CN110397361B

CN110397361B - High-safety door and window structure

Info

Publication number: CN110397361B
Application number: CN201910736667.0A
Authority: CN
Inventors: 王涛
Original assignee: Guoyang Xingfu Door Industry Co ltd
Current assignee: Guoyang Xingfu door industry Co.,Ltd.
Priority date: 2019-08-09
Filing date: 2019-08-09
Publication date: 2020-11-24
Anticipated expiration: 2039-08-09
Also published as: CN110397361A

Abstract

The invention discloses a high-safety door and window structure, which comprises a door and window frame body and a baffle plate arranged on the right end face of the door and window frame body, wherein an upper guide sliding groove and a lower guide sliding groove are arranged in the door and window frame body; the invention can realize simultaneous locking up and down, increases the safety and is worth popularizing and using.

Description

High-safety door and window structure

Technical Field

The invention relates to the technical field of doors and windows, in particular to a high-safety door and window structure.

Background

Along with the development of present economic society, the diversification of people's demand, the secret room more and more becomes the mainstream of people's fitment, and the secret room has higher disguise, can play certain guard action to the private property and the privacy of resident family, and traditional translation door and window its not good locking, and the latched position is fragile, and the theftproof nature is poor.

Disclosure of Invention

The invention aims to provide a high-safety door and window structure which is used for overcoming the defects in the prior art.

The high-safety door and window structure comprises a door and window frame body and a baffle plate arranged on the right end face of the door and window frame body, wherein an upper guide chute and a lower guide chute are arranged in the door and window frame body, a door opening with a front opening and a rear opening and a hidden cavity positioned on the right side of the door opening are arranged between the upper guide chute and the lower guide chute, the upper side and the lower side of the door opening are respectively communicated with the left side section of the upper guide chute and the left side section of the lower guide chute, the upper side and the lower side of the hidden cavity are respectively communicated with the right side section of the upper guide chute and the right side section of the lower guide chute, a door moving body is further connected between the upper guide chute and the lower guide chute in a sliding fit manner, a sliding groove is arranged in the top wall of the right side section of the upper guide chute, a first inner cavity extending upwards is arranged in the top wall of the sliding groove close to the left side, the upper side of the trapezoid inclined sliding block is provided with a first sliding block, a first limit sliding block fixedly connected with the left wall and the right wall of the first inner cavity in a matched mode is arranged between the first sliding block and the trapezoid inclined sliding block, a first rack extending up and down is connected in the first limit sliding block in a matched mode, the upper end and the lower end of the first rack are respectively connected with the first sliding block and the trapezoid inclined sliding block in a matched mode, the top of the first sliding block is connected with a first spring in a pressed and matched mode, a linkage auxiliary locking mechanism is arranged in the sliding door body, and an automatic driving control assembly used for controlling the linkage auxiliary locking mechanism to work is arranged on the upper side of the left side section of the upper guide sliding groove.

According to the technical scheme, the left and right of the end face of the bottom of the sliding door body are symmetrically provided with moving rollers which are in rolling fit connection with the bottom wall of the lower guide sliding groove, and the pushing rollers which extend into the sliding groove and are in rolling fit connection with the sliding groove are fixedly arranged on the end face of the top of the sliding door body, which is close to the right side.

According to a further technical scheme, a lock groove is formed in the lower guide sliding groove located on the lower side of the door opening.

