CN219115131U

CN219115131U - Decoration with simulation object

Info

Publication number: CN219115131U
Application number: CN202221285484.5U
Authority: CN
Inventors: 班尉翔
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-05-25
Filing date: 2022-05-25
Publication date: 2023-06-02
Anticipated expiration: 2032-05-25

Abstract

The utility model discloses a decoration with a simulation object, which comprises the simulation object (100) with wings (110) and a lifting mechanism (300) arranged in a shell (200), wherein the simulation object (100) and the lifting mechanism (300) are connected through a supporting rod (400) and synchronously move, two guide racks (210) are vertically arranged on the inner wall of the shell (200), a motor (310) and a lifting gear (320) are arranged in the lifting mechanism (300), a gear area (321) matched with the guide racks (210) is arranged on the circumferential curved surface of the lifting gear (320), and the motor (310) drives the lifting mechanism (300) to repeatedly lift and move in the shell (200) along the space between the two guide racks (210). The lifting mechanism is lifted in the shell as a whole, and the slender space in the shell is fully utilized, so that the simulation object can be lifted greatly, and the product has a simple structure and low cost.

Description

Decoration with simulation object

Technical Field

The utility model relates to a decoration, in particular to a decoration with a simulation object

Background

Artificial ornamental pieces, especially ornamental pieces with simulators, such as ornamental pieces with simulated butterflies, dragonflies, bees, etc., are often used in flower gardens near parks and squares, with one end of the ornamental piece inserted into the soil and the end with the simulators protruding out of the flower garden.

The existing decoration with the simulation object usually installs an electric driving device on the housing to drive the simulation object to make various actions, such as lifting and lowering, flapping wings or rotating. The Chinese patent application publication No. CN113844207A discloses an outdoor dynamic butterfly model, which has the function of providing a device for driving the model to greatly lift, swing and wing flapping effects, but has the advantages of complex structure, difficult assembly and high production cost.

Disclosure of Invention

The utility model aims to provide a decoration with a simulation object, which can realize the effect of greatly lifting the simulation object by adopting a simple structure.

In order to achieve the above purpose, the decoration with the simulation object comprises the simulation object with wings and a lifting mechanism arranged in a shell, wherein the simulation object and the lifting mechanism are connected through a supporting rod and move synchronously, two guide racks are vertically arranged on the inner wall of the shell relatively, a motor and a lifting gear are arranged in the lifting mechanism, a gear area matched with the guide racks is arranged on the circumferential curved surface of the lifting gear, and the motor drives the lifting mechanism to repeatedly lift and move along the two guide racks in the shell.

Further, when the lifting mechanism is lifted, the gear area of the lifting mechanism is only meshed with one guide rack, and when the lifting mechanism is lifted to two ends of the two guide racks, the gear area of the lifting mechanism is not meshed with the two guide racks.

Further, the elevating system wraps up the inner shell outward, elevating system still includes drive gear, drive gear train and worm, the worm is connected with the motor, drive gear meshing sets up in worm one side, drive gear train meshing sets up between drive gear and elevating gear.

Further, the shell is adjacent to the supporting seat, a solar cell panel is mounted on the supporting seat, a control circuit board and a conductive connecting sheet are arranged in the shell, the control circuit board is electrically connected with the solar cell panel and the conductive connecting sheet respectively, a conductive piece electrically connected with a motor is arranged at a position, opposite to the conductive connecting sheet, outside the inner shell, and when the lifting mechanism moves back and forth in the shell, the conductive piece is in electrical contact with the conductive connecting sheet.

Further, a guide sliding groove is arranged in the outer shell, and a guide sliding sheet matched with the guide sliding groove is arranged outside the inner shell.

As the preferable scheme, the supporting rod is hollow, a cavity is arranged in the simulation object, a rotatable supporting column is arranged in the cavity, and wings of the simulation object are fixedly connected with the supporting column.

Further, one side of driving gear terminal surface is equipped with the moving part, moving part is towards driving gear terminal surface one side transversely is provided with the hole groove, it has eccentric rod to drive the gear along the terminal surface extension, eccentric rod inserts in the hole inslot the top of moving part is equipped with the push rod, push rod one end and moving part fixed connection, the other end stretches into the cavity in passing the bracing piece, through connecting rod and support column fixed connection.

