CN119021576B - Energy-saving door and window integrated transverse pulling system - Google Patents

Abstract

The invention discloses an integrated transverse pulling system for energy-saving doors and windows, which relates to the technical field of green energy-saving doors and windows and comprises a window frame and a blade folding rope and a blade direction regulating rod on a shutter curtain, wherein a top groove box is fixedly arranged at the inner top of the window frame, a sliding block component is transversely and slidably arranged in the top groove box and is in transmission connection with the blade folding rope through a first traction mechanism, and the sliding block component is in transmission connection with the blade direction regulating rod through a second traction mechanism.

Description

Energy-saving door and window integrated transverse pulling system

Technical Field

The invention relates to the technical field of green energy-saving doors and windows, in particular to an integrated transverse pulling system for an energy-saving door and window.

Background

The energy-saving door and window is provided with the shutter curtain which can be pulled and adjusted, so that the effects of protecting privacy, preventing sun, insulating heat and the like are achieved, wherein the adjustment of the retraction and deflection angles of the blades of the shutter curtain is often controlled by a corresponding pulling system;

The existing traditional Chinese patent publication number is CN207033302U, the name of the patent is a direction adjusting structure of a shutter curtain blade, the patent comprises an upper beam, a lower beam, a plurality of blades, a lifting rope and a guide rope, the blades are arranged between the upper beam and the lower beam from top to bottom, both ends of each blade are provided with lifting rope holes, the lifting rope penetrates through the lifting rope holes in sequence after penetrating out of the guide lifting mechanism of the upper beam and is finally fixed with the lower beam, curled edges are formed inwards at both sides of the long edge of the blade, the guide rope penetrates out of the guide lifting mechanism of the upper beam, fixing rings are arranged on the surface of the guide rope at equal intervals, fixed point connection between the blade and the guide rope is realized by penetrating into one curled edge of the fixing rings through U-shaped steel nails, and along with upward movement or downward movement of the guide rope, the curled edges of the blade also follow upward movement or downward movement, so that the direction adjustment of the blade is realized;

The existing pulling system of the blind comprises a blade folding rope and a blade direction regulating rod which are vertically arranged on two sides of a window body, the blade folding rope can control the folding and unfolding state of the blind, the blade direction regulating rod can regulate the deflection angle of the blade, and in some installation ground window sashes, a safety barrier is usually arranged at the window sashes for safety, so that the existing vertical pulling scheme is inconvenient to regulate the blind, and the energy-saving door and window integrated transverse pulling system is provided for solving the problems.

Disclosure of Invention

The invention aims to provide an integrated transverse pulling system for energy-saving doors and windows, which aims to solve the defects in the prior art.

In order to achieve the above object, the present invention provides the following technical solutions:

The integrated transverse pulling system for the energy-saving doors and windows comprises a window frame, a blade folding rope and a blade direction regulating rod, wherein the blade folding rope and the blade direction regulating rod are arranged on a blind, a top groove box is fixedly arranged at the inner top of the window frame, a sliding block assembly is transversely and slidably arranged in the top groove box, the sliding block assembly is in transmission connection with the blade folding rope through a first traction mechanism, and the sliding block assembly is in transmission connection with the blade direction regulating rod through a second traction mechanism;

The first traction mechanism comprises a first pulley block rotatably arranged on the top groove box, a pulley on the first pulley block is connected with a first traction rope connected with the blade folding rope, and the first traction rope plays a traction role between the sliding block assembly and the blade folding rope;

The second traction mechanism comprises a second traction rope, two ends of the second traction rope are respectively fixed with the head end and the tail end of the sliding block assembly, a pulley on the second traction rope is connected with a second pulley block in the groove jacking box, a pulley on the second traction rope is connected with a driving wheel unit fixed with the blade direction-adjusting rod, and the second traction rope plays a role in driving between the sliding block assembly and the driving wheel unit.

Preferably, a partition plate is fixed in the top groove box, a slideway space for accommodating the sliding block assembly is formed between the upper side of the partition plate and the inner wall of the top groove box, an accommodating space for installing a blade steering rod is formed between the lower side of the partition plate and the inner wall of the top groove box, and a plurality of through holes are formed in the partition plate.

