阅读说明：本技术 一种磁性旋转式动力机构 (Magnetic rotary power mechanism ) 是由 赵辉 赵禹朔 赵禹翰 于 2021-09-30 设计创作，主要内容包括：本发明涉及中空玻璃技术领域,尤其是涉及一种磁性旋转式动力机构,包括：转子和磁体；所述转子为可自转的旋转体结构；所述转子第一侧的端面设置有若干个永磁仓；所述转子第二侧的端面中心设置有用于与传动机构连接的连接端；所述磁体装配于所述转子的永磁仓中。本发明磁性旋转式动力机构可应用于内置遮阳中空玻璃中,利用磁力透过玻璃实现旋转动作,进而可完成中空玻璃内的提线放线,叶片翻转等动作。本发明结构简单,操作方便,中空玻璃内部仅是机械结构,运行稳定,故障率低。(The invention relates to the technical field of hollow glass, in particular to a magnetic rotary power mechanism, which comprises: a rotor and a magnet; the rotor is a rotatable rotator structure; the end face of the first side of the rotor is provided with a plurality of permanent magnet bins; the center of the end surface of the second side of the rotor is provided with a connecting end used for being connected with a transmission mechanism; the magnets are assembled in the permanent magnet bins of the rotor. The magnetic rotary power mechanism can be applied to the built-in sunshade hollow glass, and can realize the rotary action through the glass by utilizing the magnetic force, thereby completing the actions of wire lifting and paying off, blade overturning and the like in the hollow glass. The invention has simple structure, convenient operation, stable operation and low failure rate, and the hollow glass is only of a mechanical structure inside.)

1. A magnetic rotary power mechanism, comprising: a rotor and a magnet;

the rotor is a rotatable rotator structure;

the end face of the first side of the rotor is provided with a plurality of permanent magnet bins; the center of the end surface of the second side of the rotor is provided with a connecting end used for being connected with a transmission mechanism;

the magnets are assembled in the permanent magnet bins of the rotor.

2. The magnetic rotary power mechanism of claim 1, wherein the rotor comprises: a rotor housing and a baffle;

the rotor shell is in a hollow cylindrical shape;

the end surface of the first side of the rotor shell is open, the baffle plate is arranged on the first side of the rotor shell and divides the rotor shell into a plurality of permanent magnet bins in equal parts;

the end face of the second side of the rotor shell is closed, and a connecting end used for being connected with the transmission mechanism is arranged in the center of the end face of the second side of the rotor shell.

3. The magnetic rotary power mechanism of claim 2, further comprising: a power input housing;

the rotor is rotatably mounted in the power input housing;

the magnet on the first side of the rotor is exposed out of the power input shell;

the connecting end of the second side of the rotor is positioned in the power input shell and is connected with a transmission mechanism in the power input shell.

4. The magnetic rotary power mechanism of claim 2, wherein the connection end of the second side of the rotor is connected to a transmission mechanism.

5. The magnetic rotary power mechanism of claim 2, wherein the connection end of the second side of the rotor is connected to both of the two transmission mechanisms.

6. The magnetic rotary power mechanism of claim 1,

when the transmission mechanism is a gear transmission mechanism, the connecting end of the rotor shell is a gear matched with the gear transmission mechanism.

7. The magnetic rotary power mechanism of claim 1,

when the transmission mechanism is a belt transmission mechanism, the connecting end of the rotor shell is a belt pulley matched with the belt transmission mechanism.

8. The magnetic rotary power mechanism of claim 1,

when the transmission mechanism is a gear-belt combined transmission mechanism, the connecting end of the rotor shell is a gear or a belt pulley which is matched with the gear-belt combined transmission mechanism.

9. The magnetic rotary power mechanism of claim 1,

when the transmission mechanism is a shaft transmission structure, the connecting end of the rotor shell is a shaft sleeve or a shaft hole matched with the shaft transmission structure.

