein, the power kickboard still includes:
at least two power switches arranged on the housing;
the electric control assembly is arranged in the shell;
the electric control assembly is electrically connected with the propeller and the power switches respectively, and when the at least two power switches are triggered, the electric control assembly controls the propeller to start; when the at least two power switches are not triggered, the electric control assembly controls the propeller to stop working.
Has the advantages that: the upper plate is made of soft materials, so that the touch feeling of the upper plate is better, and the influence on the comfort level of a user due to over-hard materials is avoided; the supporting frame is used as a rigid framework, can support the upper plate, avoids the collapse of the upper plate, and simultaneously forms a containing space between the upper plate and the lower shell for arranging an electric control assembly and a water flow pipeline; through setting up the support frame, can also make things convenient for upper plate and inferior valve to connect.
Drawings
Fig. 1 is an exploded view of a power floating plate according to an embodiment of the present invention;
fig. 2 is an exploded view of a sealing box according to an embodiment of the present invention;
fig. 3 is a bottom view of the sealing box according to the first embodiment of the present invention;
fig. 4 is a plan view of the assembled lower shell and supporting frame according to the first embodiment of the present invention;
fig. 5 is a schematic structural diagram of a lower shell according to a first embodiment of the present invention;
fig. 6 is a schematic partial structural view of the assembled upper plate, lower shell and supporting frame according to the first embodiment of the present invention;
fig. 7 is a circuit diagram of a power switch on the left side of a housing according to an embodiment of the present invention;
fig. 8 is a circuit diagram of a power switch on the right side of the housing according to an embodiment of the present invention;
fig. 9 is a schematic structural diagram of a motor according to a second embodiment of the present invention;
fig. 10 is a cross-sectional view of a motor according to a second embodiment of the present invention;
fig. 11 is a schematic structural view of an angle of the heat dissipation rear cover according to the second embodiment of the present invention;
fig. 12 is a schematic structural view of another angle of the heat dissipation rear cover according to the second embodiment of the present invention;
fig. 13 is a cross-sectional view of a propeller according to a fourth embodiment of the present invention.
Wherein:
11. an upper plate; 12. a support frame; 121. a hook; 13. a lower case; 131. a handle; 132. a water leakage hole; 133. a diversion trench; 134. a water jet; 21. a pipeline upper cover; 22. a lower cover of the pipeline;
3. a motor; 31. a motor housing; 32. a stator assembly;
33. a rotor assembly; 331. a rotating shaft; 3311. a helical groove;
34. a heat dissipation rear cover; 341. a rear cover body; 3411. mounting holes; 3412. threading holes; 342. a heat conducting portion; 3421. mounting grooves; 343. a heat dissipating section; 3431. a first heat sink portion; 3432. a second heat sink member; 344. sealing the connection part; 345. a lug; 3451. a fixing hole;
35. a sealing cover; 351. a sealing cover body; 352. a holding portion; 36. an electric wire;
37. a dynamic sealing structure; 381. a first seal structure; 382. a second seal structure; 383. a third seal structure;
4. a sealing box; 41. a box body; 42. a box cover; 43. a seal ring; 44. a packaging layer; 45. a heat dissipating element; 46. a water inlet detection module; 5. a nozzle; 6. a water inlet fence;
7. a propeller; 71. auxiliary blades.
Detailed Description
Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.
In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Wherein the terms "first position" and "second position" are two different positions.
Unless expressly stated or limited otherwise, the terms "mounted," "connected," and "secured" are to be construed broadly and encompass, for example, both fixed and removable connections; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.
Unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may include the first feature being in direct contact with the second feature, or may include the first feature being in direct contact with the second feature but being in contact with the second feature by another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.
The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.
Example one
The embodiment provides a power floating plate which can be used for swimming, floating and diving and other underwater projects. As shown in fig. 1, the power floating plate includes a housing, a water flow conduit disposed in the housing, and a propeller disposed in the water flow conduit. When the power floating plate is used, a user lies prone on the floating plate, the front end of the power floating plate is held by two hands, and water can be driven to be sprayed out to the rear side of the power floating plate by starting the propeller, so that the power floating plate drives the user to advance.
Specifically, the water flow pipeline comprises a water inlet section and a water outlet section which are communicated, and the front end of the water inlet section is communicated with the outside of the shell, so that water flow outside the shell can enter the water flow pipeline; the rear end of the water outlet section is communicated with the outside of the shell, so that water flow is driven by the propeller to be sprayed out of the shell by the water outlet section. The propeller comprises a motor 3 and a propeller 7, wherein an output shaft of the motor 3 is in transmission connection with the propeller 7 to drive the propeller 7 to rotate, so that water flow is driven to be sprayed out from the water outlet section to the rear side of the power floating plate, and the power floating plate is driven to move forwards.
In this embodiment, the front end of shell is provided with into water fence 6, the front end of the section of intaking and the fence 6 intercommunication of intaking, and outside rivers play the safety protection effect in getting into the rivers pipeline behind the fence 6 of intaking, avoid the user to receive the injury of rotating screw 7, can also filter the impurity of aquatic in addition, avoid impurity to block up rivers pipeline or propeller to guarantee the normal use of power kickboard. The rear end of the housing is provided with a water jet 134, and the rear end of the water outlet section is communicated with the water jet 134, so that the water flow pushed by the propeller is sprayed out from the water jet 134.
In the embodiment, the pusher is only provided with one motor 3, so that the weight of the power floating plate can be reduced, and the gravity borne by the power floating plate can be improved on the basis that the buoyancy generated by the power floating plate is the same; the single motor 3 can also reduce the cost of the power floating plate, improve the dismounting efficiency and facilitate the maintenance.