Further, one end of the push rod extending into the cavity is provided with a rectangular piece, and limit grooves matched with the rectangular piece are vertically formed in two opposite sides of the cavity.

Further, the included angle between the connecting rod and one side of the plane outline of the wing is smaller than 180 degrees.

As the preferable scheme, lifting gear keeps away from drive gear group's terminal surface one side is equipped with the transfer line, the transfer line both ends are provided with rotary gear, are fixed with the roating seat in the bracing piece bottom, the roating seat inboard is equipped with first teeth of a cogwheel, lifting gear keeps away from and is equipped with the second teeth of a cogwheel on drive gear group's the terminal surface, the rotary gear at transfer line both ends meshes with first teeth of a cogwheel and second teeth of a cogwheel respectively.

Compared with the prior art, the utility model has the beneficial effects that:

according to the scheme, the lifting mechanism is integrally lifted on the shell, the slender space in the shell is fully utilized, so that the simulation object can be lifted greatly, and the product is simple in structure and low in cost.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of the structure of the various parts within the housing of the present utility model;

FIG. 3 is a first state diagram of the elevator mechanism of the present utility model running between guide racks;

FIG. 4 is a second state diagram of the elevator mechanism of the present utility model operating between guide racks;

FIG. 5 is a third state diagram of the elevator mechanism of the present utility model operating between guide racks;

FIG. 6 is a fourth state diagram of the elevator mechanism of the present utility model operating between guide racks;

FIG. 7 is a schematic view of another angle of various parts within the housing of the present utility model;

FIG. 8 is a schematic diagram of a simulation object of the present utility model;

FIG. 9 is an exploded view of the elevator mechanism of the preferred embodiment of the present utility model;

FIG. 10 is a schematic view of another preferred embodiment of the present utility model;

fig. 11 is a top cross-sectional view of the housing of the present utility model.

Reference numerals and names in the drawings are as follows:

wing 110, simulation object 100, outer case 200, lifting mechanism 300, support bar 400, guide rack 210, motor 310, lifting gear 320, gear area 321, inner case 220, driving gear 330, driving gear set 340, worm 350, support base 230, solar cell panel 231, control circuit board 240, conductive tab 250, conductive member 221, chamber 101, support column 102, moving member 360, hole slot 361, eccentric rod 331, push rod 370, connecting rod 103, rectangular member 371, limit slot 104, driving rod 380, rotating gear 381, rotating base 410, first gear teeth 411, second gear teeth 311, guide slot 260, guide piece 222.

Detailed Description

The following description of the technical solutions in the embodiments of the present utility model will be clear and complete, and it is obvious that the described embodiments are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-2, the present embodiment provides a decoration with a dummy 100, which includes a dummy 100 with wings 110 and a lifting mechanism 300 installed in a housing 200, wherein the dummy 100 with wings 110 may be a butterfly, a dragonfly or a bee animal dummy with wing profile, the housing 200 may have a taper portion for being inserted into soil to fix the entire housing 200, the dummy 100 and the lifting mechanism 300 are connected to each other through a support bar 400, and when the lifting mechanism 300 moves up and down in the housing 200, the dummy 100 at the other end of the support bar 400 moves up and down synchronously, and two guide racks 210 are vertically disposed opposite to each other on the inner wall of the housing 200 along the longitudinal direction of the housing 200.

The lifting mechanism 300 is internally provided with a motor 310 and a lifting gear 320, the motor 310 is used for driving the lifting gear 320 to rotate, the lifting gear 320 is provided with a gear area 321, and the gear area 321 can be meshed with the guide rack 210. As shown in fig. 3-4, when the lifting mechanism 300 is at the bottom ends of the two guide racks 210, the gear area 321 of the lifting gear 320 is between the two guide racks 210, and the two ends of the gear area are not meshed with the two guide racks 210 respectively, at this time, the motor 310 drives the lifting gear 320 to start rotating, the gear area 321 starts deflecting, and only starts to mesh with one guide rack 210 and is not contacted with the guide rack 210 at the other side, so that the lifting gear 320 can be driven to start to lift while the guide racks 210 start to mesh, thereby driving the whole lifting mechanism 300 and the simulation object 100 to start to lift.

