CN216788142U - Photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating - Google Patents

Abstract

The utility model provides a photovoltaic building integrated gable bay window convenient for airing, storing clothes, ventilating and insulating heat, which comprises bay windowsills correspondingly arranged at the outer side of a gable on each floor and an L-shaped movable window arranged between an upper bay windowsill and a lower bay windowsill in a turnover mode, wherein: the L-shaped movable window divides the convex window space into an upper part and a lower part, and the front surface of the indoor space at the lower part is provided with an opaque solar photovoltaic panel; a lifting clothes-horse is transversely arranged in the outdoor space at the upper part, and a plurality of semitransparent solar photovoltaic panels are arranged at the ventilation opening on the front side of the outdoor space. This building integrated photovoltaic gable bay window utilizes the gable bay window of not counting the area, divide into indoor space and outdoor space two parts with the bay window space through L type movable window to utilize the ventilation fan that indoor outer space both sides were arranged to provide mechanical ventilation, finally reach convenient sunning, ventilation, thermal-insulated, air conditioner, solar energy power generation's new function, and accord with the building design standard requirement.

Description

Photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating

Technical Field

The utility model relates to the field of building design, in particular to a photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating clothes.

Background

At present, the house generally adopts the bay window design to make full use of space, improve daylighting ventilation. Whereas a conventional residential bay window is shown in figure 1. The inner space can be used as a seat and a table. The use of the external space is three: 1) the upper and lower spaces outside the bay window are used as outdoor machine positions; 2) the left space and the right space outside the convex window are used as the outdoor space of the air conditioner;

3) the exterior of the bay window has no utility. In addition, the bay window part is not usually counted as the building area and is used as the presenting area, which is beneficial to improving the space utility efficiency and bringing happiness to the residents.

The prior bay window has the following problems in the technology: 1) the upper and lower spaces outside the bay window and the left and right spaces outside the bay window are used as the spaces of the outdoor unit of the air conditioner, so that the installation and the maintenance are inconvenient and sanitary dead corners are formed; 2) the outer space of the bay window is not used, so that the bay window becomes a sanitary dead angle; 3) the side surface of the convex window is used as the space of the air conditioner outdoor unit, so that the window opening width of a room is reduced, and the ventilation is influenced; 4) if the existing bay window bears the airing function, the ventilation is affected; 5) the existing bay window is basically arranged on the south side of a building, and the bay window on the gable wall of the building is not utilized to provide the functions of airing and storing clothes.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is as follows: aiming at the defects of the existing house bay window, the photovoltaic building integrated bay wall bay window with the functions of convenient airing, clothes storage, ventilation and heat insulation on the building bay wall is provided.

The utility model adopts the following technical scheme for solving the technical problems:

the utility model provides a convenient sunning stores up clothing ventilation heat-insulating photovoltaic building integration gable bay window, this gable bay window sets up in upper and lower two including corresponding the protruding windowsill arranged in every floor gable outside with can overturning L type movable window between the protruding windowsill, wherein:

the L-shaped movable window divides the convex window space into an upper part and a lower part, and the front surface of the indoor space at the lower part is provided with an opaque solar photovoltaic panel; the lifting clothes-horse is transversely arranged in the outdoor space at the upper part, and a plurality of semitransparent solar photovoltaic panels are arranged at the ventilation opening on the front side of the outdoor space.

Furthermore, the cross section of the convex windowsill is of an L-shaped structure, the height from the floor is 400-800mm, and the height of the convex windowsill from the floor is 400-800 mm.

Further preferably, the cross section of the convex windowsill is of an L-shaped structure, the height of the convex windowsill from a floor is 600mm, and the height of the convex windowsill from the floor is 600 mm.

Furthermore, the indoor space forms a clothes storage space, and a clothes storage support is transversely arranged in the indoor space and used for bearing a clothes airing cross rod of the lifting clothes airing rod.

Further preferably, a push-pull louver door is arranged on the convex windowsill near the surface of the inner wall and used for closing or opening the indoor space.

Furthermore, the cross section of the L-shaped movable window is of an L-shaped structure and overturns by taking a transversely arranged crossed shaft as a center.

Furthermore, when the L-shaped movable window is in a closed state, the vertical window frame is in sealing connection with the bottom of the upper layer of the convex window sill, and the horizontal window frame is slightly inclined downwards and is in sealing connection with the window frames of the opaque solar photovoltaic panels on the front side and the two sides.

Further preferably, when the L-shaped movable window is closed, the L-shaped movable window is turned and opened counterclockwise indoors around the intersecting axis thereof, and the turning angle is 0 to 90 °.

