CN212165467U - Mirror with wire passing structure - Google Patents

Abstract

The utility model provides a mirror with a wire passing structure, which comprises a turnover mirror and a peripheral frame; a cavity for accommodating the wire passing structure is formed between the lens and the shell; a driving mechanism is arranged in the cavity, an output shaft of the driving mechanism is connected with the frame and is relatively fixed with the frame, and the output shaft of the driving mechanism is a rotating shaft at one side of the turnover mirror and the frame; a wire passing structure is arranged in the cavity; the wire passing structure comprises a first conductor and a second conductor which are isolated from each other, and the first conductor and the second conductor are respectively connected with the first electrode plate and the second electrode plate; the first electrode plate and the second electrode plate are respectively connected with the positive electrode and the negative electrode of the circuit positioned in the frame. The mirror is provided with a first conductor and a second conductor which are isolated from each other to realize the conduction of two polarity currents, so that the circuit in the mirror is conducted. And a plurality of driving mechanisms are not required to be arranged, and the problem of synchronism of the driving mechanisms is not required to be solved.

Description

Mirror with wire passing structure

Technical Field

The utility model relates to a mirror especially relates to a mirror with cross line structure.

Background

In daily life, the mirror is a necessary living article, and along with the continuous improvement of living standard of people, the functions and requirements of the mirror are more and more emphasized by people; the existing mirror has a single function, the mirror body does not have a light supplement lamp, the mirror image cannot be seen clearly under the condition of dark light, and the use requirement of a user when the ambient light is insufficient cannot be met by means of external light; movable mirrors (e.g., vanity mirrors) are portable, mobile, and are commonly used for grooming; in part of the existing mirrors, developers can install the light source on the mirror, and when the light source is required to irradiate, the corresponding switch is turned on. Such mirrors require internal wiring to complete the electrical circuit of the light source; in the prior art, most mirrors are reversible and used for adjusting the orientation angle of the mirrors, so that users have better experience. For a double-sided mirror with a circuit, when the mirror is turned over, the mirror needs to be turned over by 180 degrees or 360 degrees to realize the switching of the mirror surface, but in the turning process of the mirror, internal electric wires of the mirror are wound due to multiple turns, so that the internal electric wires are lost, and the circuit is easy to be disconnected along with long-term use. In addition, when the mirror surface of the existing mirror is electrically turned over, the problem that an internal wire is wound is solved, and the problem that the wire of a driving mechanism is crossed due to the fact that the internal space of the mirror is too small is solved.

Therefore, in order to solve the problems in the prior art, it is urgently needed to provide a mirror with a wire passing structure, which has a simple structure, and an excellent effect, and in which an internal circuit is not wound when the mirror is turned over.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, an object of the utility model is to provide a mirror with cross line structure, this mirror is through setting up the line problem of crossing when the line structure realizes the mirror upset, makes the wire can not take place to twine in the mirror is inside. The first conductor and the second conductor are arranged to be isolated from each other to conduct current of two polarities, so that the circuit in the mirror is conducted. The mirror realizes the electric turnover of the mirror surface, a plurality of driving mechanisms are not required to be arranged, and the problem of synchronism of the driving mechanisms is not required to be solved.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a mirror with a wire passing structure comprises a turnover mirror and a peripheral frame, wherein the turnover mirror is connected with the frame through a rotating shaft and comprises a mirror lens and a shell; the lens is characterized in that a cavity for accommodating the wire passing structure is formed between the lens and the shell;

a wire passing structure is arranged in the cavity, is positioned on the rotating axis of the shell and is fixedly connected with the shell;

the wire passing structure comprises a first conductor and a second conductor which are isolated from each other, and the first conductor and the second conductor are respectively connected with the first electrode plate and the second electrode plate; the first electrode plate and the second electrode plate are respectively connected with the positive electrode and the negative electrode of a circuit positioned in the frame;

the first conductor and the second conductor are connected with the positive electrode and the negative electrode of the power supply or the positive electrode and the negative electrode of the driving mechanism through leads so as to connect a circuit.

