CN115076644A - Artificial festive lantern - Google Patents

Abstract

The invention relates to a simulation festive lantern. At least three sliding arms are hinged on the pivoting area of the sliding sleeve through a restraint piece in a spaced mode. Under the condition of simulating the opening of the flower, the sliding arm can change an included angle formed by the sliding arm and the petal opening and closing control mechanism through the movement of the sliding rod connected with the sliding sleeve along the axis direction of the sliding arm. One end of the sliding rod is connected with the other end of the sleeving area of the sliding sleeve, and the other end of the sleeving area of the sliding rod is connected with a damping device or an electric transmission device which drives the sliding rod to penetrate through the center of the petal opening and closing control mechanism to drive the sliding sleeve to move.

Description

Artificial festive lantern

Technical Field

The invention relates to the technical field of lamp decoration articles, in particular to a simulation festive lantern.

Background

There are many kinds of decorative lighting products on the market to satisfy people's pursuit of good life, of which petal-type decorative lights are one.

The invention patent with publication number CN107747721A discloses a flower type LED lamp holder capable of being quickly mounted and dismounted, which comprises a heat dissipation shell, wherein jacks are arranged on an LED lamp socket, an LED lamp is mounted on the LED lamp socket, a petal-shaped supporting plate is mounted on one side of a spring bolt, and a baffle is arranged on one side of the petal-shaped supporting plate. Petal shape fagging is connected in the latch department with the baffle, realize opening and shutting of baffle through the latch, press petal shape fagging, then the baffle lifts up under the effect of latch, thereby form a breach, install the LED lamp from breach into on the LED lamp socket this moment, accomplish the installation of LED lamp, loosen petal shape fagging again, the baffle whereabouts this moment, the one end card of baffle is inside the draw-in groove on the LED lamp shell, prevent that the LED lamp from droing, the quantity of petal shape fagging and baffle is six respectively, install on six faces of heat dissipation shell, form the shape of a flower.

The invention discloses a luminous artificial flower with publication number CN103330313A, relates to a luminous artificial flower with a dye-sensitized solar cell as a power supply, and belongs to the technical field of solar lighting application. The solar flower decoration device is composed of a dye-sensitized solar cell, a conducting wire, a photovoltaic controller, an energy storage cell, a photosensitive automatic switch, an LED lamp, a flowerpot, a mounting box, fillers, a hollow support, decoration leaves and flowers. In the daytime, sunlight irradiates on flowers made of a dye-sensitized solar cell as a raw material, the dye-sensitized solar cell generates current, and the current is input into a photovoltaic controller through a conducting wire for adjustment and then is input into an energy storage cell for storage; at night, the photosensitive automatic switch is automatically switched on by the change of natural light, the circuit between the energy storage battery and the LED lamp is automatically switched on, the energy storage battery outputs current to supply power to the LED lamp, and the LED lamp emits bright light to enable the flower to emit the bright light at night.

The basic structure of the existing petal decorative lamp is that a plurality of decorative petals enclose a lamp source, most of the existing petal decorative lamp is static, namely, the petals can not be automatically opened and closed, therefore, the invention designs a dynamic simulation flower lamp which can simulate the flower opening process.

Furthermore, on the one hand, due to the differences in understanding to those skilled in the art; on the other hand, since the applicant has studied a great deal of literature and patents when making the present invention, but the disclosure is not limited thereto and the details and contents thereof are not listed in detail, it is by no means the present invention has these prior art features, but the present invention has all the features of the prior art, and the applicant reserves the right to increase the related prior art in the background.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a simulation festive lantern. The simulated festive lantern comprises at least an inner layer of petal structure, an outer layer of petal structure and at least one lamp bead. The lamp beads are wrapped on the radial inner side by the inner petal structure under the condition that the inner petal structure is closed. The at least two layers of petal structures are sleeved on the branch rod in a coaxial Z mode in a vertically sliding mode through respective sliding sleeves. In an assembly state, the sliding sleeve of the inner petal structure is located above the sliding sleeve of the outer petal structure in the axial direction Z. The petal opening and closing control mechanism is sleeved on the branch rod and used for resisting the gravity of the at least two layers of petal structures upwards along the axial direction in a mode of being coaxial Z with the respective sliding sleeves of the two layers of petal structures, wherein the petal opening and closing control mechanism can adjust the opening degree of all petals of the at least outer layer petal structures hinged to the sliding sleeves of the outer layer petal structures in a sliding mode relative to the sliding sleeves of the outer layer petal structures along the branch rod. The petal opening and closing control mechanism and the sliding sleeve slide relatively under the drive of a damping device or an electric transmission device.

Preferably, the simulated festive lantern at least comprises a first simulated festive lantern piece, a first sliding arm, a second simulated festive lantern piece, two sliding sleeves, a lamp bead, a petal opening and closing control mechanism and a damping device or an electric transmission device. The two sliding sleeves are respectively connected with the first sliding arms and the second sliding arms to form outer petals and inner petals. The first simulation flower piece and the second simulation flower piece are respectively connected with the first sliding arm and the second sliding arm to form a single petal of an outer layer petal and a single petal of an inner layer petal. The lamp beads are used for simulating pistils and providing illumination. The damping device or the electric transmission device is used for providing power for simulating the opening of the flowers. The petal opening and closing control mechanism is used for providing a connecting channel between the sliding sleeve in the outer petals and the damping device or the electric transmission device and limiting the movement of the first sliding arm.