As shown in fig. 5 to 6, when the motor 310 drives the entire lifting mechanism 300 to rise to the top ends of the two guide racks 210, the gear area 321 is disengaged from the engagement with one guide rack 210 and is not engaged with the other guide rack 210, and the lifting is stopped, at this time, the motor 310 continues to drive the lifting gear 320 to rotate, the gear area 321 continues to deflect in the same direction along the original direction, and starts to engage with the guide rack 210 on the other side only, and does not contact with the guide rack 210 on the opposite side, and can drive the lifting gear 320 to start to descend while engaging with the guide rack 210 on the other side, so as to drive the entire lifting mechanism 300 and the dummy 100 to start to descend. When moving to the bottom ends of the two guide racks 210, the gear section 321 is disengaged from the other guide rack 210, and the descent is stopped. At this time, the gear area 321 of the lifting gear 320 returns to the space between the two guide racks 210, and the two ends of the gear area are respectively not engaged with the two guide racks 210, so that a lifting cycle is formed, and if the motor 310 continues to drive the lifting gear 320, the entire lifting mechanism 300 can repeatedly move up and down along the space between the two guide racks 210 in the housing 200. As can be seen from the above embodiments, in this embodiment, the lifting mechanism 300 is lifted in the housing 200 as a whole, and in principle, the lifting amplitude of the lifting mechanism 300 and the simulation object 100 is only dependent on the lengths of the housing 200 and the guide rack 210 in the housing 200, so that the space in the housing 200 is fully utilized to realize the adjustment of the lifting amplitude.

In the above embodiment, further, as shown in fig. 7, the driving end of the motor 310 is connected with a worm 350, the motor 310 may drive the worm 350 to rotate, a driving gear 330 is disposed on one side of the worm 350, the driving gear 330 is meshed with the worm 350, a driving gear set 340 is disposed at the bottom of the driving gear 330, the driving gear set 340 is meshed with the driving gear 330 and the lifting gear 320, preferably, the driving gear set 340 is meshed with two duplex gears, preferably, the driving gear 330 and the lifting gear 320 are also duplex gears, the worm 350, the driving gear 330, the driving gear set 340 and the lifting gear 320 are all wrapped by the inner housing 220 to form an integral lifting mechanism 300, and when the motor 310 is started, the driving gear 330 is driven to rotate, and then the lifting gear 320 is driven to rotate by the driving gear set 340.

Still further, as shown in fig. 7, the housing 200 is provided with a supporting seat 230 adjacent to each other, the supporting seat 230 is disposed at intervals along the periphery of the housing 200, a groove is disposed on the supporting seat 230, a solar panel 231 for supplying power to the motor 310 is disposed in the groove, a control circuit board 240 and a conductive tab 250 are disposed at the top of the housing 200, the control circuit board 240 is electrically connected to the solar panel 231 for receiving an electrical signal of the solar panel 231, the conductive tab 250 is also electrically connected to the control circuit board 240 for transmitting a control signal and an electrical signal transmitted through the control circuit board 240, conductive members 221 are disposed opposite to the conductive tab 250 outside the inner housing 220, the conductive members 221 are electrically connected to the motor 310, the conductive members 221 are electrically contacted with the conductive tab 250, so that the motor 310 can repeatedly lift the lifting mechanism 300 through the conductive members 221 and the conductive tab 250, continuously receives an electrical signal of the solar panel 231 and a control signal of the control circuit board 240, so that the entire length of a conductive wire in the entire motor is reduced, and the conductive wire is set up and down, and down the conductive members are preferably, the conductive members are disposed in parallel to the opposite to the lifting mechanism 210, the length of the conductive members is set up and down in the opposite to the conductive tab 250, the length of the conductive members is preferably set up and down in the opposite to the lifting mechanism is set up and down in the opposite to the lifting mechanism to the length of the conductive member 300, the conductive elements 221 are in electrical contact with the conductive tabs 250 to ensure that the signal is not interrupted.