When the driving mechanism drives the frame to rotate, the shell drives the wire passing structure to synchronously rotate, so that the driving mechanism, the wire passing structure and the connected wires synchronously rotate; while the drive mechanism output shaft is used as a spindle in the mirror at the same time.

Specifically, the line passing structure is arranged in the mirror and comprises a first conductor and a second conductor which are isolated from each other, the line passing structure and the driving mechanism are respectively arranged on two sides of the rotation axis of the shell, and the line passing structure and the driving mechanism are connected through a lead to realize the circuit connection of the driving mechanism. Meanwhile, an output shaft of the driving mechanism is connected with the frame, when the frame is driven to rotate, the shell connected with the frame and the wire passing structure synchronously rotate, at the moment, the driving mechanism fixed on the shell synchronously rotates, and a wire connecting the driving mechanism and the wire passing structure rotates along with the rotation, so that the winding cannot occur; when the conducting wire is conducted, the problem of winding of the passing wire during turning is solved.

Specifically, because the space of the cavity in the mirror is limited, if two driving mechanisms are respectively arranged on two sides of the shell, the cost is increased by the two driving mechanisms; meanwhile, the two driving mechanisms are controlled to synchronously rotate, so that the wire cannot be wound; however, the synchronous control of the driving mechanism is very difficult, which increases the difficulty of circuit control design. Therefore, the threading structure of the technical scheme can solve the problem.

In particular, the circuitry within the frame includes a circuit formed by the connection of light sources or other components, such as inductive components.

Specifically, actuating mechanism fixes on the casing, can drive actuating mechanism and overturn simultaneously, and is favorable to the fixed stability of actuating mechanism.

The wire passing structure comprises a rotating shaft connected with the frame and a fixed block connected with the rotating shaft; a through groove is axially arranged on the rotating shaft, and one end of the first conductor penetrates through the through groove and is partially exposed so as to form connection between a lead and the first conductor; the other end of the first conductor is connected with the first electrode plate; the rotating shaft is wrapped with a conductive material to form the second conductor.

Specifically, the rotating shaft is provided with a through groove, the first conductor (namely the inner conductor) penetrates through the through groove to be connected with the lead, the periphery of the rotating shaft is wrapped with a conductive material to form a second conductor, and the structure realizes the isolation of the first conductor and the second conductor and can be used for conducting currents with different polarities. And the setting of fixed block can make first conductor one end that passes through logical groove fixed, and the other end is unsettled and is used for twining or connecting first electrode piece. In addition, the fixed block can also be favorable to the fixed of wire, makes the wire more stable with being connected of first conductor.

Preferably, the first conductor is fixed with the fixing block in a tight fit mode.

In the above, the fixing block is provided with a slot for inserting and connecting the first conductor.

Specifically, the first conductor is better fixed by the structure, and meanwhile, the first conductor is partially exposed to be connected with the lead, so that the lead can enter the slot to be connected with the first conductor.

As above, the first and second electrode sheets comprise elastic electrode sheets; the elastic electrode plate is in contact with the first conductor and the second conductor and can move relative to the first conductor and the second conductor; the elastic electrode slice is connected with an external power supply.

Preferably, the first electrode plate and the second electrode plate both adopt springs, one end of the first electrode plate is fixedly connected with the first conductor and wound around the periphery of the first conductor, and the other end of the first electrode plate is connected with the positive electrode or the negative electrode of the circuit in the shell; one end of the second electrode plate is connected with a second conductor on the rotating shaft and wound on the periphery of the second conductor, and the other end of the second electrode plate is connected with the negative pole or the positive pole of a circuit in the shell.

Specifically, the spring has certain elasticity and can conduct electricity. During the rotation of the shell, the elasticity of the spring can play a certain role of buffering, and meanwhile, the spring can conduct electricity, so that a circuit positioned in the frame is connected with the driving mechanism.