The sliding sleeve is a cylinder, and a direction axis Z is established according to the axis of the sliding sleeve. The sliding sleeve is divided into a sleeving area, a pivoting area and an upper joint along the axis Z. The pivoting area is connected with the first sliding arms or the second sliding arms. And a plurality of first sliding arms or a plurality of second sliding arms are hinged on the pivoting area of the sliding sleeve through a restraint piece in the same plane in a spaced mode to form the outer layer petals or the inner layer petals. The upper joint of the sliding sleeve in the inner petals is connected with the lamp bead, and the sleeving area of the sliding sleeve in the inner petals is connected with the upper joint of the sliding sleeve in the outer petals, so that the lamp bead, the outer petals and the inner petals form a flower structure.

The sleeving area of the sliding sleeve in the outer petals is used for connecting the damping device or the electric transmission device, so that the damping device or the electric transmission device can drive the sliding sleeve to move along an axis Z. The petal opening and closing control mechanism is a hemispherical shell, a through hole convenient for the damping device or the telex device to be connected with the sliding sleeve in the outer-layer petal is formed in the vertex of the petal opening and closing control mechanism, and the edge of the petal opening and closing control mechanism is in contact with the middle of the first sliding arm.

Damping device perhaps telex drives two under the condition that sliding sleeve removed along axis Z, first slide arm articulates the one end in the pin joint district, promptly, first slide arm joint can follow sliding sleeve removes, simultaneously the free end of first slide arm with sliding sleeve reverse movement, first slide arm with the contained angle that petal switching control mechanism becomes in the plane that contact point and axis Z become changes, with first slide arm is connected first emulation flower piece position changes to the opening and the polymerization of the outer petal of simulation flower.

The second sliding arm is hinged to one end of the pivoting area, namely, the second sliding arm joint can move along with the sliding sleeve, and under the condition that the outer petals simulate the opening and the polymerization of the outer petals of the flower, the sliding sleeve in the inner petals moves along with the sliding sleeve in the outer petals. And under the condition that the outer petals of the simulated flower polymerize, the second simulated flower piece connected with the second sliding arm is in contact with the first simulated flower piece and is restrained by the first simulated flower piece, so that the outer petals polymerize. And under the condition that the outer petals of the simulated flower are opened, the second simulated flower piece connected with the second sliding arm is separated from the first simulated flower piece and falls under the action of gravity, so that the inner petals are diverged, and the opening of the inner petals of the simulated flower is realized. Under the condition that the damping device or the electric transmission device drives the two sliding sleeves to be far away from the petal opening and closing control mechanism along the axis Z, the outer-layer petals and the inner-layer petals can jointly simulate petal opening. The petals of the inner layer open later than the petals of the outer layer.

At least three sliding arms are hinged on the pivoting area of the sliding sleeve through a restraint piece in a spaced mode. Under the condition of simulating the opening of the flower, the sliding arm can change an included angle formed by the sliding arm and the petal opening and closing control mechanism through the movement of the sliding rod connected with the sliding sleeve along the axis direction of the sliding arm. One end of the sliding rod is connected with the other end of the sleeving area of the sliding sleeve, and the other end of the sleeving area of the sliding rod is connected with a damping device or an electric transmission device which drives the sliding rod to penetrate through the center of the petal opening and closing control mechanism to drive the sliding sleeve to move.

According to a preferred embodiment, the sliding sleeve comprises at least a sliding sleeve connecting the outer petals and a sliding sleeve connecting the inner petals. The sliding sleeve connected with the inner petals is connected with the sliding sleeve connected with the outer petals, and the sliding sleeve connected with the outer petals can be connected with the sliding rod. The sliding arm at least comprises a first sliding arm hinged on the sliding sleeve connected with the outer petals and a second sliding arm hinged on the sliding sleeve connected with the inner petals. Under the condition that the simulated flower is opened, the included angle formed by the first sliding arm and the petal opening and closing control mechanism is changed, so that the constraint of the configured first simulated flower piece on the second simulated flower piece installed on the second sliding arm is changed.

Preferably, the first sliding arm has at least an open position, an over-open position and a closed position during the movement of the sliding rod driven by the damping means or the electric transmission means. Preferably, the artificial flower lamp can simulate the whole process of a flower from bud to full flowering. Preferably, when the artificial flower lamp simulates the shape of a flower bud of a flower, the first sliding arm is in a closed position. When the simulation flower lamp simulates a flower to be completely opened, the first sliding arm is in the over-placing position. Preferably, the first sliding arm is located at an open position in a process of simulating a flower from a bud state to a fully open state.

Preferably, electromagnetic levitation devices are disposed on the first sliding arm and the second sliding arm. Preferably, the magnetic suspension mode is arranged, so that the situation that the second simulation flower piece arranged on the second sliding arm cannot simulate a complete opening process due to the fact that the shape of the second simulation flower piece is changed by the gravity of the second sliding arm and the second simulation flower piece and the constraint of the first simulation flower piece configured by the first sliding arm can be avoided, and the anti-natural state that the second simulation flower piece is excessively opened when the first simulation flower piece is not completely opened appears.

According to a preferred embodiment, the petal opening and closing control mechanism is connected with the damping device or the electric transmission device shell through a branch rod. The branch pole is internally provided with a space capable of accommodating the sliding pole. The branch rods are connected with the damping device or the electric transmission device under the condition that the damping device or the electric transmission device drives the sliding rods to move, so that the sliding rods and the petal opening and closing control mechanism generate relative displacement.

Preferably, when the sliding rod is close to the sliding sleeve connecting the outer petals, the first sliding arm is switched from a converging state to a diverging state. The first simulation flower sheet arranged on the first sliding arm moves along with the first sliding arm, so that the opening of petals on the outer layer of the flower is simulated. When the first simulation flower piece begins to simulate the outer petals of the flower to open, the first simulation flower piece is separated from contact with a second simulation flower piece arranged on the second sliding arm, and the second simulation flower piece is not restrained by the first simulation flower piece any more. Under the condition that the second simulation flower piece is not constrained by the first simulation flower piece, the second simulation flower piece is switched from a polymerization state to a divergence state under the action of gravity of the second sliding arm, so that the opening of inner petals of the flower is simulated.