According to a further technical scheme, the automatic drive control assembly comprises a first sliding cavity and a second inner cavity located on the upper side of the first sliding cavity, a second limit sliding block is fixedly arranged in the second inner cavity, a second sliding block is arranged on the upper side of the second limit sliding block, a third sliding block is arranged on the lower side of the second limit sliding block, an inner key rotating sleeve is connected in a rotating fit mode in the third sliding block, a drive motor is fixedly arranged in the second limit sliding block, the bottom tail end of the drive motor is in power connection with a first outer key shaft in fit connection with the inner key rotating sleeve, guide sliding rods which are arranged in an up-and-down extending mode are symmetrically arranged on the left side and the right side of the drive motor, the top tail ends of the guide sliding rods are fixedly matched and connected with the bottom end face of the second sliding block, the bottom tail ends of the guide sliding rods are fixedly matched and connected with the top end face of the third sliding block, and a tension spring is fixedly arranged between the top end, a jacking sliding groove with a right-and-left opening is formed in the second sliding block, a second external key shaft extending into the second inner cavity is connected between the second inner cavity and the first sliding cavity in a rotating fit manner, a fourth sliding block is connected in the first sliding cavity in a sliding fit manner, a first screw rod is connected in the fourth sliding block in a threaded fit manner, the top end of the first screw rod is in power fit connection with the bottom end of the second external key shaft, locking pin columns which are symmetrically arranged on the left and right sides are connected in the bottom wall of the first sliding cavity in a sliding fit manner, the top end of each locking pin column is fixedly connected with the bottom end face of the fourth sliding block in a matching manner, a third inner cavity is arranged between the second inner cavity and the first inner cavity, a first rotating shaft is connected between the third inner cavity and the second inner cavity in a rotating fit manner, and an eccentric wheel which is positioned in the jacking sliding groove and is connected with the bottom wall of the jacking sliding groove in a jacking and sliding fit, the right side end of first pivot has set firmly and is located the first gear of third inner chamber, the third inner chamber with normal running fit is connected with the second pivot between the first inner chamber, the left side end of second pivot has set firmly and is located the third inner chamber and with the second gear that first gear engagement is connected, the right side end of second pivot has set firmly and is located the first inner chamber and with the third gear that first rack engagement is connected.

According to a further technical scheme, the linkage auxiliary locking mechanism comprises a fourth inner cavity and a fifth inner cavity, the fourth inner cavity is located on the upper side of the left side of the glass light collecting area, a communicating hole is formed between the fourth inner cavity and the fifth inner cavity, a first fixed block is fixedly arranged in the fourth inner cavity, a third rotating shaft is connected with the first fixed block in a rotating fit mode, a first reel is fixedly arranged at the tail end of the left side of the third rotating shaft, a fourth gear is fixedly arranged at the tail end of the right side of the third rotating shaft, a second fixed block is fixedly arranged in the fifth inner cavity, a fourth rotating shaft is connected with the second fixed block in a rotating fit mode, a second reel is fixedly arranged at the tail end of the left side of the fourth rotating shaft, a first bevel gear is fixedly arranged at the tail end of the right side of the fourth rotating shaft, a pull rope is connected in the communicating hole in a transition fit mode, one end of the pull rope, the other end of the pull rope is connected with the second reel in a winding and matching manner, the right side of the first bevel gear is connected with a fifth rotating shaft in a rotating and matching manner, a second bevel gear in meshing connection with the first bevel gear is fixedly arranged at the bottom section of the fifth rotating shaft, a torsion spring is annularly arranged at the top section of the fifth rotating shaft, one end of the torsion spring is fixedly connected with the outer surface of the fifth rotating shaft in a matching manner, the other end of the torsion spring is fixedly connected with the top wall of the fifth inner cavity in a matching manner, an embedded sliding groove is arranged in the bottom end surface of the sliding door body, an auxiliary locking block is connected in the embedded sliding groove in a sliding and matching manner, a second screw rod is connected in the auxiliary locking block in a matching manner through internal threads in the top end surface, the tail end of the top wall of the second screw rod is connected with the fifth rotating shaft in a power matching, the bottom of the fifth sliding block is connected with a second spring in a jacking and matching mode, a second rack is connected between the second sliding cavity and the fourth inner cavity in a sliding and matching mode, the top end of the second rack is fixedly connected with the bottom end face of the fifth sliding block in a matching and matching mode, the bottom section of the second rack extends into the fourth inner cavity and is connected with the fourth gear in a meshing mode, and insertion grooves with upward openings are symmetrically arranged in the top wall of the second sliding cavity in a bilateral mode.

According to the further technical scheme, a glass light collecting area is arranged in the sliding door body.

The invention has the beneficial effects that: the invention has the beneficial effects that: the automatic control device is reasonable in design and simple in structure, when the automatic drive control assembly does not work, the movable door body can be controlled to move left and right flexibly through manual control, opening and closing operations are facilitated, after the movable door body is closed, the pushing roller is in butt fit with the trapezoidal inclined sliding block through the pushing roller, power fit connection work of the inner key rotating sleeve and the second outer key shaft is further achieved, the driving motor drives and controls the second outer key shaft to rotate forwards and backwards, unlocking and locking work can be controlled automatically, the automatic drive control assembly drives and locks work, and meanwhile the linkage auxiliary locking mechanism can be controlled to lock the bottom of the movable door body, so that safety is improved, and the automatic control device is worthy of popularization and use.