Preferably, the mirror further comprises a light source disposed within the frame and illuminating in front of the lens.

Specifically, because luminous mirror generally can set up round lamp source in the frame, the material through the frame chooses the light-permeable material for use, makes the light of lamp source see through, realizes the light filling. Therefore, the light source positioned on the frame needs to be connected through a wire, and therefore, the wire passing structure is arranged near the light source to achieve the purpose that the wire is connected into the light source, and meanwhile, when the mirror rotates, the wire cannot be wound.

Preferably, the driving mechanism comprises a brush motor and a motor.

Preferably, the mirror further comprises a stand column connected with the frame, and an adjusting button is arranged on the stand column and connected with a circuit, so that the adjusting button controls the driving mechanism to be opened and closed.

Specifically, the operation of the driving mechanism needs to be realized by controlling the opening and closing of the driving mechanism; the upright post is provided with a button, so that a user can select whether to turn the mirror through electric driving or directly and manually push the mirror to turn the mirror according to requirements. When the mirror is pushed to turn manually, the wire passing structure is arranged, so that the wire inside the mirror cannot be wound and the like.

The utility model has the advantages that:

the utility model provides a mirror with cross line structure, this mirror through set up the line problem of crossing when the line structure realizes the mirror upset, make the wire can not take place to twine in the mirror is inside. The wire passing structure is provided with a first conductor and a second conductor which are isolated from each other to realize the conduction of two polar currents, and the first electrode plate and the second electrode plate are connected with the first conductor and the second conductor, so that the circuit in the mirror is conducted. The mirror realizes the electric turnover of the mirror surface, does not need to be provided with a plurality of driving mechanisms, does not need to solve the problem of synchronism of the control driving mechanism, can realize synchronous turnover of each structure only through a physical structure, can effectively save the cost, has a simple structure, and has strong practicability.

Drawings

FIGS. 1-2 are schematic structural views of a mirror provided by the present invention;

fig. 3 is a schematic view of a line-passing structure of a mirror provided by the present invention;

fig. 4 is a schematic view of the light source distribution of the mirror provided by the present invention;

fig. 5 is a schematic view of the connection between the wire passing structure of the mirror and the lamp source circuit provided by the present invention;

fig. 6 is a schematic structural view of a wire passing structure of a mirror provided by the present invention;

fig. 7 is a schematic cross-sectional view of the wire passing structure of the mirror according to the present invention;

fig. 8 is an electrode schematic view of a wire-passing structure of a mirror provided by the present invention;

fig. 9 is a schematic view illustrating the connection between the conductor of the wire passing structure and the lead wire of the mirror according to the present invention;

description of the reference numerals

1, a turnover mirror, 2 a frame and 3 a supporting seat;

the LED lamp comprises a lens 11, a shell 12, a lamp source 13, a driving mechanism 14, a wire passing structure 15 and a wire 16; column 31, adjusting button 32;

151 rotating shaft, 1511 through groove, 152 fixed block, 1521 slot, 153 first conductor, 154 second conductor, 155 first electrode piece, 156 second electrode piece.

Detailed Description

The following describes the present invention with reference to the accompanying drawings.

As shown in fig. 1 to 9, the present embodiment provides a mirror with a wire passing structure, the mirror includes a turning mirror 1, a frame 2, and a supporting seat 3, the turning mirror 1 is connected to the frame 2 through a rotating shaft, the turning mirror 1 includes a lens 11 and a housing 12; a cavity for accommodating the wire passing structure is formed between the lens 11 and the shell 12; a driving mechanism 14 is arranged in the cavity, an output shaft of the driving mechanism is connected with the frame 2 and is relatively fixed with the frame 2, and the output shaft of the driving mechanism is a rotating shaft at one side of the turnover mirror 1 and the frame 2;