In order to ensure that the power floating plate has enough propelling power, the propeller is arranged in the water inlet section, and can ensure the flow and the flow velocity of water entering the water flow pipeline from the outside of the shell, thereby ensuring higher propelling efficiency, fully utilizing the power of the motor 3 with the same power, ensuring the efficiency optimization of the propeller and ensuring higher propelling efficiency.
When using the power kickboard because of the user, the upper half body lies prone on the power kickboard, can spout the user on one's body when rivers spout backward, not only influences user's use and experiences, but also can increase the resistance that rivers sprayed, influences the gos forward of power kickboard.
In order to solve the above problem, the water flow pipe in this embodiment is provided with two water outlet sections, the water spraying ports 134 are correspondingly provided with two water outlet sections, and one end of the two water outlet sections, which is communicated with the water spraying ports 134, extends in a direction away from the central axis of the housing. Extend to the direction of keeping away from the axis of shell through a water section for rivers in through a water section are by the both sides blowout of power kickboard, and the user can be located between two water sections when using power kickboard, thereby avoids rivers to spout user on one's body, is favorable to improving user's use and experiences.
In this embodiment, the front ends of two play water sections are communicated with the section of intaking after crossing for the rivers pipeline is roughly the Y style of calligraphy, is favorable to simplifying the structure of rivers pipeline.
In other embodiments, the number of the water outlet sections can be more than two, and the specific number can be set according to actual needs.
The propeller is arranged in the water inlet section, so that the two water outlet sections can share one propeller, thereby reducing the number of the propellers and achieving the purposes of reducing cost and weight.
In other embodiments, a propeller 7 may be disposed in each water outlet section, each propeller 7 is connected to the motor 3 in the water inlet section through a transmission assembly, and a plurality of propellers 7 are driven to rotate by a single motor 3.
In order to make the power floating plate more stable when using, the section of intaking can be located the axis of shell, and the axis extends, and two play water section symmetry settings of the axis of shell relatively to make the propeller during operation, rivers are more even in the distribution of rivers pipeline, are favorable to maintaining the stability of power floating plate, avoid the power floating plate incline.
In this embodiment, the water flow pipe includes a pipe upper cover 21 and a pipe lower cover 22 that are fastened to each other, and the pipe upper cover 21 and the pipe lower cover 22 are hermetically connected to each other. The water flow pipeline is formed by buckling the pipeline upper cover 21 and the pipeline lower cover 22, so that the propeller can be conveniently disassembled and assembled in the water inlet section.
Alternatively, the upper pipe cover 21 and the lower pipe cover 22 may be sealed by a sealing member, fixing lugs may be provided at edges of the upper pipe cover 21 and the lower pipe cover 22, the fixing lugs of the upper pipe cover 21 and the lower pipe cover 22 may be fastened by screws, and the sealing member may be provided at an inner side of the fixing lugs, thereby ensuring sealing performance of the water flow pipe.
In other embodiments, the water flow pipeline can also be integrally formed, such as blow molding, and has the advantages of convenient processing and good sealing performance.
Optionally, the water inlet section can be internally provided with a mounting seat, and the propeller can be fastened on the mounting rib through screws to complete the fixation of the propeller.
In order to further increase the flow rate of the water flow provided by the propeller to the two divided water outlet sections, the structure of the water flow pipeline is further improved in the embodiment, so that the propeller adopting the single motor 3 has higher propelling efficiency.
Specifically, in order to facilitate the water flow to enter the water flow pipeline, the cross-sectional area of the water inlet section can be gradually reduced along the water flow direction, so that the opening of the water inlet section is expanded, and the increase of the water flow entering the water flow pipeline is facilitated; after the cross-sectional area of the water inlet section is gradually reduced, the pressure of water flow can be increased, and the flow speed of the sprayed water flow is favorably improved.
Optionally, the cross-sectional area of the water outlet section may gradually decrease along the water flow direction to further increase the pressure of the water flow, which is beneficial to increase the flow rate of the sprayed water flow.
In this embodiment, the cross-sectional area of the section of intaking and the section of play water all reduces along the rivers direction gradually, is favorable to avoiding the rivers boundary layer separation condition, improves rivers flow efficiency.
Optionally, the cross section of the water inlet section is a normal cross section of the water inlet section, and the cross section of the water outlet section is a normal cross section of the water outlet section.
Optionally, the area of the water inlet section is not less than the sum of the areas of the water outlets of the two water outlet sections, so that the flow rate of water entering the water flow pipeline from the water inlet is not less than the flow rate of water sprayed from the water outlets, and the water entering the water flow pipeline can be stably supplied with the water sprayed after being accelerated by the propeller.
In this embodiment, the rear end of play water section still is connected with nozzle 5, and rivers can further improve the velocity of water flow through 5 spouts of nozzle to improve the driving force of rivers to the power kickboard.
Alternatively, nozzle 5 may be rotatably disposed within spout 134. Water flow can form spiral water flow under the action of rotation of the nozzle 5, the flow speed of the water flow can be further improved, and therefore the driving force of the water flow on the power floating plate is improved.
Exemplarily, a plurality of spiral grooves are arranged in the nozzle 5, after water flow in the water outlet section enters the nozzle 5, the water flow flows along the spiral grooves, the nozzle 5 can be pushed to rotate in the water spray port 134, the nozzle 5 does not need to be driven by extra power, and the cost of the power floating plate is favorably reduced.