Preferably, the first pulley block comprises two first fixed pulleys which are respectively rotatably arranged in the slideway space and the accommodating space, and also comprises a second fixed pulley which is rotatably arranged in the accommodating space.

Preferably, the sliding block assembly comprises a moving block, a rotating wheel connected with a first traction rope pulley is rotatably arranged on the moving block, one end, far away from the blade folding rope, of the first traction rope is fixed with the partition plate, and the moving block and the first traction mechanism form a movable pulley block.

Preferably, the second pulley block comprises a first reversing fixed pulley positioned at one end of the travel of the moving block, the second pulley block further comprises a second reversing fixed pulley positioned at the other end of the travel of the moving block, and the second pulley block plays a role in supporting and steering for the second traction rope in the groove jacking box.

Preferably, the blade direction-adjusting bar is fixed with a bridging plate, and when the blades of the blind are in the maximum closed state, the edge of the bridging plate is contacted with the partition plate.

Preferably, the first reversing fixed pulley comprises a first reversing shaft lever rotatably mounted on the top groove box, two first bearing wheels are rotatably mounted on the shaft lever, and the two first bearing wheels and the second traction rope pulley are reversely rotated when in connection transmission.

Preferably, the second reversing fixed pulley comprises a mounting block which is in sliding clamping connection in a slideway space, a second bearing wheel is rotatably mounted on the mounting block, and an adjusting screw which is in spiral splicing with the mounting block is rotatably mounted on the top groove box.

Preferably, the first magnetic block is embedded in the moving block, and the first magnetic block can receive the adsorption force of the second magnetic block outside the window frame to drive the moving block to move in the slideway space.

Preferably, the driving wheel unit comprises a wheel ring movably sleeved on the blade steering rod, an annular cavity is formed in the inner wall surface of the ring body of the wheel ring, an outer ratchet ring and an inner ratchet ring are concentrically arranged on the inner wall of the annular cavity, tooth surfaces of the outer ratchet ring and the inner ratchet ring are both positioned on the end side surface of the ring body, the ratchet arrangement directions of the outer ratchet ring and the inner ratchet ring are opposite, a plurality of threaded rods fixed with the blade steering rod are arranged in the annular cavity, a linear sliding groove is formed in the rod body of the threaded rod, a gear is spirally sleeved on the rod body of the threaded rod, a damping ring unit is movably sleeved on the rod body of the threaded rod, and the damping ring unit increases resistance for spiral rotation of the gear on the threaded rod body, so that the blade steering rod can be driven to normally deflect before the maximum deflection angle is reached.

According to the integrated transverse pulling system for the energy-saving door and window, provided by the technical scheme, the sliding block assembly capable of transversely sliding is arranged at the top of the window frame and is respectively connected with the blade folding rope through the first traction mechanism, and the second traction mechanism is in transmission connection with the blade direction-adjusting rod, so that the reciprocating transverse movement of the sliding block assembly is controlled, the lifting folding of the blades of the blind and the deflection adjustment of the blind can be realized, the whole mechanism is simple in structure, all adjustment and control can be realized only by operating the movement of the sliding block assembly at the top of the window frame, and the defect that the vertical pulling scheme of the traditional blind is inconvenient for adjusting the blind installed close to a ground window sash is overcome, so that the integrated transverse pulling system has good practical significance.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings required for the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments described in the present application, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic view of an integrated energy efficient door and window lateral pulling system of the present invention on a window frame;

FIG. 2 is a schematic diagram of a top box of an integrated transverse pulling system for energy-saving doors and windows;

FIG. 3 is a schematic view of a slider assembly of an integrated transverse pulling system for energy-saving doors and windows in a top box;

FIG. 4 is a schematic view of a first traction mechanism of an integrated transverse pulling system for energy-saving doors and windows in a roof tank box according to the present invention;

FIG. 5 is a schematic view of a second traction mechanism of an integrated transverse pulling system for energy-saving doors and windows in a roof tank box according to the present invention;

Fig. 6 is a schematic diagram of connection and fixation of a second traction rope and a rib plate of the integrated transverse traction system for energy-saving doors and windows;

fig. 7 is a schematic partial cross-sectional view of a driving wheel unit of an integrated transverse pulling system for energy-saving doors and windows according to the present invention:

FIG. 8 is an enlarged view of FIG. 7 at A in accordance with the present invention;

fig. 9 is a schematic diagram of a gear cross-section structure of an integrated transverse pulling system for energy-saving doors and windows.

