CN213990415U - Outdoor rain-proof symmetrical formula two skylight structures that open door - Google Patents

Outdoor rain-proof symmetrical formula two skylight structures that open door Download PDF

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Publication number
CN213990415U
CN213990415U CN202120173676.6U CN202120173676U CN213990415U CN 213990415 U CN213990415 U CN 213990415U CN 202120173676 U CN202120173676 U CN 202120173676U CN 213990415 U CN213990415 U CN 213990415U
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China
Prior art keywords
door
water
window frame
beams
groove
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Expired - Fee Related
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CN202120173676.6U
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Chinese (zh)
Inventor
金阳
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Hangzhou Kunding Information Technology Co ltd
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Hangzhou Kunding Information Technology Co ltd
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Priority to CN202120173676.6U priority Critical patent/CN213990415U/en
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Abstract

The utility model relates to the technical field of skylights, in particular to an outdoor rainproof symmetrical double-door skylight structure; the lead screw moving module is arranged on the window frame, and the two door plates are connected with the lead screw moving module; the water collecting groove is arranged on the side wall of the end beam of the window frame and extends along the length direction of the end beam; the guide grooves comprise two groups which are respectively arranged on the side walls of the two side beams and extend along the length direction of the side beams; one end of the diversion trench, which is close to the water collection trench, extends to the water collection trench; and two water stopping grooves extending along the width direction of the door plate are formed in the side walls of the two door plates, which are opposite to each other, and two ends of each water stopping groove respectively extend to the upper parts of the two diversion grooves. The utility model discloses when the door plant is closed, the rainwater can follow the direct flow direction guiding gutter in door plant both sides, also can follow simultaneously by door plant both ends flow direction stagnant water groove, has during the stagnant water groove flows into the guiding gutter again, finally collects the catchment groove, so in order to realize water-proof effects.

Description

Outdoor rain-proof symmetrical formula two skylight structures that open door
Technical Field
The utility model relates to a skylight technical field especially, relates to an outdoor rain-proof symmetrical formula two skylight structures that open door.
Background
At present, some cabinets on the market are usually provided with skylights, most of which are hinge type door opening and closing skylights, and are not suitable for the case that the space in the cabinet is limited or objects are influenced outside; and to some skylight that the side pushed, its water-proof effects is relatively poor, when closing the skylight, the rainwater still can be very easily from the skylight get into the cabinet body, influence the use, consequently this kind of window body structure is not suitable for outdoor use, so still need improve.
SUMMERY OF THE UTILITY MODEL
In view of this, the utility model aims at providing an outdoor rain-proof symmetrical formula two skylight structures that open door.
In order to solve the technical problem, the technical scheme of the utility model is that:
an outdoor rainproof symmetrical double-door skylight structure comprises a window frame and two door plates arranged on the window frame, wherein the window frame comprises two end beams and two side beams, and the two end beams and the two side beams are arranged in an enclosing manner to form a rectangular frame structure; further comprising:
the lead screw motion module is arranged on the window frame, the two door plates are connected with the lead screw motion module, and the lead screw motion module is used for driving the two door plates to move along the length direction of the side beam and towards the direction of mutual approaching/departing;
the water collecting groove is arranged on the side wall of the end beam of the window frame and extends along the length direction of the end beam;
the guide grooves comprise two groups which are respectively arranged on the side walls of the two side beams and extend along the length direction of the side beams; one end of the diversion trench, which is close to the water collection trench, extends to the water collection trench;
and two water stopping grooves extending along the width direction of the door plate are formed in the side walls of the two door plates, which are opposite to each other, and two ends of each water stopping groove respectively extend to the upper parts of the two diversion grooves.
Furthermore, a lower wall of one of the two door panels is provided with a sinking step, and an upper wall of the other door panel is provided with an upper sinking step matched with the sinking step; the bottom wall of the upper sinking step is provided with a sealing groove extending along the length direction of the upper sinking step; and a sealing strip is embedded in the sealing groove.
Furthermore, a diversion chute inclined towards one side of the diversion chute is formed in the upper wall of one end, close to the diversion chute, of the door panel.