Preferably, the open state of the flower at least comprises four states of opening of the outer petals and polymerization of the inner petals, simultaneous opening of the outer petals and the inner petals, normal opening of the outer petals after the outer petals pass through the open inner petals, and over-opening of the outer petals and the inner petals. Preferably, the four open states of the flower correspond to a waiting state, an initial state, a holding state and an over-placing state of the flower respectively. Preferably, the invention simulates different flower opening states by arranging the electromagnetic suspension devices on the first sliding arm and the second sliding arm.

Preferably, the flower is in an open state by controlling the state of the second simulated flower piece by determining the magnitude of the magnetic force applied to the second sliding arm by the electromagnetic suspension device according to the position of the first sliding arm, so that the invention can simulate different flower open states.

Preferably, when the invention is in a state of being placed in a simulated flower, namely, when the invention is in the state of being polymerized by the petals of the outer layer and the inner layer of the simulated flower, the first sliding arm is switched from the closed position to the open position. When the first sliding arm is located at the opening position, the electromagnetic suspension device is in a first state that enables the second sliding arm to be kept unchanged. When the electromagnetic suspension device is in the first state, the suspension force generated by the electromagnetic suspension device can counteract the acting force which enables the second sliding arm and the second simulation flower piece to enter the open state from the closed state. Preferably, the force for moving the second sliding arm and the second artificial flower piece from the closed state to the open state or the force for moving the second sliding arm and the second artificial flower piece is a component of the gravity thereof in the moving direction.

Preferably, when the invention is in the initial state of the simulated flower, that is, when the invention is in the state of opening the outer petals and the inner petals of the simulated flower at the same time, the first sliding arm is in the opening position, and the electromagnetic suspension device is in the second state. Preferably, the electromagnetic suspension device in the second state first reduces the magnitude of the generated suspension force so that the suspension force is smaller than the acting force for making the second sliding arm and the second simulation flower piece enter the open state from the closed state, so that the second simulation flower piece enters the open state from the closed state. Preferably, the electromagnetic suspension device increases the magnitude of the generated levitation force to cancel the force that moves the second slider arm and the second artificial flower piece before the second artificial flower piece enters the open state, and the electromagnetic suspension device increases the generated levitation force to stop the second artificial flower piece at the open position when the second artificial flower piece enters the open state.

Preferably, when the flower-holding device is in a holding state of a simulated flower, namely when the petals on the outer layer of the simulated flower are normally opened after being opened, the petals on the inner layer are normally opened, the first sliding arm is switched from the opening position to the over-placing position. When the flower holding state is simulated, the electromagnetic suspension device is in the third state, and the suspension force generated by the electromagnetic suspension device can counteract the acting force which enables the second sliding arm and the second simulation flower piece to move, so that the second simulation flower piece is kept in the open state.

Preferably, when the invention is in the over-released state of the simulated flower, namely, when the invention is in the over-opening state of both the outer petals and the inner petals of the simulated flower, the first sliding arm is in the over-released position, and at this time, the electromagnetic suspension device is in the fourth state. Preferably, the suspension force generated by the electromagnetic suspension device in the fourth state is reduced, so that the second simulated flower piece enters the over-released state from the open state.

Preferably, the electromagnetic suspension device can adjust the magnitude of the suspension force by detecting the position of the first sliding arm to control the position of the second simulated flower piece, so as to simulate different flower opening states.

According to a preferred embodiment, the damping means comprise at least a sliding shaft, a spring and a damping oil. The damping oil provided on the surface of the sliding shaft can retard the movement of the sliding shaft with the spring being subjected to restorative deformation, so that the speed of movement of the sliding rod connected with the sliding shaft is limited.

According to a preferred embodiment, the electric drive comprises at least an electric motor and a drive carrier. The transmission frame is connected with the lower cover of the base, an output shaft of the motor is connected with the threaded strip, the threaded strip is connected with the sliding nut support, and the sliding rod is connected with the sliding nut support to form a lifting structure, so that the sliding rod has the lifting characteristic.

According to a preferred embodiment, the damping device can be connected to a base to support the artificial festive lantern. And the damping device is connected with the sliding rod and then is packaged and molded through a shell. Under the condition that the damping device is connected with the base, the protrusion arranged on the shell can be clamped with the groove arranged on the jack of the base.

According to a preferred embodiment, when the protrusion of the housing is engaged with the groove of the base, the contact piece of the housing contacts with the spring piece of the jack of the base to form a power supply channel, so that the battery box inside the base can supply power to the lamp bead of the artificial flower.

According to a preferred embodiment, the spring of the damping device arrangement is connected with an adjustment cap. In a case where a housing encloses the damping device, the spring, the adjustment cap, and the housing constitute an elastic force adjustment mechanism to adjust an initial elastic force of the spring of the damping device.

According to a preferred embodiment, the motor is arranged in the base lower cover. The motor and the transmission frame are connected to form an electric transmission device. The base lower cover is connected with the base upper cover to encapsulate the electric transmission device and provide support for the simulation festive lantern. Preferably, the base upper cover is the housing of the telex device.

According to a preferred embodiment, in the case that the damping device is used to drive the sliding rod, a pressing handle is arranged at one end of the sliding rod close to the damping device. The user can elastically deform the spring by applying a force to the pressing handle.