Reference numerals illustrate:

1. A window frame; 1.1, folding ropes of blades; 1.2, a blade direction-adjusting rod; 1.3 parts of bridging plates, 2 parts of top groove boxes, 2.1 parts of separation plates, 2.2 parts of slideway spaces, 2.3 parts of containing spaces, 2.4 parts of through holes, 2.5 parts of box bodies, 2.6 parts of shielding plates, 3 parts of sliding block assemblies, 3.1 parts of moving blocks, 3.2 parts of rotating wheels, 3.3 parts of first magnetic blocks, 4 parts of first traction mechanisms, 4.1 parts of first pulley blocks, 4.11 parts of first fixed pulleys, 4.12 parts of second fixed pulleys, 4.2 parts of first traction ropes, 5 parts of second traction mechanisms, 5.1 parts of second traction ropes, 5.2 parts of second pulley blocks, 5.21 parts of first reversing fixed pulleys, 5.211 parts of shaft rods, 5.212 parts of first bearing wheels, 5.22 parts of second reversing fixed pulleys, 5.221 parts of mounting blocks, 5.222 parts of second bearing wheels, 5.223 parts of adjusting screws, 6 parts of second magnetic blocks, 6.1 parts of wheel rings, 6.2 parts of driving wheels, 6.3 parts of ring gears, 6.3 parts of ring gears, 6.4, ring gears of ratchet gears, 6.7, 6.8, ring gears of ratchet gears, 6.82, ring gears of the magnetic gears of the ring gears of the magnetic pulleys.8.8.8.9.2.8.2, 8.2, 8, and, each, and each, and each.

Detailed Description

In order to make the technical scheme of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

The energy-saving window and door is provided with the shutter curtain which can be pulled and adjusted, the effects of protecting privacy, preventing sun and heat and the like are achieved, the retraction and deflection angle adjustment of the blades of the shutter curtain is often required to be controlled through the corresponding pulling system, the pulling system of the existing shutter curtain comprises the blade retraction ropes and the blade direction adjusting rods which are vertically arranged on two sides of the window body, the retraction state of the shutter curtain can be controlled by the blade retraction ropes, the deflection angle of the blades can be adjusted by the blade direction adjusting rods, and the window sashes of the window curtain close to the ground, such as a sealing window of a balcony or a landing window of some buildings, are formed by a plurality of frames.

Referring to fig. 1-9, an integrated transverse pulling system for energy-saving doors and windows provided by the embodiment of the invention comprises a window frame 1, a blade folding rope 1.1 and a blade direction regulating rod 1.2 on a blind, wherein a top groove box 2 is fixedly arranged at the inner top of the window frame 1, a sliding block component 3 is transversely and slidably arranged in the top groove box 2, the sliding block component 3 is in transmission connection with the blade folding rope 1.1 through a first traction mechanism 4, and the sliding block component 3 is in transmission connection with the blade direction regulating rod 1.2 through a second traction mechanism 5;

the first traction mechanism 4 comprises a first pulley block 4.1 rotatably arranged on the top groove box 2, a pulley on the first pulley block 4.1 is connected with a first traction rope 4.2 connected with the blade folding rope 1.1, and the first traction rope 4.2 plays a traction role between the sliding block component 3 and the blade folding rope 1.1;

the second traction mechanism 5 comprises a second traction rope 5.1, two ends of the second traction rope 5.1 are respectively fixed with the head end and the tail end of the sliding block assembly 3, the sliding block assembly 3 and the second traction rope 5.1 form an annular structure connected end to end, a pulley on the second traction rope 5.1 is connected with a second pulley block 5.2 in the top groove box 2, a pulley on the second traction rope 5.1 is also connected with a driving wheel unit 6 fixed with the blade direction-regulating rod 1.2, and the second traction rope 5.1 plays a role in driving between the sliding block assembly 3 and the driving wheel unit 6;