Furthermore, a water outlet pipe communicated with the water collecting tank is arranged at the bottom of the water collecting tank.
Further, the sunroof structure further includes:
the floating guide rails comprise two groups which are respectively arranged on the outer side walls of the two side beams of the window frame and extend along the length direction of the side beams; the middle part of the upper wall of the floating guide rail protrudes upwards to form a protruding section;
the floating module comprises two guide wheels which are respectively arranged at the lower parts of the two ends of the door panel and two linear motion components which are respectively arranged at the lower parts of the two ends of the door panel; the guide wheel is movably arranged on the guide rail, and when the guide wheel moves to the protruding section, the door plate is driven to move upwards through the linear motion assembly.
Furthermore, the screw rod movement module comprises two bidirectional screw rods which are respectively connected to the inner sides of the beams at the two sides in a rotating manner, and a stepping motor which is arranged on the window frame and used for driving the bidirectional screw rods to rotate; two nut sliding blocks are connected to the two-way screw rods in a threaded mode, and the two nut sliding blocks are arranged on the two thread sections of the two-way screw rods respectively.
Further, the linear motion assembly comprises a slide rail which is fixedly arranged on the side wall of the nut slide block and is vertically arranged, and a slide seat which is connected to the slide rail in a sliding manner and can move along the height direction of the slide rail; wherein the sliding seat is fixedly connected with the door panel.
Further, the skylight structure further comprises a linkage mechanism; the linkage mechanism comprises two transmission shafts which are coaxially arranged; wherein, the two transmission shafts are both rotationally connected on the inner side wall of the end beam at one side far away from the stepping motor; and the opposite ends of the two transmission shafts are arranged at intervals;
the end parts of the opposite ends of the two transmission shafts are fixedly connected with first bevel gears;
the end parts of the two transmission shafts, which are far away from the ends, are fixedly connected with second bevel gears;
the end parts of the two bidirectional screw rods, which are far away from one end of the stepping motor, are fixedly connected with third bevel gears which are respectively meshed with the two second bevel gears;
a fourth bevel gear which is respectively meshed with the two first bevel gears is arranged between the opposite ends of the two transmission shafts; and the fourth bevel gear is fixedly connected with a rotating shaft which is rotatably connected to the end beam.
Further, a fixed seat is fixedly arranged on the end beam; the rotating shaft is rotatably connected to the fixing seat, and one end, far away from the fourth bevel gear, of the rotating shaft penetrates out of the end beam and is fixedly connected with a manual operation shaft.
Further, the manual operation shaft is a hexagonal shaft.
Compare prior art, the utility model has the advantages that:
the utility model discloses when the door plant is closed, the rainwater can follow the direct flow direction guiding gutter in door plant both sides, also can follow simultaneously by door plant both ends flow direction stagnant water groove, has during the stagnant water groove flows into the guiding gutter again, finally collects the catchment groove, so in order to realize water-proof effects.
Drawings
Fig. 1 is a schematic structural view (door panel closed state) of the present invention;
fig. 2 is a schematic view of the backside structure of the present invention;
fig. 3 is a schematic structural view of the present invention (with one door panel and one diversion trench removed);
fig. 4 is a schematic front structural view of the present invention;
FIG. 5 is an enlarged view of portion A of FIG. 4;
FIG. 6 is a schematic structural view of the linear motion assembly;
FIG. 7 is a front view of the door panel;
FIG. 8 is a schematic view of a back side structure of a door panel;
fig. 9 is a schematic structural view of the floating guide rail.
Reference numerals: 1. a window frame; 11. an end beam; 12. a side beam; 2. a door panel; 21. a convex surface; 22. a diversion chute; 23. sinking a step; 24. sinking to the step; 25. a sealing groove; 3. a lead screw movement module; 31. a bidirectional lead screw; 32. a stepping motor; 33. a nut slider; 34. a module base; 4. a water collecting tank; 41. a water outlet pipe; 5. a diversion trench; 6. a water stopping tank; 7. a floating guide rail; 71. a convex section; 72. a limiting end face; 73. A guide surface; 74. a floating guide slope surface; 8. a floating module; 81. a guide wheel; 811. a support leg; 82. a linear motion assembly; 821. mounting a plate; 8211. a bending part; 8212. a guide rail portion; 822. a connecting plate; 8221. A sliding part; 9. a linkage mechanism; 91. a drive shaft; 92. a first bevel gear; 93. a second bevel gear; 94. a third bevel gear; 95. a fourth bevel gear; 96. a rotating shaft; 97. a fixed seat; 98. the shaft is manually operated.
