CN109403830B

CN109403830B - Hollow glass with built-in shutter

Info

Publication number: CN109403830B
Application number: CN201811582707.2A
Authority: CN
Inventors: 李成
Original assignee: Hefei Zhenxing Insulating Glass Co ltd
Current assignee: Hefei Zhenxing Insulating Glass Co.,Ltd.
Priority date: 2018-12-24
Filing date: 2018-12-24
Publication date: 2021-03-23
Anticipated expiration: 2038-12-24
Also published as: CN109403830A

Abstract

The invention discloses hollow glass with built-in shutters, which comprises a frame and two pieces of oppositely arranged glass, wherein a sealing cavity is formed between the frame and the two pieces of oppositely arranged glass, a plurality of shutters, a rotating shaft, a shutter overturning mechanism and a shutter lifting mechanism are arranged in the sealing cavity, the rotating shaft is transversely and rotatably arranged above the shutters, the shutter overturning mechanism comprises an overturning rotating wheel, a mounting seat, an overturning ladder rope and a control assembly, the overturning rotating wheel is mounted on the mounting seat, the rotating shaft penetrates through the mounting seat and the overturning rotating wheel, one end of the overturning ladder rope is wound on the overturning rotating wheel, the overturning ladder rope is provided with a plurality of ladder openings, and the shutters respectively penetrate through the ladder openings in a one-; the invention has the advantages of accurate control of the rotation of the rotating shaft, low manufacturing cost, convenient operation, small resistance when the magnetic handle moves and labor saving.

Description

Hollow glass with built-in shutter

Technical Field

The invention relates to the technical field of doors and windows, in particular to hollow glass with built-in blinds.

Background

Glass with built-in louvers, namely two layers of glass are connected through a frame, the louvers are arranged in a cavity between the two layers of glass and the frame, and a device for adjusting the louvers to turn over and lift is arranged in the cavity.

The turning and lifting structure of the louver in the existing glass with the built-in louver comprises a ladder rope, a rotating shaft, a plurality of rotating wheels and a pull rope assembly, wherein the ladder rope is connected with the louver, the rotating wheels are sleeved and fixed on the rotating shaft, the pull rope assembly is used for controlling the rotating shaft to rotate, and the like. The existing pull rope assembly comprises an inner overturning magnetic handle, a pull rope, a pulley mechanism and a rotating wheel fixed at one end of a rotating shaft, wherein the pull rope is connected with the top of the inner overturning magnetic handle, then penetrates through the rotating wheel upwards, then penetrates through the pulley mechanism downwards, and then is connected with the bottom of the inner overturning magnetic handle upwards to form a closed loop. However, because the contact surface between the pull rope and the rotating wheel is small, the friction force is small, the rotation of the rotating shaft cannot be accurately controlled, and the rotating wheel and the pull rope are replaced by a gear and a belt with teeth on one end face, but the gear dislocation of the belt is easy to occur due to thermal expansion and cold contraction, the rotation of the rotating shaft cannot be accurately controlled, and the manufacturing cost is high; the lifting and turning of the louver in the existing glass with the louver inside is mainly realized through a magnetic attraction mechanism, the lifting and turning of the louver in the existing glass with the louver inside is realized through the magnetic attraction mechanism, the magnetic attraction mechanism comprises an internal magnetic mechanism and an external magnetic control mechanism, the external magnetic control mechanism comprises a magnetic handle with a plurality of magnet blocks and a guide rail, one side of the magnetic handle extends into the guide rail to enable the magnetic handle to move along the guide rail, and when the magnetic handle moves, because great friction force exists between the upper end face of the magnetic handle and the glass, and between the side face of the magnetic handle and the guide rail, the magnetic handle is pushed to move with small resistance and great effort; in addition, the existing external magnetic handles are all placed on the side parts of the hollow glass (particularly the external magnetic handles for controlling the lifting of the shutters), certain requirements are imposed on the height of an operator, and the adjustment is inconvenient. It is necessary to propose new solutions.

Disclosure of Invention

The invention provides hollow glass with built-in louvers, which solves the problems of incapability of accurately controlling the rotation of a rotating shaft, high manufacturing cost and inconvenience in adjustment in the prior art.