Specifically, the shutter structure is an existing structure, the blade folding ropes 1.1 are vertically arranged, the shutter is wholly folded when being pulled upwards, the shutter is unfolded when being released, the shutter is identical to the existing shutter folding principle, the axial lead of the blade direction-adjusting rod 1.2 is parallel to the horizontal plane, the blade direction-adjusting rod 1.2 is connected with the blades of each shutter through the ladder rope structure, the blades of the shutter are deflected when the blade direction-adjusting rod 1.2 rotates, and the shutter is identical to the existing shutter folding principle and is not repeated;

In actual use, the sliding block assembly 3 slides transversely in the top groove box 2, for example, when the sliding block assembly 3 slides positively in the top groove box 2, in a first displacement stage of the sliding block assembly 3, the sliding block assembly 3 is pulled by the first traction rope 4.2, so that the blade folding rope 1.1 is acted by upward pulling force, and the blind is wholly lifted and folded, and meanwhile, the sliding block assembly 3 is pulled by the second traction rope 5.1, and friction force between the second traction rope 5.1 and the driving wheel unit 6 causes the driving wheel unit 6 to deflect positively, so that the blade steering rod 1.2 is driven to deflect positively, and the blades of the blind are in a side-turning state;

As the sliding block assembly 3 continues to slide forward in the top groove box 2, the sliding block assembly 3 enters a second displacement stage from the first displacement stage, the whole blind is lifted and folded at the moment, the blades of the blind are in a side-turning state at the tail end in the first displacement stage, the blade steering rod 1.2 reaches the maximum forward deflection position, the sliding block assembly 3 still has a pulling acting force on the second traction rope 5.1 at the moment, but at the moment, the driving wheel unit 6 cannot rotate further because the blade steering rod 1.2 reaches the maximum forward deflection position, the second traction rope 5.1 which is pulled continuously overcomes the friction resistance of the driving wheel unit 6, so that the second traction rope 5.1 slides on the driving wheel unit 6, and the second traction rope 5.1 can not drive the driving wheel unit 6 to deflect forward any more;

Similarly, when the sliding block component 3 continues to slide reversely in the top groove box 2, the shutter is adjusted to be opposite to the moving state of the sliding block component 3 when sliding positively in the top groove box 2;

In other words, in actual use, when the deflection angle of the blades of the blind is required to be adjusted, the light transmittance of the blind can be changed by slightly pushing the movable slide block assembly 3 with a small amplitude, when the folding state of the blind is required to be controlled, the movable slide block assembly 3 is directly moved with a large amplitude, in the technical scheme of the application, the light transmittance of the blind can be adjusted at any position of folding the blind, the adaptability of the blind is further improved, and the defect that the blind close to a ground window sash is inconvenient to be adjusted by a vertical pulling scheme of the conventional blind is overcome, so that the blind has good practical significance.

In another embodiment provided by the invention, a partition plate 2.1 is fixed in the top groove box 2, the partition plate 2.1 is parallel to the horizontal plane, a slideway space 2.2 for accommodating a sliding block assembly 3 is formed between the upper side of the partition plate 2.1 and the inner wall of the top groove box 2, the sliding block assembly 3 can reciprocate in the length direction of the slideway space 2.2, an accommodating space 2.3 for installing a blade steering rod 1.2 is formed between the lower side of the partition plate 2.1 and the inner wall of the top groove box 2, the blade steering rod 1.2 is rotationally installed in the accommodating space 2.3, the length direction line of the blade steering rod 1.2 is parallel to the length direction line of the partition plate 2.1, a plurality of through holes 2.4 are formed in the partition plate 2.1, and the corresponding first traction ropes 4.2 and second traction ropes 5.1 can pass through the partition plate 2.1 through the through holes 2.4.

In a further embodiment provided by the invention, the first pulley block 4.1 comprises two first fixed pulleys 4.11 which are respectively rotatably arranged in the slideway space 2.2 and the accommodating space 2.3, and also comprises a second fixed pulley 4.12 which is rotatably arranged in the accommodating space 2.3, wherein the first fixed pulley 4.11 is parallel to the pulley surface of the second fixed pulley 4.12, so that the vertical pulling of the blade folding rope 1.1 is converted into the transverse pulling consistent with the moving direction of the sliding block assembly 3.