Illustratively, the power float plate further comprises a rotary driving member connected with the nozzle 5 to drive the nozzle 5 to rotate. The rotary driving part can be a rotary motor, the nozzle 5 is driven to rotate through the rotary motor, and the rotating speed of the nozzle 5 is controllable, so that the flow speed of the sprayed water flow can be better controlled.
Alternatively, the nozzle 5 may be an elastic tube, such as a bellows tube. The corrugated pipe has the characteristic of being bendable, and can be pulled according to the required water flow spraying direction before use so as to adjust the direction of the pipe orifice of the corrugated pipe.
In order to improve the water inlet efficiency, the propeller 7 is positioned on one side of the motor 3 close to the water inlet of the water inlet section, so that water flow can enter the water flow pipeline under the driving of the propeller 7.
The propeller 7 and the motor 3 are both arranged in the water inlet section, the diameter of the motor 3 is smaller than that of the propeller 7, preferably, the diameter of the motor 3 is smaller than or equal to two thirds of the minimum diameter of the water inlet section, or the circular cross-sectional area of the motor 3 is smaller than or equal to one half of the minimum cross-sectional area of the water inlet section, so that a certain gap is formed between the motor 3 and the water inlet section to allow enough water flow to pass through.
In this embodiment, the power floating plate further includes a sealing box 4 and an electric control assembly. The automatically controlled subassembly sets up in seal box 4, and seal box 4 sets up in the shell. The electric control assembly is arranged by arranging the sealing box 4, on one hand, the electric control assembly can be separated from the water flow pipeline, and the electric control assembly is sealed independently, so that the waterproof effect of an electrical element is improved; on the other hand, can reduce the waterproof requirement to the shell, reduce the processing degree of difficulty of shell.
As shown in fig. 2, the sealing case 4 includes a case body 41, a case cover 42, and an encapsulation layer 44. One end of the box body 41 is opened so as to conveniently install the electric control assembly; the electronic control assembly is packaged in the box body 41 through the packaging material, the packaging material forms a packaging layer 44, on one hand, the electronic control assembly can be fixed in the box body 41, and on the other hand, the packaging material wraps the outer side of the electronic control assembly, so that a waterproof effect can be achieved. The cover 42 is hermetically connected to the case body 41 to close the opening of the case body 41 and further prevent water from entering the case body 41.
In this embodiment, the electric control assembly can realize a double-layer sealing effect through the outer packaging layer 44, the box body 41 and the box cover 42, so that the electric control assembly has a better sealing effect.
Optionally, a sealing ring 43 is disposed between the box body 41 and the box cover 42, and the box body 41 and the box cover 42 are fastened and fixed by screws, so that the box body 41 and the box cover 42 are fixed effectively and reliably.
In order to facilitate the packaging of the electronic control assembly, a holding tank is arranged in the box body 41, the electronic control assembly is arranged in the holding tank, and packaging material is filled in the holding tank to submerge the electronic control assembly so as to complete the packaging of the electronic control assembly. Through setting up the holding tank, can realize the location to automatically controlled subassembly before the encapsulation, avoid automatically controlled subassembly to remove at the encapsulation in-process to improve the encapsulation effect.
Optionally, the height of the top end of the receiving groove is smaller than the height of the top end of the box body 41, so as to avoid the excessive packaging material from affecting the installation of the box cover 42 and the box body 41. When the packaging material is about to overflow the accommodating groove, the supply of the packaging material is stopped to avoid the excessive packaging material.
For further guaranteeing the power consumption safety of power floating plate, still be provided with the detection module 46 of intaking of being connected with the control assembly electricity in the seal box 4, the detection module 46 of intaking can detect whether intake in the seal box 4, after detecting that the seal box 4 intakes, sends alarm signal to the control assembly in time cuts off the power supply of power floating plate.
Alternatively, the water inlet detection module 46 may include a water sensor that is turned on after contacting water, thereby determining whether water is entering the sealing box 4. It should be noted that the water sensor is a conventional structure in the art, and the specific structure, the connection circuit with the control component, and the principle thereof are conventional arrangements in the art, and any specific structure, connection circuit with the control component, and principle thereof in the prior art may be adopted in this embodiment.
In this embodiment, automatically controlled subassembly includes control assembly and battery, and control assembly is connected with propeller and battery electricity respectively, and control assembly can control the battery and supply power to the propeller to and control the propeller and open and stop, for power floating plate provides power.
To facilitate the installation of the various components within the housing, as shown in fig. 1, the housing includes snap-fit upper and lower shells 13, with an installation space formed between the upper and lower shells 13 for accommodating the fluid conduits and the seal box 4. Alternatively, the upper case and the lower case 13 may be connected by a snap-fit or a fastener such as a screw.
The electric control assembly generates a large amount of heat in the working process, so as to avoid the influence of the overhigh temperature of the electric control assembly on the working stability of the electric control assembly, as shown in fig. 3, a heat dissipation element 45 is further arranged on the outer side of the box body 41, and the heat dissipation element 45 can dissipate the heat generated by the electric control assembly in the box body 41 in time so as to reduce the temperature of the electric control assembly.
As shown in fig. 3, in this embodiment, the heat dissipation element 45 is a heat dissipation aluminum plate disposed on the outer wall of the box body 41, and the heat conductivity of the heat dissipation aluminum plate is high, so as to accelerate the dissipation of heat. In addition, because of the shell need not sealed, must have the fitting gap between epitheca and the inferior valve 13, the power kickboard is in the use, and inside water can enter into the shell through the fitting gap between epitheca and the inferior valve 13, through water and the contact of heat dissipation aluminum plate, can further improve electric control element's radiating effect.