Furthermore, when the L-shaped movable window is in an opening state, the vertical window frame inclines towards the indoor and forms a gap with the bottom of the upper layer of the convex windowsill, and the horizontal window frame inclines towards the outdoor and forms a gap with the window frames of the opaque solar photovoltaic panels on the front side and the two sides.

Further preferably, when the L-shaped movable window is in an open state, the L-shaped movable window is turned and closed clockwise outdoors around the intersecting axis thereof, and the turning angle is 90 to 0 °.

More preferably, the roof glass of the L-shaped movable window is disposed at an outdoor position of the window frame.

Furthermore, the window frames on two sides of the horizontally arranged overhead glass of the L-shaped movable window are provided with drainage guide grooves.

Still further preferably, a drainage gap corresponding to the top glass is transversely formed on a window frame of the opaque solar photovoltaic panel on the front side of the L-shaped movable window.

Further, at least one side of the indoor space is provided with an indoor ventilation fan close to the top, and the indoor ventilation fan is located below the outdoor ventilation fan.

Furthermore, the bottom of the convex windowsill on the upper layer is provided with at least one electric driver, and the electric driver is connected with the L-shaped movable window through a soft chain.

Furthermore, the wall bodies on two sides of the indoor space are provided with at least one lifting clothes airing rod and a ventilating fan switch.

Further, at least one side of the outdoor space is provided with an outdoor ventilation fan close to the bottom, and the outdoor ventilation fan is located below the lifting clothes airing rod.

Further, at least one end of the convex windowsill is provided with an air-conditioning outdoor unit platform, an air-conditioning outdoor unit position is arranged above the air-conditioning outdoor unit platform, and an inner wall body of the air-conditioning outdoor unit platform is provided with a refrigerant pipe hole communicated with the inside of the room.

Further preferably, at least one side of the air conditioner outdoor unit position is provided with an openable access door, and the access door is positioned below the indoor ventilation fan.

Furthermore, a plurality of the semitransparent solar photovoltaic panels are arranged side by side from top to bottom, and a ventilation gap is reserved between the top and the bottom.

By adopting the technical scheme, compared with the prior art, the utility model has the following technical effects:

the photovoltaic building integrated gable convex window provided by the utility model utilizes the gable convex window without the area, the convex window space is divided into an indoor space and an outdoor space through the L-shaped movable window, and the sizes of all functional spaces are calculated finely, so that the semitransparent and opaque solar panels are respectively arranged on the front surfaces of the indoor and outdoor spaces, and the airing and power generation functions are taken into consideration; mechanical ventilation is provided by using ventilation fans arranged on two sides of indoor and outdoor spaces, so that the airing speed is increased, and the hanging and airing are convenient; finally, the novel functions of convenient airing, ventilation, heat insulation, air conditioning and solar power generation are achieved, and the requirements of building design specifications are met.

Drawings

FIG. 1 is a schematic view of a conventional bay window for a residence;

FIG. 2 is a schematic view of the left overall appearance structure of the photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating clothes;

FIG. 3 is a first schematic view of a vertical cross-sectional structure of a photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating clothes;

FIG. 4 is a second schematic view of a vertical sectional structure of the gable convex window of the building integrated photovoltaic structure convenient for airing, storing, ventilating and insulating clothes;

FIG. 5 is a schematic view of a partial cross-sectional structure of a photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating clothes according to the utility model;

FIG. 6 is a second schematic sectional view of a part of the photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating clothes;

FIG. 7 is a schematic view of the overall structure of a photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating clothes;

FIG. 8 is a schematic diagram of the right side overall appearance structure of the photovoltaic building integrated gable convex window facilitating airing, clothes storage, ventilation and heat insulation;

FIG. 9 is a schematic view of an internal view of a building integrated photovoltaic gable bay window facilitating airing, clothes storage, ventilation and heat insulation according to the utility model;

FIG. 10 is a schematic view of an internal horizontal section structure of a photovoltaic building integrated gable convex window convenient for airing, storing, ventilating and insulating clothes;

wherein the reference symbols are:

01-convex windowsill, 02-convex window inner space, 03-convex window outer space, 04-casement window, 05-glass window, 06-air conditioner outdoor unit position and reserved refrigerant pipe hole;

100-gable bay window, 101-bay windowsill, 102-indoor space, 103-outdoor space, 104-opaque solar photovoltaic panel, 105-translucent solar photovoltaic panel, 106-air conditioner outdoor unit platform, 107-air conditioner outdoor unit position, 108-refrigerant pipe hole, 109-access door, 110-sliding louver door, 111-outdoor ventilating fan, 112-side translucent solar photovoltaic panel, 113-L type movable window, 114-lifting clothes airing rod, 115-clothes storage support, 116-drainage gap, 117-overhead glass, 118-drainage guide groove, 119-indoor ventilating fan, 120-side opaque solar photovoltaic panel, 121-electric driver, 122-flexible chain, 123-air conditioner indoor unit position, 124-lifting clothes airing rod and ventilating fan switch.