Drawings

FIG. 1 is a schematic view of an external result of a window and door frame according to the present invention;

FIG. 2 is a schematic view of an external structure of a high-safety door window structure according to the present invention;

FIG. 3 is a schematic view of the internal structure of a high security door/window structure according to the present invention;

FIG. 4 is an enlarged partial schematic view of A of FIG. 3 according to the present invention;

fig. 5 is a partially enlarged view of B in fig. 3 according to the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 5, a high-safety door and window structure according to an embodiment of the present invention includes a door and window frame 6 and a baffle (not shown) mounted on a right end surface of the door and window frame 6, an upper guide chute 63 and a lower guide chute 64 are disposed in the door and window frame 6, a door opening 61 with a front opening and a rear opening and a hidden cavity 62 located on a right side of the door opening 61 are disposed between the upper guide chute 63 and the lower guide chute 64, upper and lower sides of the door opening 61 are respectively communicated with a left side section of the upper guide chute 63 and a left side section of the lower guide chute 64, upper and lower sides of the hidden cavity 62 are respectively communicated with a right side section of the upper guide chute 63 and a right side section of the lower guide chute 64, a door body 7 is further connected between the upper guide chute 63 and the lower guide chute 64 in a sliding fit manner, so as to improve a movement stability of the door body 7, preventing sliding deviation, a sliding groove 631 is arranged in the top wall of the right section of the upper sliding guide groove 63, the sliding groove 631 is provided with a first inner cavity 65 extending upwards in the top wall near the left side, a trapezoid inclined sliding block 655 is connected in the first inner cavity 65 in a sliding fit manner, a first sliding block 652 is arranged on the upper side of the trapezoid inclined sliding block 655, a first limit sliding block 651 fixedly connected with the left wall and the right wall of the first inner cavity 65 in a matching way is arranged between the first sliding block 652 and the trapezoid inclined sliding block 655, a first rack 654 extending up and down is connected in the first limit slider 651 in a sliding fit manner, the upper and lower ends of the first rack 654 are respectively and fixedly connected with the first sliding block 652 and the trapezoidal inclined sliding block 655, the top of the first sliding block 652 is connected with a first spring 653 in a pressing fit manner, a linkage auxiliary lock mechanism is arranged in the sliding door body 7, and an automatic driving control assembly for controlling the working of the linkage auxiliary locking mechanism is arranged on the upper side of the left section of the upper guide chute 63.

Beneficially or exemplarily, the bottom end surface of the door moving body 7 is symmetrically provided with moving rollers 72 in rolling fit connection with the bottom wall of the lower guide sliding groove 64 from left to right, and the top end surface of the door moving body 7 is fixedly provided with a push roller 6311 which extends into the sliding groove 631 and is in rolling fit connection therewith near the right side, so as to improve the flexibility of the movement of the door moving body 7.

Advantageously or exemplarily, a lock groove 641 is provided in the lower guide groove 64 located at the lower side of the door opening 61.