In other embodiments, the heat dissipation element 45 may also be a heat conductive silica gel layer, which has a high heat conductivity coefficient, and is beneficial to accelerating heat dissipation. The heat dissipation element 45 may also be disposed on the box cover 42, or both the box body 41 and the box cover 42 may be disposed with the heat dissipation element 45.
As shown in fig. 4, in order to discharge the water in the casing after the power floating plate is used, so as to avoid the problems of corrosion or bacteria breeding caused by the residual water in the casing for a long time, a water leakage hole 132 is further formed in the casing, and the water leakage hole 132 is communicated with the cavity inside the casing. When the power floating plate is used, water flow can enter the shell through the water leakage holes 132, so that the contact water quantity with the heat dissipation aluminum plate is increased, and the heat dissipation effect is improved. When the power floating plate is not used, the water in the case can be discharged through the water leakage holes 132.
In this embodiment, the water leakage holes 132 are provided on the lower case 13 so that when the user carries the power buoyant board, the water leakage holes 132 are located on the bottom surface of the power buoyant board, thereby facilitating the discharge of water from the inside of the case.
Further, the inner wall of the shell can also form a diversion groove 133 by arranging a convex rib, and the diversion groove 133 can guide water in the shell to the water leakage hole 132 so that the water in the shell is discharged more thoroughly. Alternatively, the guide grooves 133 may be provided on the inner wall of the upper case, and also on the inner wall of the lower case 13, as long as the water in the case can be guided to flow along the guide grooves 133 into the water leakage holes 132.
As shown in fig. 5, in order to facilitate the user to carry the power floating plate, a handle 131 is further disposed on the housing, and the user can carry the power floating plate by holding the handle 131 with a hand, which is convenient to operate. The user can also adjust the angle of the power float plate by holding the handle 131 to drain the water in the housing.
In this embodiment, the handle 131 and the water leakage hole 132 are disposed at two opposite ends of the housing, so that when the user holds the handle 131 to lift the power floating plate, the handle 131 is located at the higher end of the power floating plate, and the water leakage hole 132 is located at the bottom end of the power floating plate, so as to facilitate water drainage.
Alternatively, the guiding groove 133 may have a stepped structure or a certain slope, and the water leakage hole 132 is communicated with the deeper end of the guiding groove 133, so that the water entering the guiding groove 133 flows downward to the water leakage hole 132.
In order to improve the comfort when the user uses the power floating plate, the upper shell comprises an upper plate 11 and a support frame 12, the upper plate 11 is made of soft materials, the support frame 12 is made of hard materials, the upper plate 11 is arranged at the top of the support frame 12, the support frame 12 is arranged on a lower shell 13, and a water flow pipeline and a seal box 4 are arranged between the support frame 12 and the lower shell 13. The upper plate 11 is made of soft materials, so that the touch feeling of the upper plate 11 is better, and the influence on the comfort level of a user caused by over-hardness of the materials is avoided. The support frame 12 is a rigid frame (e.g., a frame made of one or more materials selected from plastic, carbon fiber, aluminum alloy, etc.), and can support the upper plate 11 to prevent the upper plate 11 from collapsing, and at the same time, a receiving space is formed between the upper plate 11 and the lower shell 13 for disposing structural components including, but not limited to, an electronic control component, a water flow pipeline, etc.
In this embodiment, the upper plate 11 is made of an Ethylene Vinyl acetate copolymer (EVA) material, and the EVA material has the advantages of good flexibility, shock resistance, skid resistance, strong pressure resistance, and the like, and is environmentally friendly and skin friendly, and can bring a very good use experience to a user.
In other embodiments, the upper plate 11 may be replaced by leather, silicone, Polypropylene (PP), polyurethane, or foamed polyethylene (EPE).
Optionally, the upper plate 11 and the support frame 12 can be fixed by bonding and/or clamping, so that the fixing mode is simple and the fixing effect is good; the support frame 12 and the lower shell 13 can be fixed by clamping and/or by fasteners such as screws.
As shown in fig. 6, in this embodiment, the supporting frame 12 is a thin-walled structure, the bottom of the upper plate 11 is disposed in a mounting groove clamped with the supporting frame 12, and the supporting frame 12 is mounted in the mounting groove and fixed. The support frame 12 is a thin-walled structure, has good rigidity to play a supporting role, and simultaneously has smaller weight, which is beneficial to improving the load-carrying capacity of the power floating plate.
Preferably, the thin-walled structure is attached to the bottom of the upper plate 11, so as to improve the supporting effect of the upper plate 11.
Preferably, the middle of the support frame 12 is hollowed out to reduce the weight of the support frame 12, thereby reducing the overall weight and cost of the power floating plate.
The supporting frame 12 and the upper plate 11 can be adhered and fixed by auxiliary glue, so that the fixing effect of the upper plate 11 and the supporting frame 12 is improved. The support frame 12 is provided with a hook 121, and the hook 121 is matched with a clamping hole on the lower shell 13 in a clamping manner, so that the support frame 12 is fixed with the lower shell 13.
In other embodiments, the hook 121 may be disposed on the lower shell 13, and correspondingly, the fastening hole is disposed on the supporting frame 12, so as to fix the supporting frame 12 and the lower shell 13.
In this embodiment, a clamping groove can be further formed in the inner wall of the upper plate 11, and the clamping groove can be used for clamping the water flow pipeline and the sealing box 4, so that the water flow pipeline and the sealing box 4 can be conveniently fixed.