Detailed Description
The following detailed description of the embodiments of the present invention is made with reference to the accompanying drawings, so that the technical solution of the present invention can be more easily understood and grasped.
Example (b):
referring to fig. 1, the embodiment provides an outdoor rainproof symmetrical double-door skylight structure, which includes a window frame 1, and two door panels 2 arranged on the window frame 1, where the window frame 1 includes two end beams 11 and two side beams 12; the two end beams 11 are arranged in parallel, and the two side beams 12 are arranged in parallel; the two end beams 11 and the two side beams 12 are enclosed to form a rectangular frame structure. The upper wall of the door panel 2 is convex upwards to form a convex surface 21, and when the door panel 2 is closed, the convex surface 21 can be flush with the surface of the outer mask of the cabinet body.
The sunroof structure further includes:
screw motion module 3 installs on window frame 1, and two door plants 2 all are connected with screw motion module 3, screw motion module 3 is used for driving two door plants 2 along 12 length direction of curb girder, simultaneously towards the direction motion of drawing close each other/keeping away from each other to realize the closure/opening of two door plants 2, and is specific, when two door plants 2 were kept away from the motion each other, for the open mode, was the closed mode when two door plants 2 drawn close each other.
The water collecting groove 4 is arranged on the side wall of the end beam 11 of the window frame 1 and extends along the length direction of the end beam 11, the upper end of the water collecting groove 4 is open, and the water collecting groove 4 is fixed on the outer side wall of the end beam 11 through screws and is mainly used for collecting rainwater. Wherein, both ends of the water collecting tank 4 are closed, and the bottom of the water collecting tank 4 is provided with a water outlet pipe 41 communicated with the water collecting tank 4, so that the rainwater collected in the water collecting tank 4 can be discharged through the water outlet pipe 41.
The guide grooves 5 comprise two groups, are respectively arranged on the side walls of the two side beams 12 and extend along the length direction of the side beams 12; the diversion trench 5 is a V-shaped structure with an open upper end and is fixedly connected with the outer side wall of the side beam 12 through a screw. Thus, rainwater on the surface of the door panel 2 falls into the diversion trench 5 when flowing towards two sides.
The end of the diversion trench 5 far away from the water collection trench 4 is closed, and the end of the diversion trench 5 near the water collection trench 4 extends to the upper part of the water collection trench 4, so that the rainwater in the diversion trench 5 can flow to one end of the water collection trench 4 along the diversion trench 5 and finally flows into the water collection trench 4.
And the side walls of the two door panels 2 at the opposite sides are provided with water stopping grooves 6 extending along the width direction of the door panels 2, wherein the width direction of the door panels 2 refers to the direction in which the door panels 2 are parallel to the end beam 11.
The upper part of the water stopping tank 6 is opened; wherein both ends of the water stopping groove 6 are open, and both ends of the water stopping groove 6 respectively extend to the upper parts of the two diversion grooves 5. Therefore, the rainwater on the door panel 2 finally falls into the water stopping groove 6 when flowing to one side of the water stopping groove 6, and then flows into the diversion trench 5 from the water stopping groove 6.
In this embodiment, in order to ensure the sealing performance of the closed position of the two door panels 2 when the two door panels 2 are closed, the embodiment is further improved, specifically:
referring to fig. 9, one of the two door panels 2 has a lower sinking step 23 on the lower wall, as shown in fig. 7, and the other door panel 2 has an upper sinking step 24 on the upper wall, which is matched with the lower sinking step 23, and when closed, the lower sinking step 23 covers the upper part of the upper sinking step 24, and the two are overlapped in butt joint.