Drawings

FIG. 1 is a simplified schematic diagram of an artificial festive lantern using damping devices according to the present invention;

FIG. 2 is a simplified schematic illustration of a sliding sleeve provided by the present invention;

FIG. 3 is a simplified cross-sectional schematic view of a single sliding sleeve provided by the present invention;

FIG. 4 is a simplified cross-sectional schematic view of a sliding sleeve simulating the opening of a flower according to the present invention;

FIG. 5 is a simplified cross-sectional view of a sliding sleeve simulating unopened flowers according to the present invention;

FIG. 6 is a simplified cross-sectional view of a sliding sleeve with a simulated flower piece for simulating a non-opened flower according to the present invention;

fig. 7 is a simplified schematic diagram of an artificial festive lantern using an electrotransport device according to the present invention.

List of reference numerals

100: the simulated festive lantern 101: a lamp bead; 102: a second sliding arm; 103: a second simulated flower piece; 104: a first sliding arm; 105: a first simulated flower piece; 106: a petal opening and closing control mechanism; 107: a branch; 108: a slide bar; 109: a pressing handle; 110: a housing; 111: a protrusion; 112: a first contact pad; 113: a second contact pad; 114: a sliding shaft; 115: damping oil; 116: a spring; 117: an adjusting cap; 118: a spring plate; 119: a groove; 120: a jack; 121: a base; 122: a battery box; 123: a switch; 124: a pivoting area; 125: a sleeving area; 126: a base upper cover; 127: a base lower cover; 128: a motor; 129: a transmission frame; 130: an auxiliary axis Z; 132: a second sliding arm joint; 134: a first sliding arm joint; 135: an upper joint; 136: a sliding sleeve; 137: a restraint; 138: a movable nut bracket; 139: a threaded strip.

Detailed Description

The following detailed description is made with reference to fig. 1 to 7. The artificial flower sheets are arranged on the sliding arms around the lamp beads, the sliding arms are connected to the sliding sleeves, and the sliding sleeves are driven by the damping devices or the electric transmission devices to realize opening and closing of the petals. The artificial festive lantern of the invention has the advantages of small volume, easy maintenance and low cost, and can be widely applied to daily household occasions.

Example 1

In order to overcome the deficiencies of the prior art, the present invention provides a simulated festive lantern 100. The artificial festive lantern 100 comprises at least an inner layer and an outer layer of petal structures and at least one lamp bead. The lamp beads are wrapped on the radial inner side by the inner petal structure under the condition that the inner petal structure is closed. At least two petal structures are sleeved on the branch 107 in a manner of being capable of sliding up and down in a coaxial Z130 mode by respective sliding sleeves 136. In the assembled state, the inner petal design slip sleeve 136 is located above the outer petal design slip sleeve 136 in the axial direction Z130.

The branch 107 is sleeved with a petal opening and closing control mechanism 106 for resisting the gravity of at least the inner and outer layers of petal structures upwards along the axial direction in a mode of being coaxial Z130 with the respective sliding sleeves 136 of the inner and outer layers of petal structures, wherein the petal opening and closing control mechanism 106 can adjust the opening degree of all petals of at least the outer layer of petal structures, which are hinged to the sliding sleeves 136 of the outer layer of petal structures, in a sliding mode relative to the sliding sleeves 136 of the outer layer of petal structures along the branch 107. Preferably, the relative sliding of the petal opening and closing control mechanism 106 and the sliding sleeve 136 is driven by a damping device.

Preferably, the outer petals can be formed by connecting a sliding sleeve 136 by a plurality of first sliding arms 104 to which first simulated flower pieces 105 are connected. The inner petals can be formed by connecting a plurality of second sliding arms 102 connected with second simulated flower pieces 103 with another sliding sleeve 136. The petal opening and closing control mechanism 106 is a semi-spherical shell, the edge of the petal opening and closing control mechanism 106 is contacted with the middle part of the first sliding arm 104, and the vertex of the petal opening and closing control mechanism 106 is provided with a through hole which enables the sliding sleeve 136 of the outer layer petal to be connected with a damping device which provides simulated flower opening power.

Preferably, the damping means is configured to: in the case of a simulated flower opening, the two sliding sleeves 136 are brought away from the petal opening and closing control mechanism 106 along the axis Z130.

Referring to fig. 1, at least three sliding arms are hinged at spaced intervals to the pivoting region 124 of the sliding sleeve 136 by a restraint. In the case of simulating the opening of a flower, the slide arm can change the included angle with the petal opening and closing control mechanism 106 by the movement of the slide rod 108 connected with the slide sleeve 136 along the axis direction thereof. One end of the sliding rod 108 is connected with the sleeve joint area 125 of the sliding sleeve 136, and the other end is connected with a damping device which drives the sliding rod 108 to pass through the center of the petal opening and closing control mechanism 106 to drive the sliding sleeve 136 to move.

Referring to fig. 2, preferably, the slip sleeve 136 includes at least a slip sleeve 136 connecting the outer petals and a slip sleeve 136 connecting the inner petals. The sliding sleeve 136 connecting the inner petals is connected to the sliding sleeve 136 connecting the outer petals, and the sliding sleeve 136 connecting the outer petals can be connected to the sliding rod 108. The sliding arms comprise at least a first sliding arm 104 hinged to the sliding sleeve 136 connecting the outer petals and a second sliding arm 102 hinged to the sliding sleeve 136 connecting the inner petals. In the case of a simulated flower opening, the first sliding arm 104 changes the angle formed by the petal opening and closing control mechanism 106, so that the constraint of the configured first simulated flower piece 105 on the second simulated flower piece 103 mounted on the second sliding arm 102 is changed.

Preferably, the petal opening and closing control mechanism 106 is connected with the damping device through a branch 107. The branch 107 is provided with a space capable of accommodating the slide rod 108 therein. The branch 107 is connected with the damping device under the condition that the damping device drives the sliding rod 108 to move, so that the sliding rod 108 and the petal opening and closing control mechanism 106 generate relative displacement.