In still another embodiment provided by the invention, the sliding block assembly 3 comprises a moving block 3.1, the moving block 3.1 can reciprocate along the length direction of the slideway space 2.2, a rotating wheel 3.2 connected with a pulley of the first traction rope 4.2 is rotatably arranged on the moving block 3.1, one end of the first traction rope 4.2 far away from the blade folding rope 1.1 is fixed with the partition plate 2.1, in particular, a rib plate 8 is fixedly clamped on the partition plate 2.1, one end of the first traction rope 4.2 far away from the blade folding rope 1.1 is fixed with the rib plate 8, the rib plate 8 is positioned at the tail end of a travel track of the moving block 3.1, a plurality of through holes for the first traction mechanism 4 and the second traction mechanism 5 to penetrate are formed in the rib plate 8, the moving block 3.1 and the first traction mechanism 4 form a movable pulley block, when the sliding block assembly 3 slides forwards in the top groove box 2 in actual use, the moving block 3.1 is a movable pulley part of the movable pulley block, one unit of the moving block 3.1 moves, the two units of the blade folding rope 1 are folded in the lifting process, and the distance of the moving block 1 is shortened, and the two units of the moving block 1 can be folded in the lifting process, and the time is saved.

In still another embodiment provided by the invention, the second pulley block 5.2 comprises a first reversing fixed pulley 5.21 positioned at one end of the travel of the moving block 3.1, the second pulley block 5.2 also comprises a second reversing fixed pulley 5.22 positioned at the other end of the travel of the moving block 3.1, the second pulley block 5.2 plays a role in supporting and steering for the second traction rope 5.1 in the top groove box 2, and meanwhile, the sliding block assembly 3 can drive the blade steering rod 1.2 to deflect correspondingly when moving transversely;

The first reversing fixed pulley 5.21 includes a first reversing shaft lever 5.211 rotatably mounted on the top groove box 2, two first receiving wheels 5.212 are rotatably mounted on the shaft lever 5.211, and the two first receiving wheels 5.212 and the second traction rope 5.1 are opposite in direction when in pulley connection and transmission, that is, the head end and the tail end of the second traction rope 5.1 are respectively fixed with two ends of the moving block 3.1, so that when the moving block 3.1 moves, the second traction rope 5.1 also moves correspondingly on the second pulley block 5.2, and the two first receiving wheels 5.212 respectively correspond to two opposite moving positions of the second traction rope 5.1, so that when the moving block 3.1 moves, the two first receiving wheels 5.212 rotate in opposite directions;

It should be noted that, the wheel axes of the two first receiving wheels 5.212 are perpendicular to the different plane of the moving track line of the moving block 3.1, and the wheel axes of the two first receiving wheels 5.212 are coincident;

The second reversing fixed pulley 5.22 comprises a mounting block 5.221 which is in sliding connection in the slideway space 2.2, a second bearing wheel 5.222 is rotatably mounted on the mounting block 5.221, the wheel body axis of the second bearing wheel 5.222 is parallel to the vertical direction, an adjusting screw 5.223 which is in spiral connection with the mounting block 5.221 is rotatably mounted on the top groove box 2, and in actual use, the clamping position of the mounting block 5.221 in the slideway space 2.2 is controlled by rotating the adjusting screw 5.223, so that the tightness of the second traction rope 5.1 on the second pulley block 5.2 is conveniently adjusted.

In still another embodiment provided by the invention, the bridging plate 1.3 is fixed on the blade steering rod 1.2, and when the blades of the blind are in the maximum closed state, the edge of the bridging plate 1.3 is in contact with the partition plate 2.1, so that the rotation of the blade steering rod 1.2 is limited, on one hand, the blades of the blind are prevented from being damaged due to overlarge deflection angle of the blade steering rod 1.2, and on the other hand, the second traction rope 5.1 is beneficial to sliding on the driving wheel unit 6.

In still another embodiment of the present invention, the first magnetic block 3.3 is embedded in the moving block 3.1, and the first magnetic block 3.3 can receive the adsorption force of the second magnetic block outside the window frame 1 to drive the moving block 3.1 to move in the slideway space 2.2, and when the second magnetic block is adsorbed to the first magnetic block 3.3, the moving block 3.1 can receive the pulling of the first traction mechanism 4 and the second traction mechanism 5 and remain motionless in the top slot box 2.

In still another embodiment provided by the invention, the top groove box 2 comprises a box body 2.5 with an opening at one side, the shielding plate 2.6 is detachably arranged on the opening surface of the box body 2.1, and when maintenance is needed, the shielding plate 2.6 is directly detached at the moment, so that the maintenance is convenient.