As shown in fig. 7, a sealing groove 25 extending along the length direction of upper sinker 24 is formed on the bottom wall of upper sinker 24; a sealing strip (not shown) is embedded in the sealing groove 25, wherein the sealing strip can be an adhesive tape. When the door panels 2 are closed, the two sinking steps are butted, and the sinking step 23 extrudes the sealing strip in the sealing groove 25 of the upper sinking step 24 to realize sealing so as to prevent rainwater from leaking out of the door seams of the two door panels 2.
As shown in fig. 1 and fig. 3, in order to make the rainwater on the door panel 2 flow to the diversion trench 5 better, in this embodiment, a diversion chute 22 inclined to one side of the diversion trench 5 is formed on an upper wall of one end of the door panel 2 close to the diversion trench 5, and the rainwater flows to the diversion trench 5 through an inclined surface of the diversion chute 22.
In this embodiment, referring to fig. 2, the lead screw movement module 3 includes two bidirectional lead screws 31 respectively rotatably connected to the inner sides of the two side beams 12, and a stepping motor 32 mounted on the window frame 1 for driving the bidirectional lead screws 31 to rotate; it should be noted that the bidirectional screw 31 refers to a screw having two opposite thread sections on the rod wall, that is, one thread section is a positive thread and the other thread section is a negative thread; and the two-way lead screws 31 extend along the length direction of the side beam 12, specifically, as shown in fig. 6, a module base 34 extending along the length direction of the side beam 12 is fixedly connected to the inner side wall of the side beam 12, and the two-way lead screws 31 are rotatably connected to the module base 34.
The stepping motor 32 is fixedly arranged on the inner side wall of the side beam 12, and a main shaft of the stepping motor is connected with one end of the bidirectional screw 31 through a coupler; the bidirectional screw 31 is rotated by the stepping motor 32.
As shown in fig. 2, two nut sliders 33 are respectively connected to the two bidirectional screws 31 through threads, wherein the two nut sliders 33 are respectively disposed on two thread sections of the bidirectional screw 31, and the nut sliders 33 can move along the length direction of the module base 34, in other words, two nut sliders 33 are respectively disposed on each bidirectional screw 31, and the two nut sliders 33 are respectively disposed on a positive thread section and a negative thread section of the bidirectional screw 31, so that when the bidirectional screw 31 rotates, the two nut sliders 33 of the bidirectional screw 31 can move in opposite directions.
In this embodiment, the skylight structure further includes:
as shown in fig. 3, the floating guide rails 7 comprise two groups, which are respectively fixed on the outer sides of the two side beams 12 of the window frame 1 through screws, and the floating guide rails 7 are long and extend along the length direction of the side beams 12; as shown in fig. 9, the middle portion of the upper wall of the floating guide rail 7 protrudes upward to form a protruding section 71, specifically: the two ends of the floating guide rail 7 are provided with limiting end surfaces 72; the upper walls of the floating guide rail 7 at the two sides of the convex section 71 are horizontal guide surfaces 73; the junction of the guide surface 73 and the convex section 71 is a smooth arc transition section to form a floating guide ramp 74.
Referring to fig. 9, the floating module 8 includes two guide wheels 81 respectively disposed at the lower portions of the two ends of the door panel 2, and two linear motion assemblies 82 respectively disposed at the lower portions of the two ends of the door panel 2; it should be noted that two ends of each door panel 2 are provided with two guide wheels 81, specifically:
as shown in fig. 8, the bottom of each of the two ends of the door panel 2 is fixedly provided with an inverted U-shaped supporting leg 811, and the guide wheel 81 is rotatably mounted in the supporting legs 811 through a shaft pin, so that the guide wheel 81 can freely roll; the guide wheel 81 is movably arranged on the guide rail, that is, the guide wheel 81 can roll on the upper wall of the floating guide rail 7 along the track of the upper wall of the floating guide rail 7.
The linear motion assembly 82 comprises a slide rail which is fixedly installed on the side wall of the nut slide block 33 and is vertically arranged, and a slide seat which is connected to the slide rail in a sliding manner and can move along the height direction of the slide rail; wherein the slide is fixedly connected with the door panel 2.
Specifically, the method comprises the following steps: as shown in fig. 6, the slide rail includes a U-shaped mounting plate 821, wherein the mounting plate 821 may be a sheet metal part, two sides of the mounting plate 821 are folded inwards to form two bending portions 8211, and the two bending portions 8211 are both fixedly connected to a vertically arranged guide rail portion 8212. The mounting plate 821 is secured to the nut runner 33 on a side remote from the rail portion 8212.