In other embodiments, the upper shell may be made of a hard material, and in order to improve comfort of a user, a protective sleeve made of a soft material may be sleeved outside the upper shell. The protective sheath is connected with the upper shell in a sleeved mode, and the protective sheath is convenient to disassemble and assemble quickly, so that different colors and surface patterns can be replaced according to the preference of a user.
In this embodiment, the power floating plate further comprises a control switch electrically connected with the electric control assembly through a wire, the control switch comprises a power switch and a power switch, the power switch is used for controlling starting and stopping of the propeller, and a user of the power switch controls on and off between the battery and the propeller.
Specifically, the control switch is arranged at the bottom of the shell to avoid misoperation of a user on the touch switch, and the safety performance of the power floating plate is improved.
The inner wall of shell still is provided with walks the line passageway, connects the wire between each electrical components in the shell and can wear to locate in walking the line passageway, can fix the position of wire on the one hand, avoids the wire because of the position is indefinite wearing and tearing, and on the other hand can play waterproof effect to guarantee the power consumption safety of power kickboard.
In this embodiment, the wires penetrating through the routing channel include, but are not limited to, a wire connecting the motor 3 and the electronic control component, a wire connecting the power switch and the electronic control component, a wire connecting the indicator light and the electronic control component, and a wire connecting the power switch and the electronic control component.
In this embodiment, be provided with two power switch on the shell, two power switch all are connected with the control assembly electricity among the automatically controlled subassembly, and control assembly only when two power switch all are triggered, the control impeller starts to further avoid user's maloperation to start the propeller, improve the safety in utilization of power floating plate.
Two power switch set up the left and right sides in the epitheca bottom respectively, and the user lies prone behind on the power kickboard, and the power kickboard is surroundd to the arm for both hands are located near power switch, in order to conveniently trigger power switch.
In this embodiment, the control component may include a microcontrol Unit (MCU), which is also called a single chip microcomputer. Fig. 7 and 8 are circuit diagrams of the left power switch and the right power switch, respectively, wherein KEYML and KEYMR are connected to a common IO interface of the micro control unit, respectively, for detecting states of the left and right power switches. When the user does not press the power switch, the corresponding IO interface is at a high level (3.3V); when the user presses the power switch, the corresponding IO interface is at a low level (0V). And the micro-control unit judges the triggering condition of the power switch by acquiring the low level or the high level at the IO interface.
For making the user after starting the propeller, have enough time to adjust the gesture in order to stably lie prone on the power kickboard, press the back simultaneously when controlling power switch, control assembly can control the propeller and delay behind the appointed time and start, for the user provides sufficient preparation time. The specific extended designated time can be set according to actual needs.
In order to facilitate other operations of a user in the moving process of the power floating plate, when one of the two power switches is disconnected and the other power switch is still in a triggered state, the pusher continues to work to ensure that the power floating plate continues to move forwards, one arm of the user triggers the power switch, and the other arm can perform other operations, so that the control of the power floating plate is more flexible. When the two power switches are disconnected, the control assembly controls the propeller to stop running so as to avoid the power floating plate from being separated from a user.
In some embodiments, the control assembly controls the propeller to start when both power switches are pressed simultaneously and to stop when the user releases either power switch to prevent the power float plate from disengaging from the user.
In some other embodiments, the control assembly controls the propeller to activate when the user depresses either of the two power switches; when both power switches are not pressed, the control component controls the propeller to stop running.
The control process of the power floating plate in this embodiment is as follows:
when the power floating plate is not used, the power floating plate is not electrified. When a user presses the power switch, the power floating plate is powered on and maintains the power-on state, and the indicator lamp is lightened to indicate the current battery capacity and state information to wait for receiving an instruction. When the power switches on the left side and the right side are pressed down, level signals of the IO interface are sent to the micro control unit, and the micro control unit controls the propeller to operate at the maximum power after receiving the signals. When the power floating plate is not placed in water, the motor 3 is in an idle state, and at the moment, the power floating plate runs at the maximum idle speed. During the operation of the power floating plate, when any power switch is loosened, the propeller cannot stop operating, and only after the two power switches are all loosened, the propeller cannot stop operating.
After the power switch is pressed for a long time (for example, the power switch is pressed for 3S), the power floating plate is turned off. The power floating plate is not electrified after shutdown, and static power consumption is reduced. The battery consumes no power, and the service life of the battery is prolonged.
When the power floating plate is connected with the charger, the charger interface triggers the power floating plate to start, the micro-control unit detects that the charger is in a connection state, the indicator light indicates charging, the charging control MOS tube is turned on, and the power floating plate starts charging. And when the battery is fully charged, the micro control unit closes the charging control MOS and stops charging.
Example two
The existing motor adopts an open outer rotor structure for heat dissipation and motor volume consideration, and the open outer rotor motor has the advantages of large torque, small volume and good heat dissipation. But this structure uses under the water environment that has the impurity and extremely easily blocks to die, simultaneously in the use, because magnet direct and water contact cause the magnet to corrode very easily, and then influence product life-span.
Therefore, the embodiment provides a power floating plate, which improves the structure of the motor 3 in the propeller on the basis of the first embodiment, so that the structure can meet the heat dissipation requirement, can avoid contact with water and impurities, and prolongs the service life of the motor. As shown in fig. 9 to 12, the motor 3 includes a motor housing 31, a stator assembly 32, a rotor assembly 33, and a heat dissipation rear cover 34, the heat dissipation rear cover 34 is connected to the motor housing 31 to form a sealed space, the stator assembly 32 and the rotor assembly 33 are installed in the sealed space, the stator assembly 32 is connected to the motor housing 31, and the rotor assembly 33 is inserted into the stator assembly 32. Motor 3 forms the confined space who holds stator module 32 and rotor subassembly 33 through lid 34 and motor casing 31 behind the heat dissipation, plays sealed waterproof effect, avoids subassembly and water direct contact in the motor 3, and then avoids motor 3 to be died by the impurity card, has also weakened the corruption of water to subassembly in the motor 3.