Technical Field

The invention relates to the technical field of hollow glass, in particular to a magnetic rotary power mechanism.

Background

The built-in sunshade hollow glass has the characteristics of heat preservation and sound insulation of common hollow glass and convenient dimming of a shutter curtain, has the advantages of attractive appearance, elegance, convenient operation, cleanness, sanitation and space saving, and is widely applied at home and abroad. The common built-in sunshade hollow glass consists of inner glass, outer glass, a frame, a blind blade, a blade adjusting mechanism consisting of a blade lifting mechanism and a blade overturning mechanism and the like. At present, a blade adjusting mechanism with built-in sunshade hollow glass usually needs a complex driving device to realize blade turning and wire pulling actions. The driving device is generally arranged on one side or two sides of the hollow glass, and the operation is troublesome. Moreover, the hollow glass also needs to be additionally provided with the tracks on one side or two sides of the glass correspondingly, so that the daylighting area is reduced, and the hollow glass is not attractive.

The information disclosed in this background section is only for enhancement of understanding of the general background of the invention and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art already known to a person skilled in the art.

Disclosure of Invention

The invention aims to provide a magnetic rotary power mechanism which can be applied to built-in sunshade hollow glass to solve the technical problems in the prior art.

In order to achieve the purpose, the invention adopts the following technical scheme:

the invention provides a magnetic rotary power mechanism, which comprises: a rotor and a magnet; the rotor is a rotatable rotator structure; the end face of the first side of the rotor is provided with a plurality of permanent magnet bins; the center of the end surface of the second side of the rotor is provided with a connecting end used for being connected with a transmission mechanism; the magnets are assembled in the permanent magnet bins of the rotor.

Preferably, the rotor includes: a rotor housing and a baffle; the rotor shell is in a hollow cylindrical shape; the end surface of the first side of the rotor shell is open, the baffle plate is arranged on the first side of the rotor shell and divides the rotor shell into a plurality of permanent magnet bins in equal parts; the end face of the second side of the rotor shell is closed, and a connecting end used for being connected with the transmission mechanism is arranged in the center of the end face of the second side of the rotor shell.

Preferably, the magnetic rotary power mechanism further comprises: a power input housing; the rotor is rotatably mounted in the power input housing; the magnet on the first side of the rotor is exposed out of the power input shell; the connecting end of the second side of the rotor is positioned in the power input shell and is connected with a transmission mechanism in the power input shell.

Preferably, the connection end of the second side of the rotor is connected to a transmission mechanism.

Preferably, the connection end of the second side of the rotor is connected to both transmission mechanisms.

Preferably, when the transmission mechanism is a gear transmission mechanism, the connecting end of the rotor housing is a gear matched with the gear transmission mechanism.

Preferably, when the transmission mechanism is a belt transmission mechanism, the connecting end of the rotor housing is a belt pulley adapted to the belt transmission mechanism.

Preferably, when the transmission mechanism is a combined gear and belt transmission mechanism, the connecting end of the rotor housing is a gear or a belt pulley adapted to the combined gear and belt transmission mechanism.

Preferably, when the transmission mechanism is a shaft transmission structure, the connection end of the rotor housing is a shaft sleeve or a shaft hole matched with the shaft transmission structure.

By adopting the technical scheme, the invention has the following beneficial effects:

the magnetic rotary power mechanism can be applied to the built-in sunshade hollow glass, and can realize the rotary action through the glass by utilizing the magnetic force, thereby completing the actions of wire lifting and paying off, blade overturning and the like in the hollow glass. The invention has simple structure, convenient operation, stable operation and low failure rate, and the hollow glass is only of a mechanical structure inside.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a front view of a magnetic rotary power mechanism according to an embodiment of the present invention;

fig. 2 is a perspective view of a magnetic rotary power mechanism according to an embodiment of the present invention;

fig. 3 is a schematic view illustrating a usage status of the magnetic rotary power mechanism according to the embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a power input portion provided in an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a power output portion provided in an embodiment of the present invention.