Beneficially or exemplarily, the automatic driving control assembly includes a first sliding cavity 67 and a second inner cavity 66 located at an upper side of the first sliding cavity 67, a second limiting block 661 is fixedly disposed in the second inner cavity 66, a second slider 662 is disposed at an upper side of the second limiting block 661, a third slider 664 is disposed at a lower side of the second limiting block 661, an inner key sleeve 6641 is rotatably and cooperatively connected to the third slider 664, a driving motor 6611 is fixedly disposed in the second limiting block 661, a first outer key shaft 6642 cooperatively connected to the inner key sleeve 6641 is dynamically connected to a bottom end of the driving motor 6611, guide sliding rods 6612 extending up and down are symmetrically disposed at left and right sides of the driving motor 6611, a top end of the guide sliding rod 6612 is fixedly and cooperatively connected to a bottom end surface of the second slider 662, a bottom end of the guide sliding rod 6612 is fixedly and cooperatively connected to a top end surface of the third slider 664, an extension spring 663 is fixedly arranged between the top end face of the second slider 662 and the top wall of the second inner cavity 66, a top pressure sliding groove 6621 with a right-first opening is arranged in the second slider 662, a second external key shaft 665 extending into the second inner cavity 66 is connected between the second inner cavity 66 and the first sliding cavity 67 in a rotating fit manner, a fourth slider 671 is connected in the first sliding cavity 67 in a sliding fit manner, a first screw 672 is connected in the fourth slider 671 in a threaded fit manner, the top end of the first screw 672 is connected with the bottom end of the second external key shaft 665 in a power fit manner, locking pin columns 673 which are arranged in bilateral symmetry are connected in the bottom wall of the first sliding cavity 67 in a sliding fit manner, the top end of each locking pin column 673 is fixedly connected with the bottom end face of the fourth slider 671 in a fit manner, a third inner cavity 68 is arranged between the second inner cavity 66 and the first inner cavity 65, a first rotating shaft 684 is connected between the third inner cavity 68 and the second inner cavity 66 in a rotating fit manner, an eccentric wheel 686 which is positioned in the jacking sliding groove 6621 and is connected with the bottom wall of the jacking sliding groove 6621 in a jacking sliding fit manner is fixedly arranged at the tail end of the left side of the first rotating shaft 684, a first gear 685 positioned in the third inner cavity 68 is fixedly arranged at the right end of the first rotating shaft 684, a second rotating shaft 681 is connected between the third inner cavity 68 and the first inner cavity 65 in a rotating fit manner, a second gear 683 which is positioned in the third cavity 68 and engaged with the first gear 685 is fixedly arranged at the left end of the second rotating shaft 681, the right end of the second rotating shaft 681 is fixedly provided with a third gear 682 which is positioned in the first inner cavity 65 and engaged with the first rack 654, so as to realize the locking operation of the top of the sliding door body 7 by automatic driving control.

Beneficially or exemplarily, the linkage pair locking mechanism includes a fourth inner cavity 73 located at the upper side of the left side of the glass lighting area 71 and a fifth inner cavity 74 located at the lower side of the left side of the glass lighting area 71, a communicating hole 75 is provided between the fourth inner cavity 73 and the fifth inner cavity 74, a first fixing block 731 is fixedly provided in the fourth inner cavity 73, a third rotating shaft 732 is rotatably and fittingly connected to the first fixing block 731, a first winding wheel 734 is fixedly provided at the left end of the third rotating shaft 732, a fourth gear 733 is fixedly provided at the right end of the third rotating shaft 732, a second fixing block 741 is fixedly provided in the fifth inner cavity 74, a fourth rotating shaft 743 is rotatably and fittingly connected to the second fixing block 741, a second winding wheel 742 is fixedly provided at the left end of the fourth rotating shaft 743, a first bevel gear 744 is fixedly provided at the right end of the fourth rotating shaft 743, a pulling rope 751 is transitionally and fittingly connected to the communicating hole 75, one end of the pull rope 751 is connected with the first reel 734 in a winding and matching manner, the other end of the pull rope 751 is connected with the second reel 742 in a winding and matching manner, the right side of the first bevel gear 744 is connected with a fifth rotating shaft 746 in a rotating and matching manner, the bottom section of the fifth rotating shaft 746 is fixedly provided with a second bevel gear 745 in a meshing and connecting manner with the first bevel gear 744, the top section of the fifth rotating shaft 746 is annularly provided with a torsion spring 747, one end of the torsion spring 747 is fixedly connected with the outer surface of the fifth rotating shaft 746 in a matching manner, the other end of the torsion spring 747 is fixedly connected with the top wall of the fifth inner cavity 74 in a matching manner, the bottom end face of the door moving body 7 is internally provided with an embedding chute 77, the embedding chute 77 is connected with an auxiliary lock pin block 771 in a sliding and matching manner, the top inner thread end face of the auxiliary lock pin block 771 is connected with a second, the upside of fourth inner chamber 73 is equipped with second sliding chamber 76, sliding fit connects with fifth slider 761 in the second sliding chamber 76, the cooperation of top pressure of fifth slider 761 bottom is connected with second spring 763, sliding fit connects with second rack 762 between second sliding chamber 76 and the fourth inner chamber 73, the top end of second rack 762 with the bottom terminal surface fixed fit of fifth slider 761 is connected, the bottom section of second rack 762 stretches into in the fourth inner chamber 73 and with fourth gear 733 meshing is connected, bilateral symmetry is equipped with the upwards inserting groove 764 of opening that sets up in the roof of second sliding chamber 76 to realize coordinated control the bottom locking work of the sliding door body 7 has further improved the security of locking.