In still another embodiment provided by the invention, the driving wheel unit 6 comprises a wheel ring 6.1 movably sleeved on the blade steering rod 1.2, a ring clamping groove 6.2 which is matched and clamped with the second traction rope 5.1 is formed in the circumferential direction of the wheel ring 6.1, an annular cavity 6.3 is formed on the inner wall surface of a ring body of the wheel ring 6.1, an outer ratchet ring 6.4 and an inner ratchet ring 6.5 are concentrically arranged on the inner wall of the annular cavity 6.3, tooth surfaces of the outer ratchet ring 6.4 and the inner ratchet ring 6.5 are both positioned on the side surface of a ring body, the ratchet arrangement directions of the outer ratchet ring 6.4 and the inner ratchet ring 6.5 are opposite, a plurality of threaded rods 6.6 which are fixed with the blade steering rod 1.2 are arranged in the annular cavity 6.3, the shaft axis of the 6.6 is parallel to the shaft axis of the blade steering rod 1.2, a linear sliding groove 6.7 is formed in the rod body of the threaded rod 6.6, a gear 6.8 is sleeved on the rod body of the threaded rod 6, a damping unit 6.9 is sleeved on the other end surface of the inner ratchet ring 6.5, and a damping unit 6.9 is sleeved on the other end surface of the damping unit 6.7;

The gear 6.8 can be in meshed transmission with the outer ratchet ring 6.4 when rotating on the threaded rod 6.6 in the forward direction, so that the gear 6.8 moves towards the inner ratchet ring 6.5 along the threaded rod 6.6, and the gear 6.8 can be in meshed transmission with the inner ratchet ring 6.5 when rotating on the threaded rod 6.6 in the reverse direction, so that the gear 6.8 moves towards the outer ratchet ring 6.4 along the threaded rod 6.6;

Specifically, for example, when the slider assembly 3 slides forward in the top groove box 2, during the first displacement stage of the slider assembly 3, at this time, under the pulling action of the second pulling rope 5.1, the friction acting force between the second pulling rope 5.1 and the driving wheel unit 6 makes the driving wheel unit 6 deflect forward, that is, the wheel ring 6.1 in the driving wheel unit 6 drives the outer ratchet ring 6.4 to deflect forward, at this time, in the interior of the annular cavity 6.3, the gear 6.8 is meshed with the outer ratchet ring 6.4, and the resistance of forward rotation of the gear 6.8 on the threaded rod 6.6 is greater than the deflection resistance of the blade steering rod 1.2, so that the gear 6.8 transmits the deflection torque of the wheel ring 6.1 to the blade steering rod 1.2 through the threaded rod 6.6, so that the deflection angle of the blade steering rod 1.2 to the blade is adjusted;

When the vane steering rod 1.2 reaches the maximum forward deflection position, the vane steering rod 1.2 cannot further rotate at this time, namely, when the sliding block assembly 3 enters the second displacement stage process, the forward rotation resistance of the gear 6.8 on the threaded rod 6.6 is smaller than the deflection resistance of the vane steering rod 1.2, because the gear 6.8 is meshed with the outer ratchet ring 6.4, the gear 6.8 rotates forward on the threaded rod 6.6 under the meshing transmission of the outer ratchet ring 6.4 at this time, so that the sliding block of the gear 6.1 moves along the threaded rod 6.6 towards the inner ratchet ring 6.5 until the gear 6.8 is completely separated from the outer ratchet ring 6.4, at this time, the gear 6.8 is on the inner ratchet ring 6.5, and the gear 6.8 and the inner ratchet ring 6.5 are in a sliding state when the gear 6.1 deflects forward, the state of the threaded rod of the gear 6.8 on the 6.6 is not changed, at this time, the sliding block of the rotation of the gear 6.1 is reduced, so that the sliding block of the gear 6.1 is beneficial to reducing the value of the sliding block assembly 3 entering the second displacement stage process;

