CN215632660U - Connecting structure of hollow louver controller and guide rail - Google Patents

Abstract

A connecting structure of a hollow louver controller and a guide rail relates to the technical field of hollow louvers. It comprises glass, a controller and a guide rail; the guide rail is arranged on the upper surface of the glass; the connection relation between the controller and the guide rail is rolling connection; the controller comprises a controller body, a roller and a shaft pin; the side part of the controller body is provided with two connecting blocks; the roller is arranged in the connecting block through a shaft pin and penetrates through two sides of the connecting block; wherein, the roller is hinged with the connecting block; the guide rail is internally provided with a guide chute, and then the connecting block and the roller are embedded in the guide chute. The novel electric car is simple in structure, the controller and the guide rail are in rolling connection, friction between the controller and the guide rail is reduced, noise is low, movement is smoother, and use experience is improved; meanwhile, the service life is prolonged, and resources are saved.

Description

Connecting structure of hollow louver controller and guide rail

Technical Field

The utility model relates to the technical field of hollow shutters, in particular to an improvement of a connecting structure of a hollow shutter controller and a guide rail.

Background

A hollow glass system with built-in shutters is called as hollow shutters for short, and is a novel energy-saving product for mounting the shutters in hollow glass. The traditional venetian blind and the hollow glass are combined into a whole, so that the using space and inconvenience are saved, and the heat preservation and the comprehensive performance of the venetian blind are realized. The hollow louver has the functions of lifting the louver and turning 180 degrees, and the closing device and the lifting device are manually or electrically controlled, so that the operation control of the louver is realized. The hollow shutter can realize the lifting and turning of the shutter, and has reasonable structure and simple and convenient operation. The hollow glass has good sun-shading performance, improves the heat-insulating performance of the hollow glass, improves the indoor light environment, and is widely suitable for energy-saving building doors and windows. When curtain wall glass and building doors and windows are designed, certain requirements are placed on performance parameters of the hollow glass, such as visible light transmittance, shading coefficient, heat transfer coefficient, dew point and the like. In order to improve the energy-saving effect of the hollow glass, people select different types of coated glass and colored glass to synthesize the hollow glass. The glass original sheets and the structures of the hollow glass are different, and the energy-saving performance of the product is different.

The existing hollow louver controller is connected with the guide rail in a sliding way, and the sliding contact area between the hollow louver controller and the guide rail is large, so that the friction force between the hollow louver controller and the guide rail is large; after the novel shoe pad is used for a period of time, abnormal sound is accompanied, the novel shoe pad is not smooth to move, the hand feeling is very high, the use experience is poor, and meanwhile, the service life is also short.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a connecting structure of a hollow louver controller and a guide rail, aiming at the defects and shortcomings of the prior art. The novel electric car is simple in structure, the controller and the guide rail are in rolling connection, friction between the controller and the guide rail is reduced, noise is low, movement is smoother, and use experience is improved; meanwhile, the service life is prolonged, and resources are saved.

In order to achieve the purpose, the utility model adopts the following technical scheme: it comprises glass 1, a controller 2 and a guide rail 3; the guide rail 3 is arranged on the upper surface of the glass 1; the connection relation between the controller 2 and the guide rail 3 is rolling connection; the controller 2 comprises a controller body 21, a roller 22 and a shaft pin 23; the side of the controller body 21 is provided with two connecting blocks 211; the roller 22 is arranged inside the connecting block 211 through a shaft pin 23, and the roller 22 penetrates through two sides of the connecting block 211; wherein, the roller 22 is hinged with the connecting block 211; the guide rail 3 is internally provided with a guide sliding groove 31, and the connecting block 211 and the roller 22 are embedded in the guide sliding groove 31.

Further, the guide chute 31 includes a side chute 311 and an upper chute 312; the structure of the side slide groove 311 matches the structure of the roller 22, and a gap exists between the upper slide groove 312 and the connecting block 211.

Further, a gap exists between the connecting block 211 and the guide sliding groove 31, and the connecting block 211 is embedded in the guide sliding groove 31 through the roller 22.

Further, the side of the connecting block 211 is provided with an open slot 211a, and the roller 22 is transversely arranged in the open slot 211 a; and there is a gap between the roller 22 and the open groove 211 a.

Further, the rollers 22 are rolling rollers.

The working principle of the utility model is as follows: the controller 2 is further connected with the guide rail 3 in a rolling way through a roller 22, and the roller 22 is embedded in the side sliding groove 311; the rollers 22 are restricted by the side slide grooves 311, and the controller 2 is ensured to move along the track of the guide rail 3.

After the technical scheme is adopted, the utility model has the beneficial effects that: the controller is in rolling connection with the guide rail, so that friction force between the controller and the guide rail is reduced, friction noise between the controller and the guide rail is reduced, the controller and the guide rail move smoothly, and use experience of a user is improved; meanwhile, the service life of the controller and the guide rail is prolonged, and resources are saved.