Advantageously or exemplarily, a glass lighting zone 71 is provided in the moving door body 7.

In an initial state, the fifth slider 761 is pressed by the second spring 763 to be located at the topmost position in the second sliding cavity 76, and then the fifth slider 761 drives the top section of the second rack 762 to be located in the second sliding cavity 76 to the greatest extent, at this time, the first bevel gear 744 drives the second bevel gear 745 to rotate, so that the torsion spring 747 and the fifth rotating shaft 746 are in the maximum twisting state, and at the same time, the second screw 772 drives the sub-lock block 771 to be located completely in the embedded sliding slot 77, so that the pushing roller 6311 is located away from the first inner cavity 65 to the greatest extent, at this time, the first slider 652 is pressed by the first spring 653 to make the first slider 652 abut against the first limit slider 651, so that the first rack 654 drives the trapezoidal slider 655 to extend into the sliding slot to the greatest extent, at this time, the first rack 654 drives the third gear 682 to rotate, and at the first rotating shaft 684 drives the eccentric wheel to be located away from the bottom wall 6621 of the circle center of the side to the greatest extent, at this time, the second slider 662 is subjected to the stretching force of the stretching spring 663, so that the bottom wall of the jacking chute 6621 abuts against the outer surface of the eccentric wheel on the side close to the circle center, and at the same time, the second slider 662 is positioned at the topmost position in the second inner cavity 66, at this time, the second slider 662 drives the third slider 664 to abut against the bottom end surface of the second limiting slider 661 through the slide guiding rod 6612, and at the same time, the inner key rotating sleeve 6641 in the second limiting slider 661 is maximally away from the second outer key shaft 665.

Example 1

The sliding door body 7 can be controlled to slide along the left and right directions of the upper guide sliding groove 63 and the lower guide sliding groove 64 by manually moving the sliding door body 7, so that the closing and opening operations are realized, when the push roller 6311 slides to the leftmost position in the sliding groove 631, at this time, the push roller 6311 is abutted against the bottom end face of the trapezoidal inclined slider 655, the trapezoidal inclined slider 655 drives the first slider 652 through the first rack 654 to overcome the jacking force of the first spring 653, so that the first slider 652 is located at the top position in the first inner cavity 65 to the maximum extent, and at the same time, the trapezoidal inclined slider 655 completely extends into the first inner cavity 65, and the temporary positioning operation of the push roller 6311 and the sliding door body 7 by the trapezoidal inclined slider 655 is realized because the trapezoidal inclined slider 655 receives the jacking force of the first spring 653.

Example 2

When locking is required to be controlled, the left side section of the door moving body 7 is moved into the door hole 61, the left side end face of the door moving body 7 is abutted against the left side wall of the door hole 61, the insertion groove 764 is positioned opposite to the bottom end of the lock pin column 673, the bottom end of the auxiliary lock pin block 771 is positioned opposite to the lock groove 641, at this time, the door moving body 7 is moved to the leftmost position in the sliding groove 631, the push roller 6311 is further slid to the leftmost position in the sliding groove 631, at this time, the push roller 6311 is abutted against the bottom end face of the trapezoidal inclined slider 655, the first rack 654 controls the third gear 682 to rotate, the first rotating shaft 684 drives the outer surface of the eccentric 686 on the side away from the center of the circle to be abutted against the bottom wall of the push sliding groove 6621, the second slider 662 drives the third slider 664 to slide downwards through the guide sliding rod 6612, and the third slider 664 is further moved to the bottom position in the second cavity 66 to the maximum extent, at this time, the bottom section of the inner spline 6641 is connected to the second outer spline shaft 665, and at the same time, the top section of the inner spline 6641 is connected to the first outer spline shaft 6642, and then the first outer spline shaft 6642 is controlled to rotate by the driving motor 6611, so that the first outer spline shaft 6642 drives the inner spline 6641 and the second outer spline shaft 665 to rotate, the second outer spline shaft 665 drives the first screw 672 to rotate, the first screw 672 drives the fourth slider 671 to slide toward the bottom direction in the first sliding cavity 67, the fourth slider 671 drives the lock pin 673 to extend into the insertion slot 764 to abut against the top end face of the fifth slider 761, and at the same time, the fifth slider 761 drives the second rack 762 to move downward against the jacking force of the second spring 763 until the fifth slider 761 moves to the bottom position in the second sliding cavity 76 to the maximum extent, and at this time, the lock pin 673 and the insertion slot 764 are locked, meanwhile, the fourth gear 733 is driven to rotate by the downward movement of the second rack 762, and then the first reel 734 is driven to rotate for paying off by the third rotating shaft 732, at this time, the fifth rotating shaft 746 is subjected to the torsion of the torsion spring 747, and then the second bevel gear 745 and the second screw 772 are driven to rotate, at the same time, the first bevel gear 744 is driven to rotate by the second bevel gear 745, at this time, the second reel 742 is driven to rotate for taking up by the fourth rotating shaft 743, and at the same time, the auxiliary lock pin block 771 is driven to slide towards the bottom direction of the embedding chute 77 by the rotation of the second screw 772 until the bottom end of the auxiliary lock pin block 771 extends into the lock groove 641 to the maximum extent.