Referring to fig. 2 and 3, sliding sleeve 136 is divided along axis Z130 into a telescoping section 125, a pivoting section 124, and an upper joint 135. The pivoting region 124 is connected to the first sliding arms 104 or the second sliding arms 102. The first sliding arms 104 or the second sliding arms 102 are hinged on the pivoting area 124 of the sliding sleeve 136 in the same plane in a spaced manner through a first sliding arm joint 134 and a restraint 137 to form an outer layer petal or an inner layer petal. The upper joint 135 of the sliding sleeve 136 in the inner petals is connected with the lamp bead 101, and the sleeved area 125 of the sliding sleeve 136 in the inner petals is connected with the upper joint 135 of the sliding sleeve 136 in the outer petals, so that the lamp bead 101, the outer petals and the inner petals form a flower structure. The nesting area 125 of the sliding sleeve 136 in the outer petals is used to connect the damping device so that the damping device can move the sliding sleeve 136 along the axis Z130. Preferably, the damping means is connected by a sliding rod 108 to a socket region 125 of a sliding sleeve 136 in the outer petals.

In the case of the damping device moving the two sliding sleeves 136 along the axis Z130, the first sliding arm 104 is hinged at one end to the pivoting area 124, i.e. the first sliding arm joint 134 can move along with the sliding sleeves 136, while the free end of the first sliding arm 104 moves opposite to the sliding sleeves 136. The angle between the first slider arm 104 and the petal opening and closing control mechanism 106 in the plane of the contact point and the axis Z130 changes, and the position of the first simulated flower piece 105 attached to the first slider arm 104 changes, thereby simulating the opening and the convergence of the outer petals of the flower.

Referring to fig. 4, the damping device preferably moves a sliding sleeve 136 in the outer petals away from the petal opening and closing control mechanism 106 via the sliding rod 108, thereby simulating the opening of the flower. Preferably, when the simulated flower is opened, the included angle between the first sliding arm 104 and the sliding sleeve 136 hinged with the first sliding arm is increased, and the hinged point is close to the edge of the petal opening and closing control mechanism 106. Preferably, the first sliding arm 104 resists the weight of the outer petal design itself by contacting the edge of the petal opening and closing control mechanism 106, thereby avoiding excessive sagging of the outer petal design.

Preferably, the second sliding arm 102 falls under gravity, limited by the step of the sliding sleeve 136 hinged thereto, and the opening and closing degree between the second sliding arm 102 and the sliding sleeve 136 is less than ninety degrees.

Referring to fig. 5, preferably, the damping device is driven by the sliding rod 108 to close the inner vertex of the petal opening and closing control mechanism 106 with the sliding sleeve 136 in the outer petals, so as to simulate the flower polymerization. Preferably, the damping device is driven by the sliding rod 108 to move the sliding sleeve 136 in the outer petals close to the inner vertex of the petal opening and closing control mechanism 106 when simulating the polymerization of the flowers. The housing and rim of the petal opening and closing control mechanism 106 forces the first sliding arm 104 to rotate about its hinge point with the sliding sleeve 136 to reduce the angle between it and the sliding sleeve 136, thereby reducing the opening and closing degree of the outer petals. Preferably, the inner petal structures are pressed by the outer petal structures under the condition that the opening degree of the outer petal structures is reduced so as to reduce the opening degree.

Referring to fig. 6, preferably, a first simulated floral patch 105 in an outer petal configuration is capable of contacting a second simulated floral patch 103 in an inner petal configuration when simulating flower polymerization. In the process that the housing and the edge of the petal opening and closing control mechanism 106 force the first sliding arm 104 to rotate around the hinged point between the first sliding arm and the sliding sleeve 136 so as to reduce the included angle between the first sliding arm and the sliding sleeve 136, the first simulation flower piece 105 arranged on the first sliding arm 104 can be contacted with the second simulation flower piece 103 arranged on the second sliding arm 102, and the thrust of the housing and the edge of the petal opening and closing control mechanism 106 is transmitted to the second simulation flower piece 103, so that the second sliding arm 102 is forced to be close to the sliding sleeve of the inner layer petal structure, and the opening degree of the inner layer petal structure is further reduced.

Preferably, the second sliding arm 102 is hinged at one end of the pivoting area 124, i.e. the second sliding arm joint 132 is able to follow the sliding sleeve 136. In the case where the outer petals mimic the opening and converging of the outer petals of a flower, the gliding sleeve 136 in the inner petals moves with the gliding sleeve 136 in the outer petals.

Preferably, the first sliding arm 104 has at least an open position, an over-position and a closed position during the movement of the sliding rod 108 driven by the damping means. Preferably, the artificial flower light 100 of the present invention can simulate the whole process of a flower from bud to full flowering. Preferably, when the artificial lantern 100 of the invention is in a bud configuration simulating a flower, the first sliding arm 104 is in a closed position. When the artificial flower light 100 of the present invention is after the simulated flower is completely opened, the first sliding arm 104 is in the over-position. Preferably, the first sliding arm 104 is located in an open position during the process of simulating the flower from the bud state to the fully open state.

Referring to fig. 1, preferably, the damping means includes at least a sliding shaft 114, a spring 116, and a damping oil 115. The damping oil 115 provided on the surface of the sliding shaft 114 can retard the movement of the sliding shaft 114 with the spring 116 being subjected to restorative deformation, so that the moving speed of the sliding rod 108 connected to the sliding shaft 114 is limited.