Icon: 101-a rotor; 102-a magnet; 103-hollow glass.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The following detailed description of embodiments of the invention refers to the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the present invention, are given by way of illustration and explanation only, not limitation.

Example one

Referring to fig. 1 to 5, the present embodiment provides a magnetic rotary power mechanism, which includes: a rotor 101 and a magnet 102; the rotor 101 has a rotatable rotor structure; the end face of the first side of the rotor 101 is provided with a plurality of permanent magnet bins; the center of the end surface of the second side of the rotor 101 is provided with a connecting end used for being connected with a transmission mechanism; the magnets 102 are fitted in permanent magnet pockets of the rotor 101.

Preferably, the rotor 101 includes: a rotor housing and a baffle; the rotor shell is in a hollow cylindrical shape; the end surface of the first side of the rotor shell is open, the baffle plate is arranged on the first side of the rotor shell and divides the rotor shell into a plurality of permanent magnet bins in equal parts; the end face of the second side of the rotor shell is closed, and a connecting end used for being connected with the transmission mechanism is arranged in the center of the end face of the second side of the rotor shell.

Preferably, the magnetic rotary power mechanism further comprises: a power input housing; the rotor 101 is rotatably mounted in the power input housing; the magnet 102 on the first side of the rotor 101 is exposed to the power input housing; the connection end of the second side of the rotor 101 is located inside the power input housing and is connected to the transmission mechanism in the power input housing.

Preferably, the connection end of the second side of the rotor 101 is connected to a transmission mechanism.

Preferably, the connection end of the second side of the rotor 101 is connected to both transmission mechanisms.

Preferably, when the transmission mechanism is a gear transmission mechanism, the connecting end of the rotor housing is a gear matched with the gear transmission mechanism.

In this embodiment, preferably, the gear transmission mechanism includes: a plurality of meshed gears; all or part of the gears are arranged in parallel with the hollow glass. Of course, the number of gears and the transmission ratio can be varied and can be flexibly adjusted by those skilled in the art according to the actual situation.

The following is exemplified in one of the specific forms:

the plurality of meshed gears includes: a reduction gear, an intermediate gear, a spool gear set and a direction change gear set; the large gear of the reduction gear is meshed with the gear on the second side of the rotor; the pinion of the reduction gear is meshed with the intermediate gear; the intermediate gear is meshed with a gear of the spool gear set; the spools of the spool gear set are connected with the hollow glass blade cords to realize the cord lifting action; the gear of the spool gear set is meshed with the gear of the direction conversion gear set; the direction conversion gear set is connected with the blade turnover mechanism of the hollow glass through the connecting shaft, and the direction conversion gear set drives the connecting shaft to rotate by changing the rotating direction, so that the blade turnover mechanism is driven to turn over, and the light entering amount is adjusted.

Preferably, when the transmission mechanism is a belt transmission mechanism, the connecting end of the rotor housing is a belt pulley adapted to the belt transmission mechanism.

Preferably, when the transmission mechanism is a combined gear and belt transmission mechanism, the connecting end of the rotor housing is a gear or a belt pulley adapted to the combined gear and belt transmission mechanism.

Preferably, when the transmission mechanism is a shaft transmission structure, the connection end of the rotor housing is a shaft sleeve or a shaft hole matched with the shaft transmission structure.

In conclusion, the magnetic rotary power mechanism can be applied to the built-in sunshade hollow glass, and can realize the rotation action through the glass by utilizing the magnetic force, thereby completing the actions of wire lifting and paying off, blade overturning and the like in the hollow glass. The invention has simple structure, convenient operation, stable operation and low failure rate, and the hollow glass is only of a mechanical structure inside.

Example two

The second embodiment provides a power input part with a built-in sunshade hollow glass, and a magnetic rotary power mechanism is adopted. The embodiment is another technical solution on the basis of the first embodiment, the technical features disclosed in the first embodiment are also applicable to the embodiment, and the technical features disclosed in the first embodiment are not described repeatedly.