The invention has the beneficial effects that: the automatic control device is reasonable in design and simple in structure, when the automatic drive control assembly does not work, the movable door body can be controlled to move left and right flexibly through manual control, opening and closing operations are facilitated, after the movable door body is closed, the pushing roller is in butt fit with the trapezoidal inclined sliding block through the pushing roller, power fit connection work of the inner key rotating sleeve and the second outer key shaft is further achieved, the driving motor drives and controls the second outer key shaft to rotate forwards and backwards, unlocking and locking work can be controlled automatically, the automatic drive control assembly drives and locks work, and meanwhile the linkage auxiliary locking mechanism can be controlled to lock the bottom of the movable door body, so that safety is improved, and the automatic control device is worthy of popularization and use.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims

1. The utility model provides a high security door and window structure, includes the door and window frame body and install in the baffle of door and window frame body right side terminal surface, its characterized in that: an upper guide chute and a lower guide chute are arranged in the door and window frame, a front opening and a rear opening are formed between the upper guide chute and the lower guide chute, a hidden cavity is positioned on the right side of the door opening, the upper side and the lower side of the door opening are respectively communicated with the left side section of the upper guide chute and the left side section of the lower guide chute, the upper side and the lower side of the hidden cavity are respectively communicated with the right side section of the upper guide chute and the right side section of the lower guide chute, a shifting body is connected between the upper guide chute and the lower guide chute in a sliding fit manner, a sliding groove is arranged in the top wall of the right side section of the upper guide chute, a first inner cavity extending upwards is arranged in the top wall close to the left side of the sliding groove, a trapezoid inclined sliding block is connected in a sliding fit manner in the first inner cavity, a first sliding block is arranged on the upper side of the trapezoid inclined sliding block, and a first limiting sliding block fixedly connected with the left wall and the, a first rack extending up and down is connected in the first limiting slide block in a sliding fit mode, the upper end and the lower end of the first rack are fixedly connected with the first slide block and the trapezoidal inclined slide block in a matching mode respectively, a first spring is connected to the top of the first slide block in a pressing fit mode, a linkage auxiliary locking mechanism is arranged in the sliding door body, and an automatic driving control assembly used for controlling the linkage auxiliary locking mechanism to work is arranged on the upper side of the left side section of the upper guide slide groove; the automatic drive control assembly comprises a first sliding cavity and a second inner cavity positioned on the upper side of the first sliding cavity, a second limit sliding block is fixedly arranged in the second inner cavity, a second sliding block is arranged on the upper side of the second limit sliding block, a third sliding block is arranged on the lower side of the second limit sliding block, an inner key rotating sleeve is connected in a rotating fit mode in the third sliding block, a driving motor is fixedly arranged in the second limit sliding block, the bottom tail end of the driving motor is in power connection with a first outer key shaft in fit connection with the inner key rotating sleeve, guide sliding rods which are arranged in an up-and-down extending mode are symmetrically arranged on the left side and the right side of the driving motor, the top tail ends of the guide sliding rods are fixedly in fit connection with the bottom end face of the second sliding block, the bottom tail ends of the guide sliding rods are fixedly in fit connection with the top end face of the third sliding block, and a tension spring is fixedly arranged between the top end face, a jacking sliding groove with a right-and-left opening is formed in the second sliding block, a second external key shaft extending into the second inner cavity is connected between the second inner cavity and the first sliding cavity in a rotating fit manner, a fourth sliding block is connected in the first sliding cavity in a sliding fit manner, a first screw rod is connected in the fourth sliding block in a threaded fit manner, the top end of the first screw rod is in power fit connection with the bottom end of the second external key shaft, locking pin columns which are symmetrically arranged on the left and right sides are connected in the bottom wall of the first sliding cavity in a sliding fit manner, the top end of each locking pin column is fixedly connected with the bottom end face of the fourth sliding block in a matching manner, a third inner cavity is arranged between the second inner cavity and the first inner cavity, a first rotating shaft is connected between the third inner cavity and the second inner cavity in a rotating fit manner, and an eccentric wheel which is positioned in the jacking sliding groove and is connected with the bottom wall of the jacking sliding groove in a jacking and sliding fit, a first gear positioned in the third inner cavity is fixedly arranged at the tail end of the right side of the first rotating shaft, a second rotating shaft is connected between the third inner cavity and the first inner cavity in a rotating fit manner, a second gear positioned in the third inner cavity and meshed with the first gear is fixedly arranged at the tail end of the left side of the second rotating shaft, and a third gear positioned in the first inner cavity and meshed with the first rack is fixedly arranged at the tail end of the right side of the second rotating shaft;