a wire passing structure 15 is arranged in the cavity, and the wire passing structure 15 and the driving mechanism 14 are respectively and fixedly connected with two sides of the rotation axis of the shell;

the wire passing structure 15 comprises a rotating shaft 151 connected with the frame 2 and a fixed block 152 connected with the rotating shaft 151, a through groove 1511 is axially arranged on the rotating shaft 151, one end of the first conductor 153 passes through the through groove 1511 to be fixedly connected with the fixed block 152, and the other end of the first conductor 153 is connected with the first electrode plate 155; one end portion of the first conductor 153 connected to the fixing block 152 is exposed so that the lead 16 is connected to the first conductor 153; the shaft 151 is wrapped with a conductive material to form the second conductor 154. The first conductor 153 and the second conductor 154 are connected to the first electrode sheet 155 and the second electrode sheet 156, respectively; the first electrode sheet 155 and the second electrode sheet 156 are respectively connected with the positive electrode and the negative electrode of the circuit in the frame 2; the first conductor 153 and the second conductor 154 are connected to the positive and negative poles of the driving mechanism 14 through the wires 16, so that the circuit is connected to the driving mechanism 14.

When the driving mechanism 14 drives the frame 2 to rotate, the housing 12 drives the wire passing structure 15 to rotate synchronously, so that the driving mechanism 14, the wire passing structure 15 and the lead 16 connected with the wire passing structure rotate synchronously.

Specifically, the line passing structure 15 is disposed in the mirror, the line passing structure 15 includes a first conductor 153 and a second conductor 154 that are isolated from each other, the line passing structure 15 and the driving mechanism 14 are disposed on two sides of the rotation axis of the housing 12, and the line passing structure 15 and the driving mechanism 14 are connected by the lead 16, so that the circuit of the driving mechanism 14 is connected. Meanwhile, the output shaft of the driving mechanism is connected with the frame 2, when the frame is driven to rotate, the shell 12 and the wire passing structure 15 which are connected with the frame 2 synchronously rotate, at the moment, the driving mechanism 14 fixed on the shell also synchronously rotates, and a wire connecting the driving mechanism and the wire passing structure does not wind along with the rotation; when the conducting wire is conducted, the problem of winding of the passing wire during turning is solved. Because the space of the cavity in the mirror is limited, if two driving mechanisms are respectively arranged on two sides of the shell, the cost is increased by the two driving mechanisms; meanwhile, the two driving mechanisms are controlled to synchronously rotate, so that the wire cannot be wound; however, the synchronous control of the driving mechanism is very difficult, which increases the difficulty of circuit control design. Therefore, the threading structure of the technical scheme can solve the problem.

Specifically, the driving mechanism 14 is fixed on the housing 13, and can drive the driving mechanism 14 to turn over simultaneously, which is favorable for the stability of fixing the driving mechanism 14. The shaft 151 is provided with a through groove 1511 for connecting the first conductor 153 with a conducting wire through the through groove 1511, and the outer circumference of the shaft 151 is wrapped with a conductive material to form the second conductor 154, which realizes the isolation of the first conductor 153 from the second conductor 154 and can be used for conducting current with different polarities. The fixing block 152 may fix one end of the first conductor 153 passing through the through groove 1511, and suspend the other end thereof to wind or connect the first electrode sheet 155. In addition, the fixing block 152 may also facilitate fixing of the wire, so that the connection of the wire and the first conductor 153 is more stable.

The fixing block 152 is provided with a slot 1521 for inserting and connecting the first conductor 153. The design of the slot 1521 enables the first conductor 153 to be better fixed on the fixing block, and simultaneously, the first conductor 153 is partially exposed to realize connection with a lead, so that the lead can enter the slot 1521 to be connected with the first conductor 153.