Preferably, a damping device can be connected with the base 121 to achieve support of the artificial festive lantern 100. The damping device is connected with the sliding rod 108 and then encapsulated and molded by the outer shell 110. In the case where the damper device is connected to the base 121, the protrusion 111 provided to the housing 110 can be engaged with the recess 119 provided to the insertion hole 120 of the base 121.

Preferably, in the case that the protrusion 111 of the outer shell 110 is engaged with the groove 119 of the base 121, the contact piece of the outer shell 110 is in contact with the spring piece 118 disposed in the insertion hole 120 of the base 121 to form a power supply channel, so that the battery box 122 disposed inside the base 121 can supply power to the lamp bead 101 disposed on the artificial flower. Preferably, the user can control the power supply of the lamp bead 101 through a switch 123 connected with the battery box 122.

Preferably, an adjustment cap 117 is connected to the spring 116 of the damping device arrangement. In the case where the housing 110 encloses the damping device, the spring 116, the adjustment cap 117 and the housing 110 constitute an elastic force adjusting mechanism to adjust an initial elastic force of the spring 116 of the damping device, thereby enabling to adapt to users of different strength.

Preferably, in the case of using a damping device to drive the sliding rod 108, one end of the sliding rod 108 near the damping device is provided with a pressing handle 109. The user can elastically deform the spring 116 by applying a force to the pressing handle 109.

The user can cause the first slide arm 104 to gather by forcing the slide rod 108 away from the slide sleeve 136 by applying a force to the press handle 109. When the spring 116 recovers the generated elastic deformation, the sliding rod 108 is driven to approach the sliding sleeve 136, and under the action of the damping oil 115, the sliding rod 108 slowly and smoothly moves towards the sliding sleeve 136 connected with the outer petals. During the movement of the slide bar 108 toward the slide sleeve 136, which connects the outer petals, by the damping means, the first slide arm 104 moves from the closed position to the open position and finally to the over position. When the position of the first sliding arm 104 is changed, the first simulated flower piece 105 configured on the first sliding arm 104 does not restrict the second simulated flower piece 103 mounted on the second sliding arm 102 any more, and the second sliding arm 102 and the second simulated flower piece 103 configured thereon generate displacement under the action of gravity, so that the flower opening process is simulated.

Preferably, when the user applies force to the pressing handle 109, the sliding rod 108 moves away from the sliding sleeve 136, so that the first sliding arm 104 gathers, the first artificial flower piece 105 configured on the first sliding arm 104 contacts with the second artificial flower piece 103 mounted on the second sliding arm 102 and forces the second artificial flower piece 103 to gather, thereby realizing the closing of the flower.

Example 2

This embodiment is a further improvement of embodiment 1, and repeated contents are not described again. Referring to fig. 7, the present embodiment employs an electrical drive to actuate slide bar 108.

Preferably, the electric drive comprises at least an electric motor 128 and a drive carrier 129. The transmission frame 129 is connected with the lower cover 127 of the base, the output shaft of the motor 128 is connected with the threaded bar 139, the threaded bar 139 is connected with the sliding nut bracket 138, and the sliding rod 108 is connected with the sliding nut bracket 138 to form a lifting structure, so that the sliding rod 108 has the lifting characteristic. Preferably, the motor 128 may be a stepper motor, thereby facilitating user adjustment of the rotational speed of the motor 128 and the starting attitude of the simulated flower piece.

Preferably, the motor 129 is provided in the base lower cover 127. The motor 128 and the transmission frame 129 are connected to form an electric transmission device. The base lower cover 127 is coupled to the base upper cover 126 to enclose the electrotransport device and provide support to the festive light 100. The petal opening and closing control mechanism 106 is connected with a base upper cover 126 (an electric transmission device shell) through a branch 107.

Preferably, after the sliding rod 108 of the present embodiment is connected to the electrical transmission device, the user can adjust the opening speed of the artificial festive lantern 100 by adjusting the rotation speed of the motor. Preferably, the present embodiment utilizes the fly-by-wire device to drive the artificial flower lamp 100, so as to arbitrarily adjust the initial posture of the artificial flower, and during the process of simulating flower opening, the present embodiment can also simulate different flower opening speeds by adjusting the rotation speed of the motor 128.

Example 3

This embodiment is a further improvement on embodiments 1 and 2, and repeated details are not repeated. Preferably, electromagnetic levitation devices are disposed on the first and second slider arms 104 and 102. Preferably, the magnetic suspension mode is adopted to prevent the second simulation flower piece 103 mounted on the second sliding arm 102 from changing form due to the gravity of the second sliding arm 102 and the second simulation flower piece 103 and the constraint of the first simulation flower piece 105 configured by the first sliding arm 104, so that a complete opening process cannot be simulated, and an anti-natural state that the second simulation flower piece is excessively opened when the first simulation flower piece is not fully opened occurs.

Preferably, the petal opening and closing control mechanism 106 is connected to a damping device or an electric transmission device through a branch 107. The branch 107 is provided with a space capable of accommodating the slide rod 108 therein. The branch 107 is connected with the damping device or the electric transmission device under the condition that the damping device or the electric transmission device drives the sliding rod 108 to move, so that the sliding rod 108 and the petal opening and closing control mechanism 106 generate relative displacement.

Preferably, the first sliding arm 104 switches from a converging state to a diverging state when the sliding bar 108 is adjacent the sliding sleeve 136 connecting the outer petals. The first simulated flower piece 105 disposed on the first sliding arm 104 moves with the first sliding arm 104, thereby simulating the opening of the outer petals of the flower. When the first simulated flower piece 105 begins to simulate the opening of the outer petals of the flower, the first simulated flower piece 105 is out of contact with the second simulated flower piece 103 mounted on the second slider arm 102, and the second simulated flower piece 103 is no longer constrained by the first simulated flower piece 105. Under the condition that the second simulated flower piece 103 is not constrained by the first simulated flower piece 105, the second simulated flower piece 103 is switched from the converging state to the diverging state under the action of the gravity of the second sliding arm 102, so that the opening of the inner petals of the flower is simulated.