the sliding door is internally provided with a glass light collecting area, the linkage auxiliary locking mechanism comprises a fourth inner cavity positioned at the upper side of the left side of the glass light collecting area and a fifth inner cavity positioned at the lower side of the left side of the glass light collecting area, a communicating hole is arranged between the fourth inner cavity and the fifth inner cavity, a first fixed block is fixedly arranged in the fourth inner cavity, a third rotating shaft is connected with the first fixed block in a rotating and matching manner, a first reel is fixedly arranged at the left end of the third rotating shaft, a fourth gear is fixedly arranged at the right end of the third rotating shaft, a second fixed block is fixedly arranged in the fifth inner cavity, a fourth rotating shaft is connected with the second fixed block in a rotating and matching manner, a second reel is fixedly arranged at the left end of the fourth rotating shaft, a first bevel gear is fixedly arranged at the right end of the fourth rotating shaft, a pull rope is connected in the communicating hole in a transition and matching manner, and one end of the pull rope, the other end of the pull rope is connected with the second reel in a winding and matching manner, the right side of the first bevel gear is connected with a fifth rotating shaft in a rotating and matching manner, a second bevel gear in meshing connection with the first bevel gear is fixedly arranged at the bottom section of the fifth rotating shaft, a torsion spring is annularly arranged at the top section of the fifth rotating shaft, one end of the torsion spring is fixedly connected with the outer surface of the fifth rotating shaft in a matching manner, the other end of the torsion spring is fixedly connected with the top wall of the fifth inner cavity in a matching manner, an embedded sliding groove is arranged in the bottom end surface of the sliding door body, an auxiliary locking block is connected in the embedded sliding groove in a sliding and matching manner, a second screw rod is connected in the auxiliary locking block in a matching manner through internal threads in the top end surface, the tail end of the top wall of the second screw rod is connected with the fifth rotating shaft in a power matching, the bottom of the fifth sliding block is connected with a second spring in a jacking and matching mode, a second rack is connected between the second sliding cavity and the fourth inner cavity in a sliding and matching mode, the top end of the second rack is fixedly connected with the bottom end face of the fifth sliding block in a matching and matching mode, the bottom section of the second rack extends into the fourth inner cavity and is connected with the fourth gear in a meshing mode, and insertion grooves with upward openings are symmetrically arranged in the top wall of the second sliding cavity in a bilateral mode.

2. The high-safety door and window structure according to claim 1, wherein: the sliding door is characterized in that moving rollers which are connected with the bottom wall of the lower guide sliding groove in a rolling fit mode are symmetrically arranged on the left side and the right side of the end face of the bottom of the sliding door body in a bilateral mode, and pushing rollers which stretch into the sliding groove and are connected with the sliding groove in a rolling fit mode are fixedly arranged on the end face of the top of the sliding door body close to the right side.

3. The high-safety door and window structure according to claim 1, wherein: and a lock groove is arranged in the lower guide sliding groove positioned on the lower side of the door opening.