Similarly, when the slider assembly 3 slides reversely in the top groove box 2, the principle of forward sliding of the slider assembly 3 in the top groove box 2 is the same as that of forward sliding of the slider assembly 3 in the top groove box 2 in the first displacement stage of the slider assembly 3, and the direction is opposite, and not repeated, when the blade steering rod 1.2 reaches the maximum reverse deflection position, the wheel ring 6.1 in the second displacement stage continues to deflect reversely, and at the moment, the inner ratchet ring 6.5 rotates reversely to drive the gear 6.8 in a meshing manner, so that the gear 6.8 moves along the threaded rod 6.6 towards the outer ratchet ring 6.4 until the gear 6.8 is completely separated from the inner ratchet ring 6.5, at this time, the gear 6.8 is in a sliding state with the outer ratchet ring 6.4 in the reverse deflection process, and the state of the gear 6.8 on the threaded rod 6.6 is not changed, thereby being beneficial to reducing the resistance value of the slider assembly 3 entering the second displacement stage.

In a further embodiment provided by the invention, the damping ring unit 6.9 adds resistance to the helical rotation of the gear 6.8 on the threaded rod 6.6, before the blade steering rod 1.2 is below the maximum deflection angle, thereby ensuring that the blade steering rod 1.2 can be driven to deflect normally;

specifically, the damping ring unit 6.9 includes an iron ring sheet 6.91 fixed to the side surface of the gear 6.8, and further includes a connecting ring 6.92 fixed to the slide post 7, and a magnetic ring 6.93 magnetically adsorbed to the iron ring sheet 6.91 is fixed to the connecting ring 6.92;

In the actual use process, when the gear 6.8 rotates on the threaded rod 6.6, the iron ring piece 6.91 synchronously rotates along with the gear 6.8, so that friction sliding occurs between the iron ring piece 6.91 and the magnetic ring 6.93 which is magnetically adsorbed, and the connecting ring 6.92 synchronously moves along the threaded rod 6.6 due to the magnetic adsorption force between the iron ring piece 6.91 and the magnetic ring 6.93 along with the movement of the gear 6.8 on the axis of the threaded rod 6.6, and the connecting ring 6.92 slides in the linear sliding groove 6.7 through the sliding column 7, so that the connecting ring 6.92 is prevented from synchronously rotating along with the gear 6.8.

In still another embodiment provided by the invention, the gear 6.8 comprises a base wheel 6.81, a plurality of evenly distributed insertion holes 6.82 are formed in the annular wheel surface of the base wheel 6.81, inserting rods 6.83 are movably inserted in the insertion holes 6.82, the inserting ends of the inserting rods 6.83 are connected with the inner bottom of the insertion holes 6.82 through springs 6.84, the inserting rods 6.83 can elastically stretch and retract on the annular wheel surface of the base wheel 6.81, the axis line of the inserting rods 6.83 is perpendicular to the axis line of the base wheel 6.81, and a plurality of inserting rods extending out of the annular wheel surface of the base wheel 6.81 form teeth of the gear 6.8.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the invention, which is defined by the appended claims.

Claims (9)

1. The integrated transverse pulling system for the energy-saving doors and windows comprises a window frame (1) and a blade folding rope (1.1) and a blade direction regulating rod (1.2) on a blind, and is characterized in that a top groove box (2) is fixedly arranged at the inner top of the window frame (1), a sliding block assembly (3) is transversely and slidably arranged in the top groove box (2), the sliding block assembly (3) is in transmission connection with the blade folding rope (1.1) through a first traction mechanism (4), and the sliding block assembly (3) is in transmission connection with the blade direction regulating rod (1.2) through a second traction mechanism (5);

The first traction mechanism (4) comprises a first pulley block (4.1) rotatably arranged on the top groove box (2), a first traction rope (4.2) connected with the blade folding rope (1.1) is connected to a pulley on the first pulley block (4.1), and the first traction rope (4.2) plays a traction role between the sliding block component (3) and the blade folding rope (1.1);