Further, as shown in fig. 11, a guide chute 260 is provided in the outer housing 200, the guide chute 260 is parallel to the guide rack 210, and a guide vane 222 matched with the guide chute 260 is provided outside the inner housing 220, so that the lifting mechanism 300 wrapped by the whole inner housing 220 can be better prevented, and the deviation of the track occurs when the outer housing 200 moves.

As another preferred embodiment, as shown in fig. 8-9, the supporting rod 400 is hollow, a chamber 101 is provided in the simulation object 100, supporting columns 102 capable of performing circumferential rotation are provided at two sides in the chamber 101, and wings 110 of the simulation object 100 are fixedly connected with sides of the supporting columns 102. One side of the end face of the driving gear 330 is provided with a moving part 360, one side of the moving part 360 facing the end face of the driving gear 330 is transversely provided with a hole groove 361, the driving gear 330 extends along the end face to form an eccentric rod 331, the eccentric rod 331 is inserted into the hole groove 361, when the motor 310 drives the driving gear 330 to rotate, the eccentric rod 331 is driven to rotate, the eccentric rod 331 can move back and forth in the hole groove 361 of the moving part 360, and accordingly the moving part 360 is driven to move back and forth.

As shown in fig. 9, a push rod 370 is disposed at the top end of the moving member 360, one end of the push rod 370 is fixedly connected with the moving member 360, the other end of the push rod passes through the hollow support rod 400 and extends into the cavity 101, and is fixedly connected with the side surface of the support column 102 through the connecting rod 103, so that when the motor 310 drives the moving member 360 to reciprocate, the push rod 370 is driven to move synchronously, and the support column 102 is driven to rotate circumferentially through the connecting rod 103, so that the wings 110 of the simulation object 100 are in a vertically turned view, the whole product is more vivid, and the upper and lower lifting of the simulation object 100 and the vertical turning of the wings 110 of the simulation object 100 can be simultaneously driven through the motor 310, and the structure is simple and reliable.

As further shown in fig. 8, in the above embodiment, a rectangular piece 371 is disposed at one end of the push rod 370 extending into the cavity 101, and a limit groove 104 matching with the rectangular piece 371 is vertically disposed at two sides of the cavity 101. Rectangular piece 371 only can slide in spacing groove 104 to lead to push rod 370 to only can remove along the direction of spacing groove 104 in cavity 101, guarantee that the deviation of position can not appear in the in-process of push rod 370 oscilaltion, thereby better assurance the effect of the upper and lower roll of wing 110 on simulation object 100.

Still further, the angle formed by the connecting rod 103 and one side of the planar profile of the wing 110 is less than 180 degrees. The angle push down rod 370 is preferably used to flip up and down the wings 110 of the simulation object 100 during the up and down process.

As still another preferred embodiment of the present utility model, as shown in fig. 10, a transmission rod 380 is disposed on a side of the end surface of the lifting gear 320 away from the transmission gear set 340, rotation gears 381 are disposed at two ends of the transmission rod 380, a rotation seat 410 is fixed at the bottom of the support rod 400, the support rod 400 can rotate synchronously with the rotation seat 410, a first gear tooth 411 is disposed on the inner side of the bottom of the rotation seat 410, a second gear tooth 311 is disposed on the end surface of the lifting gear 320 away from the transmission gear set 340, and the rotation gears 381 at two ends of the transmission rod 380 are meshed with the first gear tooth 411 and the second gear tooth 311 respectively. When the motor 310 drives the lifting gear 320 to rotate, the rotating gear 381 at one end of the transmission rod 380 is driven to rotate, so that the transmission rod 380 drives the rotating gear 381 at the other end to rotate, and the rotating seat 410 is driven to rotate and the support rod 400 is synchronously rotated with the rotating gear 381.