The slide includes including the connecting plate 822 that is right angle Z type, can adopt the sheet metal component, and this connecting plate 822 is close to the sliding part 8221 of two vertical settings of fixedly connected with on the lateral wall of guide rail portion 8212 one side, and two sliding part 8221 are sliding connection respectively on two guide rail portion 8212 to along the vertical displacement of guide rail portion 8212, the upper end of connecting plate 822 and door plant 2's diapire fixed connection.
Through the arrangement, the gravity of the door panel 2 is concentrated on the guide wheel 81 at the lower part of the door panel 2, so that the door panel is tightly attached to the upper surface of the floating guide rail 7 to roll; when the door panels 2 are in the opening process, the guide wheels 81 on the two door panels 2 roll on the two guide surfaces 73 respectively, at the moment, the two door panels 2 move horizontally inside the outer mask of the cabinet body in a matched mode, before the two door panels 2 are closed, the guide wheels 81 of the two door panels 2 are located on the floating guide slope surfaces 74, the two door panels 2 can float upwards under the guide of the sliding rails and the sliding seats, the floating upwards stops when the guide wheels 81 are located on the upper wall of the protruding section 71, at the moment, the upper surface convex surfaces 21 of the two door panels 2 are located on the same plane with the outer surface of the outer mask of the cabinet body, in other words, when the door panels 2 are closed, the outer surfaces of the outer mask of the cabinet body can be flush, and therefore the cabinet is more attractive.
In this embodiment, as shown in fig. 4 and 5, the skylight structure further includes a linkage mechanism 9; the linkage mechanism 9 comprises two transmission shafts 91 which are coaxially arranged; wherein, the two transmission shafts 91 are rotatably connected on the inner side wall of the end beam 11 at one side far away from the stepping motor 32; and the opposite ends of the two transmission shafts 91 are spaced apart.
The end parts of the opposite ends of the two transmission shafts 91 are fixedly connected with first bevel gears 92;
the end parts of the two transmission shafts 91 opposite to each other are fixedly connected with second bevel gears 93;
the end parts of the two-way screw rods 31 far away from one end of the stepping motor 32 are fixedly connected with third bevel gears 94 which are respectively meshed with the two second bevel gears 93;
a fourth bevel gear 95 meshed with the two first bevel gears 92 is arranged between the opposite ends of the two transmission shafts 91; wherein the fourth bevel gear 95 is fixedly connected with a rotating shaft 96 which is rotatably connected to the end beam 11.
Through the arrangement, the two transmission shafts 91 and the two bidirectional screws 31 form a closed-loop motion system; if the linkage mechanism 9 is not arranged, the two door panels 2 are controlled to move only by the two stepping motors 32, so that once one stepping motor 32 is out of step, the rotation angles of the two stepping motors 32 are different, and the stepping motor 32 which moves in advance is overloaded and tripped due to overlarge load moment.
In the embodiment, due to the arrangement of the linkage mechanism 9, the two bidirectional screws 31 are kept to rotate synchronously under the linkage of the bevel gears and the two transmission shafts 91, so that the problems that one door panel 2 is large in opening distance and one door panel 2 is small in opening distance due to the fact that the stepping motor 32 is out of step can be avoided.
In order to manually open/close the door panel 2 when an electric failure occurs, in the present embodiment, a fixing seat 97 is fixedly installed on the end beam 11; the rotating shaft 96 is rotatably connected to the fixed seat 97, and one end of the rotating shaft 96, which is far away from the fourth bevel gear 95, penetrates through the end beam 11 and the fixed seat 97 to be fixedly connected with a manual operating shaft 98.
In order to facilitate the rotation of the manual operating shaft 98, in the present embodiment, the manual operating shaft 98 is a hexagonal shaft, which is suitable for a hexagonal wrench.