The second traction mechanism (5) comprises a second traction rope (5.1) with two ends respectively fixed with the head end and the tail end of the sliding block assembly (3), a pulley on the second traction rope (5.1) is connected with a second pulley block (5.2) in the top groove box (2), a pulley on the second traction rope (5.1) is also connected with a driving wheel unit (6) fixed with the blade direction-adjusting rod (1.2), and the second traction rope (5.1) plays a role in transmission between the sliding block assembly (3) and the driving wheel unit (6);

the driving wheel unit (6) comprises a wheel ring (6.1) movably sleeved on the blade steering rod (1.2), an annular cavity (6.3) is formed in the inner wall surface of a ring body of the wheel ring (6.1), an outer ratchet ring (6.4) and an inner ratchet ring (6.5) are concentrically arranged on the inner wall of the annular cavity (6.3), tooth surfaces of the outer ratchet ring (6.4) and the inner ratchet ring (6.5) are both positioned on the end side surface of the ring body, the ratchet arrangement directions of the outer ratchet ring (6.4) and the inner ratchet ring (6.5) are opposite, a plurality of threaded rods (6.6) fixed with the blade steering rod (1.2) are arranged in the annular cavity (6.3), a linear chute (6.7) is formed in a rod body of the threaded rod (6.6), gears (6.8) are spirally sleeved on the rod body of the threaded rods (6.6), a ring unit (6.4) is movably sleeved on the rod body of the threaded rods (6.6.6), and the blade steering rod (6.2) can rotate to the maximum damping rod (6.8) in advance, and the damping rod (6.2) can be driven to rotate normally.

2. The integrated transverse pulling system for the energy-saving doors and windows according to claim 1, wherein a partition plate (2.1) is fixed in the top groove box (2), a slideway space (2.2) for accommodating a sliding block assembly (3) is formed between the upper side of the partition plate (2.1) and the inner wall of the top groove box (2), an accommodating space (2.3) for installing a blade steering rod (1.2) is formed between the lower side of the partition plate (2.1) and the inner wall of the top groove box (2), and a plurality of through holes (2.4) are formed in the partition plate (2.1).

3. An integrated transverse pulling system for energy-saving doors and windows according to claim 2, characterized in that the first pulley block (4.1) comprises two first fixed pulleys (4.11) rotatably mounted in the slideway space (2.2) and the accommodating space (2.3), respectively, and a second fixed pulley (4.12) rotatably mounted in the accommodating space (2.3).

4. An integrated transverse pulling system for energy-saving doors and windows according to claim 3, wherein the sliding block assembly (3) comprises a moving block (3.1), a rotating wheel (3.2) connected with a pulley of a first traction rope (4.2) is rotatably arranged on the moving block (3.1), one end of the first traction rope (4.2) far away from the blade folding rope (1.1) is fixed with the partition plate (2.1), and the moving block (3.1) and the first traction mechanism (4) form a movable pulley block.

5. The integrated transverse pulling system for energy-saving doors and windows according to claim 4, wherein the second pulley block (5.2) comprises a first reversing fixed pulley (5.21) positioned at one end of the travel of the moving block (3.1), the second pulley block (5.2) further comprises a second reversing fixed pulley (5.22) positioned at the other end of the travel of the moving block (3.1), and the second pulley block (5.2) supports and deflects the second traction rope (5.1) in the top groove box (2).

6. The energy-saving door and window integrated transverse pulling system according to claim 5, wherein the blade direction-adjusting rod (1.2) is fixedly provided with a bridging plate (1.3), and when the blades of the blind are in a maximum closed state, the edge of the bridging plate (1.3) is in contact with the partition plate (2.1).

7. The integrated transverse pulling system for energy-saving doors and windows according to claim 5, wherein the first reversing fixed pulley (5.21) comprises a first reversing shaft lever (5.211) rotatably mounted on the top groove box (2), two first receiving wheels (5.212) are rotatably mounted on the shaft lever (5.211), and the two first receiving wheels (5.212) are opposite in rotation when in pulley connection transmission with the second traction rope (5.1).

8. The integrated transverse pulling system for the energy-saving doors and windows according to claim 5, wherein the second reversing fixed pulley (5.22) comprises a mounting block (5.221) which is in sliding clamping connection in a slideway space (2.2), a second bearing wheel (5.222) is rotatably mounted on the mounting block (5.221), and an adjusting screw (5.223) which is in spiral splicing with the mounting block (5.221) is rotatably mounted on the top groove box (2).

9. The integrated transverse pulling system for the energy-saving doors and windows according to claim 4, wherein the moving block (3.1) is embedded with a first magnetic block (3.3), and the first magnetic block (3.3) can receive the adsorption force of a second magnetic block outside the window frame (1) to drive the moving block (3.1) to move in the slideway space (2.2).