Optionally, the end of the motor casing 31 away from the heat dissipation rear cover 34 is tapered to reduce resistance.
Optionally, the heat dissipation rear cover 34 is made of an aluminum material, so that the heat transfer effect is good, and the heat dissipation effect is good. The heat dissipating rear cover 34 may be made of other materials with good thermal conductivity. Optionally, the heat dissipation rear cover 34 is integrally formed, so as to ensure the sealing performance of the heat dissipation rear cover 34. In this embodiment, the heat dissipation rear cover 34 is made of aluminum alloy, which not only has a good heat dissipation effect, but also meets the strength requirement.
As shown in fig. 11 and 12, the heat dissipation rear cover 34 includes a rear cover body 341 and a heat conduction portion 342 connected to one side of the rear cover body 341, and the rear cover body 341 is hermetically connected to the motor casing 31, so that the connection between the heat dissipation rear cover 34 and the motor casing 31 is realized. The heat conduction part 342 is arranged between the stator assembly 32 and the rotor assembly 33 and is abutted against the inner wall of the stator assembly 32, so that heat generated by the motor 3 can be quickly led out to the external water through the heat conduction part 342, and the reliability of the motor 3 is improved. Optionally, the heat conducting portion 342 is in interference fit with the stator assembly 32, so that the connection manner is simple and the heat conducting effect is good. The heat conducting portion 342 may also be connected by a connecting member, which is not specifically limited herein, as long as the heat conducting portion 342 abuts against the inner wall of the stator assembly 32, so as to dissipate the heat generated by the stator assembly 32.
Optionally, the heat conducting portion 342 is of a sleeve structure, so that the heat conducting portion 342 and the stator assembly 32 can be in circumferential contact, the contact area is large, and the heat conducting effect is good.
In order to quickly dissipate the heat conducted by the heat conducting portion 342 into water, the heat dissipating rear cover 34 further includes a heat dissipating portion 343, and the heat dissipating portion 343 is disposed on a side of the rear cover body 341 facing away from the inside of the motor case 31. The heat dissipation portion 343 increases the contact area of the heat dissipation rear cover 34 with water, and can further increase the speed of guiding heat generated by the motor 3 into the external water.
Optionally, the heat dissipation portion 343 includes a first heat dissipation portion 3431 and a second heat dissipation portion 3432 coaxially disposed, the second heat dissipation portion 3432 is sleeved outside the first heat dissipation portion 3431, and the second heat dissipation portion 3432 is connected to the circumferential direction of the rear cover body 341. The first and second heat sink members 3431 and 3432 each extend in the longitudinal direction of the motor case 31, so that heat conducted from the heat conduction member 342 can be uniformly conducted to the outside of the motor case 31 through the first and second heat sink members 3431 and 3432 in the longitudinal direction of the motor case 31.
Alternatively, the first heat sink part 3431 is a sleeve structure, and the radial cross section of the first heat sink part 3431 is an annular structure. The rear cover body 341 is provided with a mounting hole 3411, and the mounting hole 3411 is respectively communicated with the heat conducting part 342 and the first heat dissipating part 3431, so that the internal components of the motor 3 can be conveniently mounted, and the heat dissipating effect is good. The mounting hole 3411 is provided coaxially with the heat conduction portion 342 and the first heat sink portion 3431, and thus has a simple structure, facilitating the mounting of components in the motor 3.
A plurality of lugs 345 are circumferentially arranged on the second heat sink part 3432, fixing holes 451 are formed in the lugs 345, and the rear cover body 341 is connected to the motor case 31 through fixing members passing through the fixing holes 451. The heat dissipation rear cover 34 is connected with the motor shell 31 through the arrangement of the lug 345, so that the structure is simple; in addition, the lug 345 is located outside the motor casing 31, which can also play a role in heat dissipation, further improving the heat dissipation efficiency of the motor 3. Alternatively, the fixing member may be a bolt.
The heat conduction portion 342 has an inner diameter smaller than that of the mounting hole 3411, and the mounting hole 3411 has a diameter smaller than that of the first heat sink member 3431, so that the assembly of the motor 3 is facilitated. The inner wall of the mounting hole 3411 of the rear cap body 341 and the end of the first heat sink part 3431 at the end connected to the rear cap body 341 form a stepped structure, facilitating the mounting of the first bearing of the rotor assembly 33. An inner wall of one end of the heat conductive portion 342, which is far away from the first heat sink portion 3431, is provided with a mounting groove 3421, and a second bearing is mounted in the mounting groove 3421, thereby achieving rotation of the rotation shaft 331. The first bearing and the second bearing are respectively sleeved on the rotating shaft 331 so that the rotating shaft 331 is rotatably arranged.
Alternatively, heat dissipation ribs may be disposed between the first heat dissipation portion 3431 and the second heat dissipation portion 3432, and the heat dissipation ribs are connected to the rear cover body 341 to further accelerate heat dissipation, and the specific shape of the heat dissipation ribs is not limited herein.
As shown in fig. 9 and 10, the motor 3 further includes a seal cap 35, one end of the seal cap 35 extends into the first heat sink member 3431, and the other end of the seal cap 35 is in sealing contact with the first heat sink member 3431. The installation of the subassembly in the motor 3 is convenient for realize in the setting of mounting hole 3411, and the setting of sealed lid 35 can seal the pivot 331 of motor 3, avoids in water enters into motor 3 by lid 34 after the heat dissipation, influences motor 3's performance.