Preferably, the open state of the flower at least comprises four states of opening of the outer petals and polymerization of the inner petals, simultaneous opening of the outer petals and the inner petals, normal opening of the outer petals after the outer petals pass through the open inner petals, and over-opening of the outer petals and the inner petals. Preferably, the four open states of the flower correspond to a waiting state, an initial state, a holding state and an over-placing state of the flower respectively. Preferably, the present invention simulates different flower opening states by providing electromagnetic suspension devices on the first sliding arm 104 and the second sliding arm 102.

Preferably, the flower opening state is performed by the electromagnetic suspension device determining the magnitude of the magnetic force exerted on the second sliding arm 102 according to the position of the first sliding arm 104 so as to control the state of the second simulated flower piece 103, so that the present invention can simulate different flower opening states.

Preferably, first slider arm 104 is switched from the closed position to the open position when the invention is in a resting state of the simulated flower, i.e., when the invention is in a closed position wherein the petals of the outer layer of the simulated flower are open and the petals of the inner layer are closed. When first slider arm 104 is in the open position, the electromagnetic levitation device is in a first state in which second slider arm 102 remains stationary. When the electromagnetic suspension device is in the first state, the suspension force generated by the electromagnetic suspension device can counteract the acting force which enables the second sliding arm 102 and the second simulation flower piece 103 to enter the open state from the closed state. Preferably, the force for bringing the second sliding arm 102 and the second artificial flower 103 from the closed state to the open state or the force for moving the second sliding arm 102 and the second artificial flower 103 is a component of the gravity thereof in the moving direction thereof.

Preferably, when the present invention is in the initial state of the simulated flower, i.e., the invention is in the simultaneous opening of the outer petals and the inner petals of the simulated flower, the first sliding arm 104 is in the open position and the electromagnetic suspension device is in the second state. Preferably, the electromagnetic suspension device in the second state first reduces the magnitude of the generated suspension force so that the suspension force is smaller than the acting force for making the second slider arm 102 and the second artificial flower piece 103 enter the open state from the closed state, thereby making the second artificial flower piece 103 enter the open state from the closed state. Preferably, the electromagnetic levitation device increases the magnitude of the generated levitation force to cancel the force that causes the second slider arm 102 and the second artificial flower piece 103 to move before the second artificial flower piece 103 enters the open state, and the electromagnetic levitation device increases the generated levitation force to stop the second artificial flower piece 103 at the open position when the second artificial flower piece 103 enters the open state.

Preferably, when the present invention is in a holding state of a simulated flower, i.e., when the present invention is in a state where petals on an outer layer of the simulated flower are normally opened by over-opening petals on an inner layer, the first sliding arm 104 is switched from the open position to the over-release position. When the flower holding state is simulated, the electromagnetic suspension device is in the third state, and the suspension force generated by the electromagnetic suspension device can counteract the acting force which enables the second sliding arm 102 and the second simulation flower piece 103 to move, so that the second simulation flower piece 103 is kept in the open state.

Preferably, when the invention is in the over-released state of the simulated flower, that is, when the invention is in the state that both outer petals and inner petals of the simulated flower are over-opened, the first sliding arm 104 is in the over-released position, and at this time, the electromagnetic suspension device is in the fourth state. Preferably, the levitation force generated by the electromagnetic levitation device in the fourth state is reduced, so that the second artificial flower piece 103 enters the over-released state from the open state.

Preferably, the electromagnetic suspension device can adjust the magnitude of the suspension force by detecting the position of the first sliding arm 104 to control the position of the second simulated flower piece 103, so as to simulate different flower opening states.

It should be noted that the above-mentioned embodiments are exemplary, and that those skilled in the art, having benefit of the present disclosure, may devise various arrangements that are within the scope of the present disclosure and that fall within the scope of the invention. It should be understood by those skilled in the art that the present specification and figures are illustrative only and are not limiting upon the claims. The scope of the invention is defined by the claims and their equivalents. Throughout this document, the features referred to as "preferably" are only an optional feature and should not be understood as necessarily requiring that such applicant reserves the right to disclaim or delete the associated preferred feature at any time. The present description contains several inventive concepts, such as "preferably", "according to a preferred embodiment" or "optionally", each indicating that the respective paragraph discloses a separate concept, the applicant reserves the right to submit divisional applications according to each inventive concept.

Claims (10)

1. An artificial festive lantern, which comprises at least an inner layer and an outer layer of petal structures and at least one lamp bead,

wherein the lamp bead is wrapped on the radial inner side by the inner petal structure under the condition that the inner petal structure is closed,

wherein the at least two layers of petal structures are sleeved on the branch rod (107) in a way of being capable of sliding up and down in a coaxial Z (130) mode by means of respective sliding sleeves (136), wherein in an assembling state, the sliding sleeve (136) of the inner layer petal structure is positioned above the sliding sleeve (136) of the outer layer petal structure in the axial direction Z (130),

it is characterized in that the preparation method is characterized in that,

the petal opening and closing control mechanism (106) used for resisting the gravity of the at least inner and outer layers of petal structures upwards along the axial direction is sleeved on the branch rod (107) in a mode of being coaxial with Z (130) of the respective sliding sleeves (136) of the inner and outer layers of petal structures, wherein the petal opening and closing control mechanism (106) can adjust the opening and closing degree of all petals of the at least outer layer petal structures hinged to the sliding sleeves (136) of the outer layer petal structures in a sliding mode relative to the sliding sleeves (136) of the outer layer petal structures along the branch rod (107), and the relative sliding of the petal opening and closing control mechanism (106) and the sliding sleeves (136) is driven by a damping device or an electric transmission device to generate.