Detailed Description

The technical solution of the present invention is further described in detail below with reference to the accompanying drawings.

In some embodiments, as shown in fig. 2, 3 and 4, a photovoltaic building integrated gable bay window for facilitating airing, storing, ventilating and insulating clothes is provided, the gable bay window 100 includes bay window platforms 101 correspondingly arranged on the outer side of the gable of each floor, and L-shaped movable windows 113 capable of being arranged between the upper and lower bay window platforms 101 in a turnover manner, and the main scheme is to finely calculate the size of each functional space by using the special design of the bay window outside the gable without area and the L-shaped movable windows 113, so as to achieve new functions of facilitating airing, ventilating, insulating heat, air conditioning and solar power generation.

In one embodiment, as shown in fig. 2, 3, 4 and 5, the gable bay window structure 100 adopted by the integrated bay window for photovoltaic building for facilitating air-drying, ventilation, heat insulation, air conditioning and solar power generation is used as an important heat insulation and ventilation part in a house, and the bay window space outside the gable is innovatively divided into two independent spaces, namely an indoor space 102 and an outdoor space 103, by using the structural design of the L-shaped movable window 113. Specifically, the front surface of the indoor space 102 below the L-shaped movable window 113 is provided with an opaque solar photovoltaic panel 104, and the opaque solar photovoltaic panel 104 is backed with a thermal insulation material for photovoltaic power generation and thermal insulation; and a lifting clothes-horse 114 is transversely arranged in the outdoor space 103 above the L-shaped movable window 113, and a plurality of semitransparent solar photovoltaic panels 105 are arranged at a ventilation opening on the front surface of the outdoor space 103, so that clothes-drying, ventilation and photovoltaic power generation are realized.

In one embodiment, as shown in fig. 3 and 4, the cross section of the protruding windowsill 101 is an L-shaped structure, the height from the floor is 400-. Preferably, the height of the bay window 101 from the floor is 600mm, and the height of the overhanging outer wall is 600 mm. As an embodiment, that is, the indoor space 102 of the bay window is partially composed of a space surrounded by a top L-shaped movable window 113 having a height 600mm from the floor, a height 600mm from the outer wall of the bay window, a front side and both sides of the window, and a height 2000 mm from the floor, and its main functions are clothes storage, ventilation and heat insulation.

In one embodiment, as shown in fig. 3, 4 and 5, the indoor space 102 forms a clothes storage space, and a clothes storage bracket 115 is transversely arranged in the indoor space for receiving a clothes drying cross bar of the lifting clothes drying rod 114. When the lifting clothes-drying rod 114 descends to a height of 1000mm from the top surface of the convex windowsill 101, the connection between the clothes-drying rod on the lifting clothes-drying rod 114 and the electric lifting rope hook can be released, and the clothes-drying rod is converted into a clothes storage rack supporting rod for bearing. After the electric lifting rope returns to the airing area of the outdoor space 103, the L-shaped movable window 113 can be closed to enter a clothes storage state.

In one embodiment, as shown in fig. 3, 4 and 5, a push-pull louver door 110 is provided on the convex sill 101 near the inner cavity surface for closing or opening the indoor space 102 to facilitate the storage and taking of clothes.

In one embodiment, as shown in fig. 3, 4, 5, 6 and 7, an L-shaped movable window 113 is mounted on a metal sash, which is mainly composed of an aluminum alloy frame and a roof glass 117, at the bottom position of the upper bay 101 and at the top of the glass window. The cross section of the L-shaped movable window 113 is in an L-shaped structure, and is turned over with the cross axis arranged transversely as the center. Namely, the movable window is rotated around the L-shaped intersection axis, and the turning angle of the L-shaped movable window 113 is specifically rotated according to actual needs.