Alternatively, the other end of the sealing cover 35 and the first heat sink member 3431 are sealed by a first sealing structure 381, and the first sealing structure 381 is a static seal.
Specifically, as shown in fig. 10, the seal cover 35 includes a seal cover body 351 and a holding portion 352 located at one end of the seal cover body 351, an outer diameter of the seal cover body 351 is smaller than or equal to an inner diameter of the first heat dissipation portion 3431, a circumferential dimension of the holding portion 352 is larger than the outer diameter of the seal cover body 351, the seal cover body 351 extends into the first heat dissipation portion 3431, and the holding portion 352 and one end of the first heat dissipation portion 3431, which is not connected to the rear cover body 341, are sealingly held. The abutting portion 352 is connected to one end of the first heat dissipating portion 3431, which is not connected to the rear cover body 341, in a sealing manner by a first sealing structure 381.
As shown in fig. 11 and 12, a sealing connection portion 344 is further disposed on the rear cover body 341 in the circumferential direction of the side where the heat conduction portion 342 is disposed, and the sealing connection portion 344 is inserted into the motor casing 31 and is connected to the motor casing 31 in a sealing manner. The sealing connection part 344 is capable of forming a sealing connection with the motor casing 31, so that water is prevented from entering a gap between the motor casing 31 and the heat dissipation rear cover 34, and the practicability of the motor 3 is prevented from being affected.
Optionally, the circumferential direction of the sealing connection portion 344 is provided with a groove structure, a second sealing structure 382 is arranged between the groove structure and the inside of the motor casing 31, the arrangement of the groove structure facilitates the accommodation of the second sealing structure 382, and water can be prevented from entering from a gap between the motor casing 31 and the heat dissipation rear cover 34 through the second sealing structure 382, so that the practicability of the motor 3 is affected. The second seal structure 382 is a static seal.
The output end of the rotating shaft 331 of the rotor assembly 33 penetrates out of the motor casing 31, and the matching position of the output end and the motor casing 31 is sealed through a dynamic sealing structure 37. The output end of the rotating shaft 331 penetrates out of the motor casing 31, and the matching position of the rotating shaft 331 and the motor casing 31 is sealed through the dynamic sealing structure 37, so that the sealing effect can be achieved on the premise that the relative rotation between the stator assembly 32 and the rotor assembly 33 is achieved.
Alternatively, the dynamic seal structure 37 uses two oil seals, and the dynamic seal structure 37 may also use other seals such as a flooding plug seal, a stett seal, and the like.
Optionally, a plurality of threading holes 3412 are formed in the rear cover body 341, the electric wires 36 connected to the stator assembly 32 are inserted into the threading holes 3412, and the electric wires 36 are hermetically sealed with the inner wall of the threading holes 3412. The electric wire 36 that is connected with stator module 32 is convenient for wear out in the setting of threading hole 3412, through sealed setting between the inner wall of electric wire 36 and threading hole 3412, can play sealed effect, avoids inside water enters into motor 3 by the clearance between electric wire 36 and the threading hole 3412, influences motor 3's performance.
Optionally, the wire 36 is sealed with the inner wall of the threading hole 3412 by a third sealing structure 383, and the third sealing structure 383 is a static seal. Alternatively, the third sealing structure 383 may be a sealing ring, or may be a potting sealing manner.
The first sealing structure 381, the second sealing structure 382 and the third sealing structure 383 can adopt structures such as an O-shaped ring, a gasket, a star-shaped ring and the like as long as static sealing can be realized.
The motor 3 realizes the sealing of the motor 3 through the dynamic sealing structure 37, the first sealing structure 381, the second sealing structure 382 and the third sealing structure 383, and effectively avoids the phenomena of loose sealing and water leakage of the motor 3.
Optionally, a sealant is filled among the first heat dissipation part 3431, the second heat dissipation part 3432, and the rear cover body 341, so as to further improve the sealing effect.
This motor 3 forms the confined space who holds stator module 32 and rotor subassembly 33 through lid 34 and motor casing 31 behind the heat dissipation, play waterproof effect, heat conduction portion 342 sets up between stator module 32 and rotor subassembly 33, and with stator module 32 inner wall looks butt for the heat that motor 3 produced can derive heat dissipation portion 343 through heat conduction portion 342 fast, conduct external aquatic through heat dissipation portion 343, the reliability of motor 3 has been improved.
EXAMPLE III
The present embodiment provides a power floating plate, which is different from the second embodiment in that the structure of the heat conducting portion 342 of the heat dissipation rear cover 34 of the motor 3 is different from the structure of the heat conducting portion 342 in the second embodiment, the structure of the heat conducting portion 342 in the second embodiment is an integrated sleeve structure, and the heat conducting portion 342 in the present embodiment may be an arc structure, and the arc structure is in heat conducting contact with the stator assembly 32 to play a role in heat conduction.
Alternatively, the heat conduction portion 342 may include one arc-shaped structure, and may further include a plurality of arc-shaped structures, and when the heat conduction portion 342 includes a plurality of arc-shaped structures, the plurality of arc-shaped structures are spaced apart from each other to form a cylindrical structure. Of course, the heat conducting portion 342 may have other shapes as long as the heat of the stator assembly 32 can be conducted out, so as to achieve good heat dissipation.