2. The artificial festive lantern according to claim 1,

the outer petals can be formed by connecting a plurality of first sliding arms (104) connected with first simulation flower pieces (105) with one sliding sleeve (136);

the inner petals can be formed by connecting a plurality of second sliding arms (102) connected with second simulation flower pieces (103) with another sliding sleeve (136);

the petal opening and closing control mechanism (106) is a hemispherical shell, the edge of the petal opening and closing control mechanism (106) is in contact with the middle part of the first sliding arm (104), and a through hole for connecting the sliding sleeve (136) of the outer layer petal with a damping device or an electric transmission device for providing simulated flower opening power is arranged at the vertex of the petal opening and closing control mechanism (106);

wherein the content of the first and second substances,

the damping device or the electrical transmission device is configured to: under the condition of simulating the opening of the flower, the two sliding sleeves (136) are driven to be away from the petal opening and closing control mechanism (106) along the axis Z (130).

3. The artificial festive lantern according to claim 1 or 2, wherein said sliding sleeve (136) is divided along said axis Z (130) into a sheathing zone (125), a pivoting zone (124) and an upper joint (135), wherein,

the pivoting area (124) is connected with a plurality of first sliding arms (104) or a plurality of second sliding arms (102), wherein a plurality of first sliding arms (104) or a plurality of second sliding arms (102) are provided with a first sliding arm joint (134) which is hinged on the pivoting area (124) of the sliding sleeve (136) through a restraining piece (137) in the same plane in a spaced mode to form the outer layer petals or the inner layer petals;

the upper joint (135) of the sliding sleeve (136) in the inner petals connects the light bead (101) and the telescoping region (125) of the sliding sleeve (136) in the inner petals connects with the upper joint (135) of the sliding sleeve (136) in the outer petals so that the light bead (101), the outer petals and the inner petals constitute a flower structure;

the sleeving area (125) of the sliding sleeve (136) in the outer petals is used for connecting the damping device or the electric transmission device, so that the damping device or the electric transmission device can drive the sliding sleeve (136) to move along an axis Z (130).

4. The artificial festive lantern according to any of claims 1 to 3, wherein in the case of movement of the two sliding sleeves (136) along the axis Z (130) by the damping means or the electric transmission means, the first sliding arm (104) is hinged at one end of the pivoting area (124), i.e. the first sliding arm joint (134) is able to follow the movement of the sliding sleeves (136), while the free end of the first sliding arm (104) moves opposite to the sliding sleeves (136), the angle between the contact point and the plane formed by the axis Z (130) of the first sliding arm (104) and the petal opening and closing control mechanism (106) changes, and the position of the first artificial flower petal (105) connected to the first sliding arm (104) changes, simulating the opening and the polymerization of the outer petals of the flower.

5. The artificial festive lantern according to any one of claims 1-4,

the second sliding arm (102) is hinged at one end of the pivoting area (124), i.e. the second sliding arm joint (132) can move along with the sliding sleeve (136), and under the condition that the outer petals simulate the opening and the polymerization of the outer petals of the flower, the sliding sleeve (136) in the inner petals moves along with the sliding sleeve (136) in the outer petals.

6. The artificial festive lantern according to any of claims 1-5, wherein said petal opening and closing control mechanism (106) is connected to said damping device or said housing of said electrotransport device by a branch (107), said damping device or said electrotransport device being connected to said sliding sleeve (136) in said outer petals by a sliding rod (108);

the branch rod (107) is internally provided with a space capable of accommodating the sliding rod (108), and the branch rod (107) is connected with the damping device or the electric transmission device under the condition that the damping device or the electric transmission device drives the sliding rod (108) to move, so that the sliding rod (108) and the petal opening and closing control mechanism (106) generate relative displacement.

7. The artificial festive lantern according to any one of claims 1 to 6, wherein the damping device comprises at least a sliding shaft (114), a spring (116) and a damping oil (115), wherein the damping oil (115) disposed on the surface of the sliding shaft (114) can retard the movement of the sliding shaft (114) under the restoring deformation of the spring (116), so that the speed of the movement of the sliding rod (108) connected with the sliding shaft (114) is limited;

an adjusting cap (117) is connected to the spring (116), and under the condition that the damping device is encapsulated by the shell (110), the spring (116), the adjusting cap (117) and the shell (110) form an elastic force adjusting mechanism so as to adjust the initial elastic force of the spring (116) of the damping device.

8. The artificial festive lantern according to any one of claims 1-7, wherein the electric transmission device comprises at least a motor (128) and a transmission frame (129), wherein the transmission frame (129) is connected with a base lower cover (127), an output shaft of the motor (128) is connected with a threaded bar (139), the threaded bar (139) is connected with a sliding nut bracket (138), and the sliding rod (108) is connected with the sliding nut bracket (138) to form a lifting structure, so that the sliding rod (108) has a lifting characteristic.

9. The artificial festive lantern according to any one of claims 1-8, wherein the damping device can be connected with a base (121) to support the artificial festive lantern, wherein the damping device is connected with the sliding rod (108) and then encapsulated by a shell (110), and under the condition that the damping device is connected with the base (121), a protrusion (111) arranged on the shell (110) can be clamped with a groove (119) arranged on a jack (120) of the base (121).

10. The artificial festive lantern according to any of claims 1-9, wherein the motor (129) is disposed in a base lower cover (127), the motor (128) and the transmission frame (129) are connected to form an electrical transmission device, and the base lower cover (127) is connected to a base upper cover (126) to encapsulate the electrical transmission device and provide support for the artificial festive lantern.

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