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 only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged view of the structure corresponding to part A of FIG. 1;

FIG. 3 is an enlarged view of the structure of the controller 2 according to the present invention;

fig. 4 is an enlarged schematic view of the structure of the guide rail 3 in the present invention;

fig. 5 is a top view corresponding to fig. 1.

Description of reference numerals: glass 1, controller 2, controller body 21, connecting block 211, open slot 211a, roller 22, pivot pin 23, guide rail 3, guide runner 31, side runner 311, upper runner 312.

Detailed Description

Referring to fig. 1 to 5, the technical solution adopted by the present embodiment is: it comprises glass 1, a controller 2 and a guide rail 3; the guide rail 3 is arranged on the upper surface of the glass 1; the connection relation between the controller 2 and the guide rail 3 is rolling connection; the controller 2 comprises a controller body 21, a roller 22 and a shaft pin 23; the side of the controller body 21 is provided with two connecting blocks 211; the roller 22 is arranged inside the connecting block 211 through a shaft pin 23, and the roller 22 penetrates through two sides of the connecting block 211; wherein, the roller 22 is hinged with the connecting block 211; the guide rail 3 is internally provided with a guide sliding groove 31, and the connecting block 211 and the roller 22 are embedded in the guide sliding groove 31.

Further, the guide chute 31 includes a side chute 311 and an upper chute 312; the structure of the side slide groove 311 matches the structure of the roller 22, and a gap exists between the upper slide groove 312 and the connecting block 211. The roller 22 is matched with the side groove 311, so that the roller 22 can smoothly roll in the side groove 311; meanwhile, the upper chute 312 is not in contact with the connecting block 211, which effectively reduces the friction between the connecting block 211 and the guide rail 3.

Further, a gap exists between the connecting block 211 and the guide sliding groove 31, and the connecting block 211 is embedded in the guide sliding groove 31 through the roller 22. The connecting block 211 is not in direct contact with the guide chute 31, thereby reducing the friction between the connecting block 211 and the guide rail 3.

Further, the side of the connecting block 211 is provided with an open slot 211a, and the roller 22 is transversely arranged in the open slot 211 a; and a gap exists between the roller 22 and the open groove 211 a; the phenomenon that the roller 22 interferes with a connecting block in the rotating process to influence the rotation of the roller 22, so that the controller 2 and the guide rail 3 cannot move smoothly to influence the use is avoided.

Further, the rollers 22 are rolling rollers. The rolling roller has good wear resistance, and can prolong the service life of the roller 22, thereby prolonging the service life of the whole structure.

The working principle of the utility model is as follows: the controller 2 is further connected with the guide rail 3 in a rolling way through a roller 22, and the roller 22 is embedded in the side sliding groove 311; the rollers 22 are restricted by the side slide grooves 311, and the controller 2 is ensured to move along the track of the guide rail 3.

After the technical scheme is adopted, the utility model has the beneficial effects that: the controller is in rolling connection with the guide rail, so that friction force between the controller and the guide rail is reduced, friction noise between the controller and the guide rail is reduced, the controller and the guide rail move smoothly, and use experience of a user is improved; meanwhile, the service life of the controller and the guide rail is prolonged, and resources are saved.

The above description is only for the purpose of illustrating the technical solutions of the present invention and not for the purpose of limiting the same, and other modifications or equivalent substitutions made by those skilled in the art to the technical solutions of the present invention should be covered within the scope of the claims of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims (5)

1. A connection structure of cavity louver controller and guide rail which characterized in that: the glass comprises glass (1), a controller (2) and a guide rail (3); the guide rail (3) is arranged on the upper surface of the glass (1); the connection relation between the controller (2) and the guide rail (3) is rolling connection; the controller (2) comprises a controller body (21), a roller (22) and a shaft pin (23); two connecting blocks (211) are arranged on the side part of the controller body (21); the roller (22) is arranged inside the connecting block (211) through a shaft pin (23), and the roller (22) penetrates through two sides of the connecting block (211); wherein, the roller (22) is hinged with the connecting block (211); the guide rail (3) is internally provided with a guide sliding groove (31), and then the connecting block (211) and the roller (22) are embedded in the guide sliding groove (31).

2. The connecting structure of the hollow louver controller and the guide rail according to claim 1, wherein: the guide sliding groove (31) comprises a side sliding groove (311) and an upper sliding groove (312); the structure of the side sliding groove (311) is matched with that of the roller (22), and a gap exists between the upper sliding groove (312) and the connecting block (211).

3. The connecting structure of the hollow louver controller and the guide rail according to claim 1, wherein: a gap exists between the connecting block (211) and the guide sliding groove (31), and the connecting block (211) is embedded in the guide sliding groove (31) through the roller (22).

4. The connecting structure of the hollow louver controller and the guide rail according to claim 1, wherein: an open groove (211a) is formed in the side of the connecting block (211), and the roller (22) is transversely arranged in the open groove (211 a); and a gap is formed between the roller (22) and the open groove (211 a).

5. The connecting structure of the hollow louver controller and the guide rail according to claim 1, wherein: the rollers (22) are rolling rollers.

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