In this embodiment, the first electrode plate 155 and the second electrode plate 156 both adopt springs, one end of the first electrode plate 155 is fixedly connected to the first conductor 153, and after winding around the periphery of the first conductor 153, the other end is connected to the positive electrode or the negative electrode of the circuit in the housing 12; one end of the second electrode plate 156 is connected to the second conductor 154 on the rotating shaft 151, and after winding around the second conductor 154, the other end is connected to the negative electrode or the positive electrode of the circuit in the housing 12. The spring has certain elasticity and can conduct electricity. The elasticity of the spring provides some cushioning during rotation of the housing 12 and also provides electrical conductivity to allow electrical circuitry within the frame 2 to be connected to the drive mechanism 14.

The mirror also comprises a light source 13, and the light source 13 is arranged in the frame 2 and irradiates towards the front of the lens 11; the circuit comprises a light source 13. The street light source 13 is disposed within the frame 2 on the peripheral side of the wire passing structure 15.

Specifically, because the luminous mirror generally can set up round lamp source 13 in casing 12, the material through casing 12 chooses the light-permeable material for use, makes the light of lamp source 13 see through, realizes the light filling. A circle of light sources are adopted to form a road of light sources, and the light sources are connected with the electrode plates to realize the conduction of the circuit.

In this embodiment, the drive mechanism employs a brush motor. The supporting seat 3 comprises a column 31, an adjusting button 32 is arranged on the column 31, and the adjusting button 32 is connected with a circuit so that the adjusting button controls the driving mechanism 14 to be opened and closed. Specifically, the operation of the driving mechanism 14 needs to be realized by controlling the opening and closing thereof; the button is arranged on the supporting seat 3, so that a user can select whether to turn the mirror through electric driving or directly and manually push the mirror to turn the mirror according to requirements. When the mirror is pushed to turn manually, the wire passing structure is arranged, so that the wire inside the mirror cannot be wound and the like.

Variations and modifications to the above-described embodiments may occur to those skilled in the art, in light of the above teachings and teachings. Therefore, the present invention is not limited to the specific embodiments disclosed and described above, and some modifications and changes to the present invention should fall within the protection scope of the claims of the present invention. Furthermore, although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.

Claims (8)

1. A mirror with a wire passing structure comprises a turnover mirror and a peripheral frame, wherein the turnover mirror is connected with the frame through a rotating shaft and comprises a mirror lens and a shell; the lens is characterized in that a cavity for accommodating the wire passing structure is formed between the lens and the shell;

a wire passing structure is arranged in the cavity, is positioned on the rotating axis of the shell and is fixedly connected with the shell;

the wire passing structure comprises a first conductor and a second conductor which are isolated from each other, and the first conductor and the second conductor are respectively connected with the first electrode plate and the second electrode plate; the first electrode plate and the second electrode plate are respectively connected with the positive electrode and the negative electrode of a circuit positioned in the frame;

the first conductor and the second conductor are connected with the positive electrode and the negative electrode of the power supply through leads so as to connect a circuit.

2. The mirror as claimed in claim 1, wherein said wire passing structure includes a rotating shaft connected to the frame, and a fixing block connected to the rotating shaft; a through groove is axially arranged on the rotating shaft, and one end of the first conductor penetrates through the through groove and is partially exposed so as to form connection between a lead and the first conductor; the other end of the first conductor is connected with the first electrode plate;

the rotating shaft is wrapped with a conductive material to form the second conductor.

3. A mirror according to claim 2, wherein the first conductor is secured to the anchor block by a tight fit.

4. The mirror as claimed in claim 2, wherein said first and second electrode sheets comprise resilient electrode sheets.

5. The mirror according to claim 4, wherein said flexible electrode sheet is in contact with and movable relative to said first and second conductors.

6. The mirror as claimed in claim 5, wherein said flexible electrode tabs are connected to an external power source.

7. The mirror as claimed in claim 2, further comprising a light source disposed within the frame and shining in front of the lens.

8. The mirror according to claim 1, further comprising a post connected to the frame, the post having an adjustment button thereon, the adjustment button being connected to the electrical circuit such that the adjustment button controls the drive mechanism to open and close.

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