In order to achieve the purpose, the technical scheme of the invention is realized as follows: the built-in shutter hollow glass comprises a frame and two pieces of glass arranged oppositely, a sealing cavity is formed between the frame and the two pieces of glass arranged oppositely, a plurality of shutters, a rotating shaft, a shutter overturning mechanism and a shutter lifting mechanism are arranged in the sealing cavity, the rotating shaft is transversely and rotatably arranged above the shutters, the shutter overturning mechanism comprises an overturning rotating wheel, a mounting seat, an overturning ladder rope and a control assembly, the overturning rotating wheel is mounted on the mounting seat, the rotating shaft penetrates through the mounting seat and the overturning rotating wheel, one end of the overturning ladder rope is wound on the overturning rotating wheel, the overturning ladder rope is provided with a plurality of ladder openings, and the shutters respectively penetrate through the ladder openings in a one-to-one correspondence manner;

the control assembly comprises a control rotating wheel, a control ladder rope, a first pull rope, a second pull rope, an inner overturning magnetic handle and a pulley mechanism arranged on the lower side of the frame, the control rotating wheel is fixed at one end of a rotating shaft, the control rotating wheel is provided with a plurality of gear structures matched with the control ladder rope, one end of the control ladder rope is connected with one end of the first pull rope, the other end of the control ladder rope penetrates through the control rotating wheel and then is connected with one end of the second pull rope, the other end of the second pull rope penetrates through the pulley mechanism and then is connected with the bottom of the inner overturning magnetic handle, and the other end of the first pull rope is connected with the top of the inner overturning magnetic handle;

the louver lifting mechanism comprises a turning rotating wheel, a lifting stay cord, a corner pulley and an inner lifting magnetic handle, the corner pulley is arranged at the corner of the frame right below the control rotating wheel, the inner lifting magnetic handle is positioned below the plurality of louvers and transversely moves along the bottom of the frame, one end of the lifting stay cord penetrates through the plurality of louvers and is connected with the louver at the lowest end, and the other end of the lifting stay cord penetrates through the mounting seat and then bypasses the corner pulley and is connected with the inner lifting magnetic handle;

the magnetic sealing device is characterized by further comprising two groups of external magnetic control mechanisms which are respectively matched with the inner overturning magnetic handle and the inner lifting magnetic handle, wherein the two groups of external magnetic control mechanisms are arranged on the outer side of the sealing cavity, each external magnetic control mechanism comprises a guide rail, a first limiting block, a second limiting block and an outer magnetic handle, the first limiting blocks and the second limiting blocks are respectively arranged in the guide rails, the first limiting blocks and the second limiting blocks are oppositely arranged, the outer magnetic handle comprises a handle body, a sliding block and a connecting part for connecting the handle body and the sliding block, the sliding block is arranged in the guide rails in a sliding manner, a plurality of magnet blocks and a plurality of rollers are embedded and installed on the inner side end surface of the handle body, the plurality of rollers are distributed on two sides of the plurality of magnet blocks, and a plurality of balls are embedded and installed on the side end surface of the handle body opposite to the guide rails, the handle body is connected with the guide rail in a rolling mode through the plurality of rolling balls.

Preferably, the control ladder rope includes left rope, right rope and a plurality of connection the left side rope is connected with the rope of being connected of right rope, the one end of first stay cord with at least two of the one end of control ladder rope are connected the rope and are linked to each other, the one end of second stay cord with at least two of the other end of control ladder rope are connected the rope and are linked to each other.

Preferably, the gear structure extends in a thickness direction of the control runner.

Preferably, the plurality of balls are arranged in a row along a longitudinal direction of the handle body.

Preferably, the diameters of the plurality of balls are the same and are respectively larger than the distance between the upper side edge and the lower side edge of the guide rail.

Preferably, each of the plurality of balls is partially located between the upper and lower side edges of the guide rail.

Preferably, the outer magnetic handle is of an H-shaped structure.