In some embodiments, the space between the thermally conductive portion 342 and the stator assembly 32 may be filled with a thermally conductive but electrically non-conductive material to provide thermal conductivity. Optionally, the heat-conducting but non-electrically-conducting material may be a heat-conducting sealant, which not only has a heat-conducting effect, but also is waterproof, thereby being beneficial to further improving the waterproof performance of the motor 3.
Example four
In this embodiment, a power floating plate is further provided, as shown in fig. 13, the motor 3 in the second embodiment or the third embodiment is adopted in the propeller, and the rotating shaft 331 of the motor 3 is provided with the propeller 7. This underwater propulsor passes through above-mentioned motor 3, can realize good heat dispersion, prolongs underwater propulsor's life.
Because the sealing between the rotating shaft and the rotor of the existing motor needs to use dynamic sealing, the oil seal can generate heat in the high-speed rotating process of the motor, even if the oil seal is in contact with water, the heat dissipation is not good, the service life of the oil seal can be influenced by long-time use, and the sealing performance is reduced. Because, in order to solve the problem of dynamic seal heat dissipation, a gap is arranged between the dynamic seal structure 37 of the motor 3 and the propeller 7, so that the contact area of the rotating shaft 331 of the motor 3 and water is increased, the dynamic seal structure 37 and the rotating shaft 331 are convenient to wash by water flow, and the heat dissipation efficiency is improved. The clearance between the dynamic sealing structure 37 of the motor 3 and the propeller 7 is large, and the heat dissipation efficiency can be improved.
Optionally, an auxiliary blade 71 is disposed on an inner wall of the motor casing 31 of the propeller 7 near one end of the dynamic seal structure 37, and the auxiliary blade 71 enhances the liquid flow in the cavity inside the propeller 7 when the motor 3 rotates, so as to help dissipate heat between the dynamic seal structure 37 and the rotating shaft 331 of the motor 3.
Alternatively, the diameter of the end of the rotating shaft 331 of the motor 3, which protrudes out of the motor housing 31 of the motor 3, is smaller than the diameter of the body of the rotating shaft 331 of the motor 3, which can reduce the resistance of the underwater propeller.
Optionally, a spiral groove 3311 is disposed at an end of the rotating shaft 331 of the motor 3, which extends out of the motor housing 31 of the motor 3, so as to increase a heat dissipation area of the rotating shaft 331, which is beneficial to heat dissipation of the oil seal.
The above description is only for the preferred embodiment of the present invention, and for those skilled in the art, there are variations on the detailed description and the application scope according to the idea of the present invention, and the content of the description should not be construed as a limitation to the present invention.
Claims (11)
1. A powered float plate comprising a housing, wherein the housing comprises:
the upper plate (11), the said upper plate (11) is the board made of soft material;
the support frame (12), the said support frame (12) is fixed to the bottom of the said upper plate (11); and
the lower shell (13), lower shell (13) with support frame (12) fixed connection.
2. A power float plate according to claim 1, characterised in that the support frame (12) is snap-fitted and/or adhesively secured to the upper plate (11);
the support frame (12) and the lower shell (13) are fixedly connected through clamping and/or fasteners.
3. The power floating plate of claim 1, wherein the support frame (12) is of a thin-wall structure and is arranged to be attached to the bottom of the upper plate (11), the bottom of the upper plate (11) is provided with a mounting groove, and the support frame (12) is mounted in the mounting groove.
4. The power flotation plate of any one of claims 1-3, further comprising:
the water flow pipeline is arranged in the shell, extends along the central axis of the shell and is symmetrically arranged relative to the central axis of the shell;
and the propeller is arranged in the water flow pipeline and is used for driving water flow to be sprayed out after passing through the water flow pipeline.
5. The power float of claim 4, wherein the propeller comprises:
a motor (3); and
the output end of the motor (3) is in transmission connection with the propeller (7), and the diameter of the motor (3) is smaller than that of the propeller (7).
6. The dynamic floating plate of claim 4, wherein the water flow pipeline comprises a water inlet section and a water outlet section, and the area of the water inlet section is not less than the sum of the areas of the water outlets of all the water outlet sections.
7. The dynamic floating plate according to claim 4, wherein the water flow conduit comprises a water inlet section and a water outlet section, and the cross-sectional area of the water inlet section and/or the water outlet section is gradually reduced along the water flow direction.
8. The power buoyant panel of any one of claims 1-3 wherein the power buoyant panel further comprises:
a sealing box (4) disposed within the housing; and
the electric control assembly is arranged in the sealing box (4);
the electric control assembly is electrically connected with the thruster.
9. A powered flotation plate according to any of claims 1-3, characterized in that the casing is provided with water leakage holes (132).
10. The power flotation plate as claimed in claim 9, wherein the inner wall of the housing is provided with guide grooves (133), and the guide grooves (133) are used for guiding the water in the housing to the water leakage holes (132).
11. The power flotation plate of any one of claims 1-3, further comprising:
at least two power switches arranged on the housing;
the electric control assembly is arranged in the shell;
the electric control assembly is electrically connected with the propeller and the power switches respectively, and when the at least two power switches are triggered, the electric control assembly controls the propeller to start; when the at least two power switches are not triggered, the electric control assembly controls the propeller to stop working.
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Cited By (1)
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CN112619074A (en) * | 2020-12-16 | 2021-04-09 | 张愉 | Lifesaving equipment |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN112619074A (en) * | 2020-12-16 | 2021-04-09 | 张愉 | Lifesaving equipment |
CN112619074B (en) * | 2020-12-16 | 2021-11-26 | 山东蓝城智能环境科技有限公司 | Lifesaving equipment |
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