So, when taking place electrical failure, can rotate manual operation axle 98 with the help of the spanner, so alright drive pivot 96 rotatory, and then drive two transmission shafts 91 through engaged with fourth bevel gear 95 and first bevel gear 92 and rotate, and then drive two-way lead screw 31 through engaged with second bevel gear 93 and third bevel gear 94 and rotate, and then drive nut slider 33 displacement on the two-way lead screw 31 to this realization is opened/is closed the mesh of door plant 2.
As can be seen, the linkage mechanism 9 in the present embodiment has two functions, one of which is: a closed-loop motion system can be formed between the two bidirectional screw rods 31 and other components, so that the problem of door panel 2 opening/closing failure caused by step loss of the stepping motor 32 is solved; secondly, the operation of manually opening/closing the door panel 2 when the electric power fails avoids the need for complicated disassembly work during maintenance.
The implementation principle is as follows:
when the two door panels 2 need to be closed, the two stepping motors 32 drive the two nut sliders 33 to move towards the direction of closing, so that the two door panels 2 are closed gradually towards the middle, in the process, the gravity of the door panel 2 is concentrated on the guide wheel 81 at the lower part of the door panel 2, and the door panel 2 is forced to cling to the upper surface of the floating guide rail 7 to roll, at the moment, the two door panels 2 horizontally move in the outer mask of the adapted cabinet body, before the two door panels 2 are closed, when the guide wheels 81 of the two door panels 2 are positioned on the floating guide slope surfaces 74, the two door panels 2 can float upwards under the guide of the sliding rails and the sliding seats until the guide wheels 81 are positioned on the upper wall of the protruding section 71 and stop floating upwards, at the moment, the convex surfaces 21 of the upper surfaces of the two door panels 2 and the outer surface of the outer mask of the cabinet body are positioned in the same plane, in other words, when the door panels 2 are closed, the outer surfaces of the outer mask of the cabinet body can be flush, and therefore the appearance is more attractive.
Similarly, when the door panel 2 needs to be opened, the two door panels 2 can move in opposite directions only by controlling the two stepping motors 32 to rotate reversely, and finally are collected in the cabinet.
And when door plant 2 is closed, if when having the rainwater, because the looks remote site of door plant 2 is equipped with and sinks rank 24 and sink rank 23, and be provided with the sealing strip, so when door plant 2 is closed, the sealing strip is extrudeed the compression, in order to seal the crack of two door plant 2, make the rainwater leak from this crack, the rainwater only can flow to the both sides and the afterbody of door plant 2, the rainwater that flows to door plant 2 both sides can directly get into guiding gutter 5, the rainwater that flows to door plant 2 afterbody then can flow into stagnant water groove 6, flow by stagnant water groove 6 again and collect to catchment groove 4 in, finally discharge from catchment groove 4's outlet pipe 41, so in order to realize water-proof effects.
Above only the typical example of the utility model discloses, in addition, the utility model discloses can also have other multiple concrete implementation manners, all adopt the technical scheme that equivalent replacement or equivalent transform formed, all fall in the utility model discloses the scope of claiming.

Claims (10)

1. An outdoor rainproof symmetrical double-door skylight structure comprises a window frame and two door plates arranged on the window frame, wherein the window frame comprises two end beams and two side beams, and the two end beams and the two side beams are arranged in an enclosing manner to form a rectangular frame structure; it is characterized by also comprising:
the lead screw motion module is arranged on the window frame, the two door plates are connected with the lead screw motion module, and the lead screw motion module is used for driving the two door plates to move along the length direction of the side beam and towards the direction of mutual approaching/departing;
the water collecting groove is arranged on the side wall of the end beam of the window frame and extends along the length direction of the end beam;
the guide grooves comprise two groups which are respectively arranged on the side walls of the two side beams and extend along the length direction of the side beams; one end of the diversion trench, which is close to the water collection trench, extends to the water collection trench;
and two water stopping grooves extending along the width direction of the door plate are formed in the side walls of the two door plates, which are opposite to each other, and two ends of each water stopping groove respectively extend to the upper parts of the two diversion grooves.
2. The outdoor rainproof symmetrical double-door skylight structure of claim 1, wherein the lower wall of one of the two door panels is provided with a sunken step, and the upper wall of the other door panel is provided with an upper sunken step matched with the sunken step; the bottom wall of the upper sinking step is provided with a sealing groove extending along the length direction of the upper sinking step; and a sealing strip is embedded in the sealing groove.