The invention has the following advantages by adopting the scheme:

when the built-in shutter hollow glass is used, when a person pushes the outer magnetic handle, the inner overturning magnetic handle or the inner lifting magnetic handle correspondingly moves, when the inner overturning magnetic handle ascends, the second pull rope pulls the other end of the control ladder rope to move downwards, and in the process that the other end of the control ladder rope moves downwards, the control runner can rotate through the gear structure matched with the control ladder rope, and the control runner rotates to drive the rotating shaft to rotate correspondingly; when external magnetism control mechanism uses, when needs upset tripe or lift tripe, realize through removing outside magnetism handle, at the in-process that removes outer magnetism handle, the handle body converts the sliding friction between handle body and the guide rail into rolling friction through a plurality of balls, and greatly reduced frictional resistance between the two just also saves labour comparatively speaking relatively. The external magnetic handle for controlling the lifting of the louver is arranged at the bottom of the hollow glass with the louver inside, so that the adjustment is convenient. Therefore, compared with the prior art, the invention has the advantages of accurate control of the rotation of the rotating shaft, low manufacturing cost, convenient operation, small resistance when the magnetic handle moves and labor saving.

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, 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 the drawings without creative efforts.

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

FIG. 2 is a schematic structural diagram of a control assembly 9 according to the present invention;

fig. 3 is a schematic structural view of the external magnetic control mechanism 10 according to the present invention;

fig. 4 is a longitudinal sectional view of fig. 3.

In the figure: 1-frame, 2-glass, 3-tripe, 4-pivot, 5-upset runners, 6-mount pad, 7-upset ladder rope, 8-lift stay cord, 9-control assembly, 10-outside magnetism control mechanism, 11-corner pulley, 12-interior lift magnetism handle, 91-control runner, 92-control ladder rope, 93-first stay cord, 94-second stay cord, 95-interior upset magnetism handle, 96-pulley mechanism, 101-guide rail, 102-first stopper, 103-second stopper, 104-outer magnetism handle, 921-left rope, 922-right rope, 923-connection rope, 1041-handle body, 1042-slider, 1043-connecting portion, 1044-gyro wheel, 1045-ball.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without inventive effort based on the embodiments of the present invention, are within the scope of the present invention.

As shown in fig. 1, fig. 1 is a schematic structural diagram of the present invention.

The invention provides hollow glass with built-in blinds, which comprises a frame 1 and two pieces of glass 2 arranged oppositely, wherein a sealed cavity is formed between the frame 1 and the two pieces of glass 2 arranged oppositely, a plurality of blinds 3, a rotating shaft 4, a blind overturning mechanism and a blind lifting mechanism are arranged in the sealed cavity, the rotating shaft 4 is transversely and rotatably arranged above the plurality of blinds 3, the blind overturning mechanism comprises an overturning rotating wheel 5, a mounting seat 6, an overturning ladder rope 7 and a control assembly 9, the overturning rotating wheel 5 is mounted on the mounting seat 6, the rotating shaft 4 penetrates through the mounting seat 6 and the overturning rotating wheel 5, one end of the overturning ladder rope 7 is wound on the overturning rotating wheel 5, the overturning ladder rope 7 is provided with a plurality of ladder openings, the plurality of blinds 3 respectively penetrate through the plurality of ladder openings in a one-to-one correspondence.

Fig. 2 is a schematic structural diagram of the control assembly 9 of the present invention.

The control assembly 9 comprises a control runner 91, a control ladder rope 92, a first pull rope 93, a second pull rope 94, an inner turning magnetic handle 95 and a pulley mechanism 96 installed on the lower side of the frame, the control runner 91 is fixed at one end of the rotating shaft 4, a plurality of gear structures 97 matched with the control ladder rope 92 are arranged on the control runner 91, and the gear structures 97 extend along the thickness direction of the control runner 91. Thus, the gear structure 97 has a large contact area with the control ladder rope 92 and has a large friction force.

As shown in fig. 1 and 2, one end of the control ladder cord 92 is connected to one end of a first pull cord 93, the other end of the control ladder cord 92 passes through the control pulley 91 and then is connected to one end of a second pull cord 94, the other end of the second pull cord 94 passes through the pulley mechanism 96 and then is connected to the bottom of the inner flip magnetic handle 95, and the other end of the first pull cord 93 is connected to the top of the inner flip magnetic handle 95.