The details of the above-described exemplary embodiments and the utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims

1. Decoration with simulation thing, its characterized in that includes simulation thing (100) and elevating system (300) of installing in shell (200) with wing (110), simulation thing (100) and elevating system (300) are connected and synchronous motion through bracing piece (400), are provided with two guide racks (210) relatively vertical at shell (200) inner wall, be equipped with motor (310) in elevating system (300) and with elevating gear (320), the circumference curved surface of elevating gear (320) is equipped with and is used for with guide rack (210) complex gear area (321), motor (310) drive elevating system (300) are along carrying out repeated elevating movement between two guide racks (210) in shell (200).

2. A decorative item with a simulated object according to claim 1, wherein the gear area (321) of the lifting mechanism (300) will only intermesh with one guide rack (210) when the lifting mechanism (300) is lifted, and the gear area (321) of the lifting mechanism (300) will not intermesh with both guide racks (210) when the lifting mechanism (300) is lifted to both ends of both guide racks (210).

3. The decorative piece with the simulation object according to claim 2, wherein the lifting mechanism (300) is wrapped with the inner shell (220), the lifting mechanism (300) further comprises a driving gear (330), a transmission gear set (340) and a worm (350), the worm (350) is connected with the motor (310), the driving gear (330) is arranged on one side of the worm (350) in a meshing manner, and the transmission gear set (340) is arranged between the driving gear (330) and the lifting gear (320) in a meshing manner.

4. A decorative piece with a simulation object according to claim 3, wherein a supporting seat (230) is adjacent to the outer shell (200), a solar panel (231) is mounted on the supporting seat (230), a control circuit board (240) and a conductive tab (250) are arranged in the outer shell (200), the control circuit board (240) is electrically connected with the solar panel (231) and the conductive tab (250) respectively, a conductive piece (221) electrically connected with a motor (310) is arranged at a position opposite to the conductive tab (250) outside the inner shell (220), and the conductive piece (221) is electrically contacted with the conductive tab (250) when the lifting mechanism (300) moves back and forth in the outer shell (200).

5. The decorative piece with a simulation object according to claim 4, wherein a guide sliding groove (260) is arranged in the outer shell (200), and a guide sliding sheet (222) matched with the guide sliding groove (260) is arranged outside the inner shell (220).

6. Decoration with simulation object according to any of the claims 3-5, characterized in that the support bar (400) is hollow, a chamber (101) is arranged in the simulation object (100), a rotatable support column (102) is arranged in the chamber (101), and the wings (110) of the simulation object (100) are fixedly connected with the support column (102).

7. The decoration with simulation objects according to claim 6, wherein a moving part (360) is arranged on one side of the end face of the driving gear (330), a hole groove (361) is transversely formed in one side of the end face of the moving part (360) facing the driving gear (330), an eccentric rod (331) is arranged on the driving gear (330) in an extending mode along the end face, the eccentric rod (331) is inserted into the hole groove (361), a push rod (370) is arranged at the top end of the moving part (360), one end of the push rod (370) is fixedly connected with the moving part (360), the other end of the push rod (370) penetrates through the support rod (400) to extend into the cavity (101), and the other end of the push rod (370) is fixedly connected with the support column (102) through a connecting rod (103).

8. The decoration with the simulation object according to claim 7, wherein a rectangular piece (371) is arranged at one end of the push rod (370) extending into the cavity (101), and limit grooves (104) matched with the rectangular piece (371) are vertically arranged at two opposite sides of the cavity (101).

9. Decoration with simulant according to claim 8, characterized in that the angle between the connecting rod (103) and the side of the plane contour of the wing (110) is less than 180 degrees.

10. The decoration with simulation objects according to claim 9, wherein a transmission rod (380) is arranged on one side of the end face, away from the transmission gear set (340), of the lifting gear (320), rotary gears (381) are arranged at two ends of the transmission rod (380), a rotary seat (410) is fixed at the bottom of the supporting rod (400), first gear teeth (411) are arranged on the inner side of the rotary seat (410), second gear teeth (311) are arranged on the end face, away from the transmission gear set (340), of the lifting gear (320), and the rotary gears (381) at two ends of the transmission rod (380) are meshed with the first gear teeth (411) and the second gear teeth (311) respectively.