Specifically, the power input portion includes: the power input shell, the first magnetic rotary power mechanism and the transmission mechanism are arranged in the shell; the first magnetic rotary power mechanism comprises: a rotor 101 and a magnet 102; the rotor 101 is rotatably mounted in the power input housing; the magnets 102 are assembled in permanent magnet bins of the rotor 101; the magnet 102 on the first side of the rotor 101 is exposed to the power input housing; the connection end of the second side of the rotor 101 is located inside the power input housing and is connected to the transmission mechanism in the power input housing.

Preferably, the connection end of the second side of the rotor 101 is a gear. Correspondingly, the gear mechanism is likewise a gear mechanism. In addition, the gear of the rotor 101 may be simultaneously connected to one gear transmission mechanism, or may be simultaneously engaged with two gear transmission mechanisms.

Each gear transmission mechanism comprises: a reduction gear, an intermediate gear, a spool gear set and a direction change gear set; the large gear of the reduction gear is meshed with the gear on the second side of the rotor; the pinion of the reduction gear is meshed with the intermediate gear; the intermediate gear is meshed with a gear of the spool gear set; the spools of the spool gear set are connected with the hollow glass blade cords to realize the cord lifting action; the gear of the spool gear set is meshed with the gear of the direction conversion gear set; the direction conversion gear set is connected with the blade turnover mechanism of the hollow glass through the connecting shaft, and the direction conversion gear set drives the connecting shaft to rotate by changing the rotating direction, so that the blade turnover mechanism is driven to turn over, and the light entering amount is adjusted.

EXAMPLE III

The third embodiment provides a power output part with a built-in sunshade hollow glass, and a magnetic rotary power mechanism is adopted. The embodiment is another technical solution on the basis of the first embodiment, the technical features disclosed in the first embodiment are also applicable to the embodiment, and the technical features disclosed in the first embodiment are not described repeatedly.

Preferably, the power output portion includes: the second magnetic rotary power mechanism, the telescopic mechanism and the driving mechanism; the second magnetic rotary power mechanism comprises: a rotor 101 and a magnet 102; the magnets 102 are assembled in permanent magnet bins of the rotor 101; the end face of the first side of the rotor 101 is provided with a plurality of permanent magnet bins; the center of the end surface of the second side of the rotor 101 is provided with a connecting end for connecting with a driving mechanism; the driving mechanism is connected with the telescopic mechanism.

The magnet 102 of the first magnetic rotary power mechanism and the magnet 102 of the second magnetic rotary power mechanism interact with each other through glass, so that the rotation of the rotor 101 of the first magnetic rotary power mechanism is realized.

In this embodiment, the telescopic mechanism includes: any one of an electric telescopic rod, a pneumatic telescopic rod or a manual telescopic rod. Telescopic link design is adopted to telescopic machanism, and it is more convenient when the user uses, no matter high low window can both touch the hand and reach.

In the present embodiment, preferably, the driving manner of the driving mechanism includes: any one of electric, pneumatic, hydraulic or manual drive.

Preferably, the drive mechanism is a motor. Correspondingly, the driving mechanism further comprises: a battery compartment and a battery; the battery is responsible for providing energy to the motor. The battery compartment is used for placing batteries. The motor rotates to drive the rotor 101 to rotate, and the magnetic force acts on the rotor 101 of the power input part through the glass, so that the power input part is driven to rotate. The working principle is as follows: the power output part enables the motor to rotate through electric energy, then the magnet magnetically penetrates through the glass to act on the magnet inside the hollow glass, so that the gear of the power input part is driven to rotate, and finally the spool is driven to realize the actions of pulling and paying off the cord. And the power direction is converted by the direction conversion gear group so as to realize the rotation of the shaft, thereby carrying out direction adjustment on the shading blades and finally realizing the function of adjusting the daylighting amount.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.