As shown in fig. 1, the louver lifting mechanism comprises a turning rotating wheel 5, a lifting stay cord 8, a corner pulley 11 and an inner lifting magnetic handle 12, wherein the corner pulley 11 is arranged at the corner of a frame 1 right below a control rotating wheel 91, the inner lifting magnetic handle 12 is arranged below a plurality of louvers 3 and transversely moves along the bottom of the frame 1, one end of the lifting stay cord 8 penetrates through the louvers 3 and is connected with the louver 3 at the lowest end, and the other end of the lifting stay cord 8 penetrates through a mounting seat 6, then bypasses the corner pulley 11 and is connected with the inner lifting magnetic handle 12;

as shown in fig. 3 and 4, fig. 3 is a schematic structural view of the external magnetic control mechanism 10 according to the present invention; fig. 4 is a longitudinal sectional view of fig. 3.

The present embodiment further includes two sets of external magnetic control mechanisms 10 respectively cooperating with the inner flipping magnetic handle 95 and the inner lifting magnetic handle 12, wherein one set of external magnetic control mechanism 10 controls the inner flipping magnetic handle 95 to move up or down, and one set of external magnetic control mechanism 10 controls the inner lifting magnetic handle 12 to move left or right. Two sets of outside magnetism control mechanism 10 all locate the outside in sealed chamber, outside magnetism control mechanism 10 includes guide rail 101, first stopper 102, second stopper 103 and outer magnetism handle 104, first stopper 102 and second stopper 103 set up respectively in guide rail 101, first stopper 102 sets up with second stopper 103 relatively, first stopper 102 and second stopper 103 are used for fixing a position the extreme position of outer magnetism handle 104 removal in-process, prevent that outer magnetism handle 104 excessively moves up and down or excessively moves left and right and move. The outer magnetic handle 104 is of an H-shaped configuration. Therefore, the two sides of the external magnetic handle 104 are stressed in a balanced manner, the movement is stable, and the situation that one side is stressed too heavily to shake can not occur.

As shown in fig. 4, the external magnetic handle 104 includes a handle body 1041, a slider 1042 and a connecting portion 1043 connecting the handle body 1041 and the slider 1042, the slider 1042 is slidably disposed in the guide rail 101, a plurality of magnet blocks and a plurality of rollers 1044 are mounted on an inner end surface of the handle body 1041, the rollers 1044 are distributed on two sides of the magnet blocks, and the magnet blocks are matched with the corresponding magnet blocks on the internal flipping magnetic handle 95 and the internal lifting magnetic handle 12, so that the external magnetic handle 104 moves up and down or moves left and right, the internal flipping magnetic handle 95 also moves up and down correspondingly, and the internal lifting magnetic handle 12 also moves left and right correspondingly.

A plurality of balls 1045 are embedded on the end face of one side of the handle body 1041 opposite to the guide rail 101, and the plurality of balls 1045 are arranged in the length direction of the handle body 1041. The handle body 1041 is connected to the guide rail 101 by rolling balls 1045. Thus, the handle body 1041 converts the sliding friction between the handle body 1041 and the guide rail 101 into rolling friction through the plurality of balls 1045, so that the frictional resistance between the handle body 1041 and the guide rail 101 is greatly reduced, and relatively speaking, the labor is saved.

As shown in fig. 2, the control ladder rope 92 includes a left rope 921, a right rope 922 and a plurality of connecting ropes 923 connecting the left rope 921 and the right rope 922, one end of the first pulling rope 93 is connected with at least two connecting ropes 923 of one end of the control ladder rope 92, and one end of the second pulling rope 94 is connected with at least two connecting ropes 923 of the other end of the control ladder rope 92. Thus, the connection part of one end of the first pull rope 93 and one end of the control ladder rope 92 and the connection part of one end of the second pull rope 94 and the other end of the control ladder rope 92 have higher reliability and are not easy to separate.