3. The structure of claim 1, wherein the upper wall of the door panel near one end of the diversion trench is provided with a diversion chute inclined toward one side of the diversion trench.
4. The outdoor rainproof symmetrical double-door skylight structure of claim 3, wherein a water outlet pipe communicated with the water collection tank is arranged at the bottom of the water collection tank.
5. The outdoor weatherproof symmetrical double door skylight structure of any of claims 1-4, further comprising:
the floating guide rails comprise two groups which are respectively arranged on the outer side walls of the two side beams of the window frame and extend along the length direction of the side beams; the middle part of the upper wall of the floating guide rail protrudes upwards to form a protruding section;
the floating module comprises two guide wheels which are respectively arranged at the lower parts of the two ends of the door panel and two linear motion components which are respectively arranged at the lower parts of the two ends of the door panel; the guide wheel is movably arranged on the guide rail, and when the guide wheel moves to the protruding section, the door plate is driven to move upwards through the linear motion assembly.
6. The outdoor rainproof symmetrical double-door skylight structure of claim 5, wherein the lead screw motion module comprises two bidirectional lead screws which are respectively rotatably connected to the inner sides of the two side beams, and a stepping motor which is arranged on the window frame and used for driving the bidirectional lead screws to rotate; two nut sliding blocks are connected to the two-way screw rods in a threaded mode, and the two nut sliding blocks are arranged on the two thread sections of the two-way screw rods respectively.
7. The outdoor rainproof symmetrical double-door skylight structure of claim 6, wherein the linear motion assembly comprises a slide rail which is fixedly installed on the side wall of the nut slide block and is vertically arranged, and a slide seat which is slidably connected to the slide rail and can move along the height direction of the slide rail; wherein the sliding seat is fixedly connected with the door panel.
8. The outdoor weather-proof symmetrical double-door skylight structure of claim 7, further comprising a linkage mechanism; the linkage mechanism comprises two transmission shafts which are coaxially arranged; wherein, the two transmission shafts are both rotationally connected on the inner side wall of the end beam at one side far away from the stepping motor; and the opposite ends of the two transmission shafts are arranged at intervals;
the end parts of the opposite ends of the two transmission shafts are fixedly connected with first bevel gears;
the end parts of the two transmission shafts, which are far away from the ends, are fixedly connected with second bevel gears;
the end parts of the two bidirectional screw rods, which are far away from one end of the stepping motor, are fixedly connected with third bevel gears which are respectively meshed with the two second bevel gears;
a fourth bevel gear which is respectively meshed with the two first bevel gears is arranged between the opposite ends of the two transmission shafts; and the fourth bevel gear is fixedly connected with a rotating shaft which is rotatably connected to the end beam.
9. The outdoor rainproof symmetrical double-door skylight structure of claim 8, wherein the end beams are fixedly provided with fixing seats; the rotating shaft is rotatably connected to the fixing seat, and one end, far away from the fourth bevel gear, of the rotating shaft penetrates out of the end beam and is fixedly connected with a manual operation shaft.
10. The outdoor weather-proof symmetrical double-door skylight structure of claim 9, wherein the manual operating shaft is a hexagonal shaft.
CN202120173676.6U 2021-01-21 2021-01-21 Outdoor rain-proof symmetrical formula two skylight structures that open door Expired - Fee Related CN213990415U (en)

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CN202120173676.6U CN213990415U (en) 2021-01-21 2021-01-21 Outdoor rain-proof symmetrical formula two skylight structures that open door

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Application Number Priority Date Filing Date Title
CN202120173676.6U CN213990415U (en) 2021-01-21 2021-01-21 Outdoor rain-proof symmetrical formula two skylight structures that open door

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114851816A (en) * 2022-04-28 2022-08-05 东风越野车有限公司 Large-size telescopic skylight with bulletproof function and special combat vehicle with large-size telescopic skylight

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114851816A (en) * 2022-04-28 2022-08-05 东风越野车有限公司 Large-size telescopic skylight with bulletproof function and special combat vehicle with large-size telescopic skylight

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