The plurality of balls 1045 have the same diameter and are respectively larger than a distance between the upper side edge and the lower side edge of the guide rail 101. The plurality of balls 1045 are respectively partially located between the upper and lower side edges of the guide rail 101. The outer magnetic handle 104 is of an H-shaped configuration. Thus, the balls 1045 are sandwiched between the handle body 1041 and the guide rail 101.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. The hollow glass with the built-in shutter is characterized by comprising a frame (1) and two pieces of glass (2) which are oppositely arranged, a sealing cavity is formed between the frame (1) and the two pieces of glass (2) which are oppositely arranged, a plurality of shutters (3), a rotating shaft (4), a shutter overturning mechanism and a shutter lifting mechanism are arranged in the sealing cavity, the rotating shaft (4) is transversely arranged above the shutters (3) in a rotating manner, the shutter overturning mechanism comprises an overturning rotating wheel (5), a mounting seat (6), an overturning ladder rope (7) and a control assembly (9), the overturning rotating wheel (5) is mounted on the mounting seat (6), the rotating shaft (4) penetrates through the mounting seat (6) and the overturning rotating wheel (5), one end of the overturning ladder rope (7) is wound on the overturning rotating wheel (5), and the overturning ladder rope (7) is provided with a plurality of ladder openings, the plurality of shutters (3) respectively penetrate through the plurality of ladder openings in a one-to-one correspondence manner;

the control component (9) comprises a control rotating wheel (91), a control ladder rope (92), a first pull rope (93), a second pull rope (94), an inner turning magnetic handle (95) and a pulley mechanism (96) arranged on the lower side of the frame, the control rotating wheel (91) is fixed at one end of the rotating shaft (4), a plurality of gear structures (97) matched with the control ladder rope (92) are arranged on the control rotating wheel (91), one end of the control ladder rope (92) is connected with one end of the first pull rope (93), the other end of the control ladder rope (92) passes through the control rotating wheel (91) and then is connected with one end of the second pull rope (94), the other end of the second pull rope (94) passes through the pulley mechanism (96) and then is connected with the bottom of the inner turning magnetic handle (95), the other end of the first pull rope (93) is connected with the top of the inner turnover magnetic handle (95);

the control ladder rope (92) comprises a left rope (921), a right rope (922) and a plurality of connecting ropes (923) for connecting the left rope (921) and the right rope (922), one end of the first stay rope (93) is connected with at least two connecting ropes (923) at one end of the control ladder rope (92), and one end of the second stay rope (94) is connected with at least two connecting ropes (923) at the other end of the control ladder rope (92);

the louver lifting mechanism comprises a turning rotating wheel (5), a lifting stay cord (8), a corner pulley (11) and an inner lifting magnetic handle (12), the corner pulley (11) is arranged at the corner of a frame (1) right below the control rotating wheel (91), the inner lifting magnetic handle (12) is positioned below the louvers (3) and transversely moves along the bottom of the frame (1), one end of the lifting stay cord (8) penetrates through the louvers (3) and is connected with the louver (3) at the lowest end, and the other end of the lifting stay cord (8) penetrates through the mounting seat (6) and then bypasses the corner pulley (11) and is connected with the inner lifting magnetic handle (12);

the magnetic sealing device is characterized by further comprising two groups of external magnetic control mechanisms (10) which are respectively matched with the inner overturning magnetic handle (95) and the inner lifting magnetic handle (12), wherein the two groups of external magnetic control mechanisms (10) are arranged on the outer side of the sealed cavity, each external magnetic control mechanism (10) comprises a guide rail (101), a first limiting block (102), a second limiting block (103) and an external magnetic handle (104), the first limiting blocks (102) and the second limiting blocks (103) are respectively arranged in the guide rails (101), the first limiting blocks (102) and the second limiting blocks (103) are oppositely arranged, each external magnetic handle (104) comprises a handle body (1041), a sliding block (1042) and a connecting part (1043) for connecting the handle body (1041) and the sliding block (1042), the sliding block (1042) is arranged in the guide rails (101) in a sliding manner, a plurality of magnet blocks (1044) are embedded on the inner side surface of the handle body (1041), the rollers (1044) are distributed on two sides of the magnet blocks, a plurality of balls (1045) are embedded on the end face of one side of the handle body (1041) opposite to the guide rail (101), and the handle body (1041) is in rolling connection with the guide rail (101) through the balls (1045);

the diameters of the balls (1045) are the same and are respectively larger than the distance between the upper side edge and the lower side edge of the guide rail (101);

the balls (1045) are respectively and partially positioned between the upper side edge and the lower side edge of the guide rail (101);

the outer magnetic handle (104) is of an H-shaped structure.

2. The built-in louvered hollow glass of claim 1, wherein: the gear structure (97) extends in the thickness direction of the control runner (91).

3. The built-in louvered hollow glass of claim 1, wherein: the plurality of balls (1045) are arranged in a row along the length direction of the handle body (1041).