Specifically, when the L-shaped movable window 113 is in the closed state, the vertical window frame is in sealing engagement with the bottom of the upper-layer raised window platform 101, and the horizontal window frame is slightly inclined downward and in sealing engagement with the window frames of the front and two sides of the opaque solar photovoltaic panels 104. When the L-shaped movable window 113 needs to be opened, the L-shaped movable window 113 is turned and opened anticlockwise indoors by taking the crossed shaft as the center, the turning angle is 0-90 degrees, the L-shaped movable window 113 is gradually opened at the moment, the indoor space 102 at the lower part is communicated with the outdoor space 103 at the top, and hot air gathered in an indoor ceiling can be discharged outdoors on the top of the convex window.

On the other hand, when the initial state of the L-shaped movable window 113 is the open state, the vertical window frame thereof is inclined to the indoor and forms a gap with the bottom of the upper convex windowsill 101, and the horizontal window frame thereof is inclined to the outdoor and forms a gap with the window frames of the front and both sides of the opaque solar photovoltaic panels 104. When the L-shaped movable window 113 needs to be closed, the L-shaped movable window 113 is turned clockwise around the intersecting axis thereof to be closed outdoors, and the turning angle is 90 to 0 °, at this time, the L-shaped movable window 113 is gradually closed, and the communication between the indoor space 102 at the lower portion and the outdoor space 103 at the top portion is blocked.

In one embodiment, as shown in FIGS. 3, 4, 5, 6 and 7, the L-shaped movable window 113 is angled at 90-120 to accommodate the different bay window height and width combinations. Preferably, the L-shaped movable window 113 has an included angle of 90-110 deg. More preferably, the L-shaped movable window 113 has an included angle of 90-100. According to the standard of use, when the L-shaped movable window 113 is closed, the vertical window frame is engaged with the bottom of the upper-layer convex window platform 101, and the horizontal window frame is slightly inclined downwards and engaged with the window frames of the front and two sides of the opaque solar photovoltaic panels 104.

In one embodiment, as shown in fig. 5, 6 and 7, the roof glass 117 of the L-shaped movable window 113 is disposed at an outdoor position of the window frame. And drainage guide grooves 118 are provided on the window frames at both sides of the horizontally arranged roof glass 117 of the L-shaped movable window 113. Correspondingly, a drainage gap 116 corresponding to the overhead glass 117 is transversely arranged on the window frame of the opaque solar photovoltaic panel (104) on the front surface of the L-shaped movable window 113.

In addition, in order to make the L-shaped movable window 113 completely block the indoor space 102 and the outdoor space 103 in the closed state, a rubber gasket is disposed between the frame of the L-shaped movable window 113 and the frame of the solar photovoltaic panel 104 corresponding thereto to completely seal the L-shaped movable window 113 and prevent outdoor rainwater from penetrating into the indoor space through a gap between the L-shaped movable window 113 and the frame of the solar photovoltaic panel 104.

In one embodiment, as shown in fig. 6 and 8, an indoor ventilating fan 119 is disposed at a position near a ceiling of at least one side of the indoor space 102, an air inlet of the indoor ventilating fan 119 is communicated with the outside, and the indoor ventilating fan 119 is disposed at a position below the outdoor ventilating fan 111. Preferably, two indoor ventilating fans 119 are disposed at both sides of the indoor space 102 near the top, respectively, to enhance ventilation in the airing area and accelerate drying.

Further, it should be noted that, as shown in fig. 7 and 8, side opaque solar photovoltaic panels 120 are provided at both sides of the clothes storage rack 115 in the indoor space 102, and the side translucent solar photovoltaic panels 120 are also located at positions above the indoor ventilating fan 119.

In one embodiment, as shown in fig. 9 and 10, at least one electric driver 121 is arranged at the bottom of the upper bay 101, the electric driver 121 is connected with the L-shaped movable window 113 through a soft chain 122, and the L-shaped window can be easily opened and closed by using the soft chain 122.

In one embodiment, as shown in fig. 9 and 10, at least one lifting clothes-horse and ventilating fan switch 124 is disposed on the wall at both sides of the indoor space 102. The lifting clothes-horse and ventilation fan switch 124 is electrically connected with the outdoor ventilation fan 111, the lifting clothes-horse 114, the indoor ventilation fan 119 and the electric driver 121 respectively so as to control the opening of the outdoor ventilation fan 111, the lifting clothes-horse 114, the indoor ventilation fan 119 and the electric driver 121, thereby facilitating the airing and ventilation.

In one embodiment, as shown in fig. 6, 7 and 8, the outdoor space 103 is composed of the aforementioned L-shaped movable window 113 with a height of 2000 mm from the floor, an exposed wall surface 600mm, a translucent solar glass panel on the front and both sides, and a space to the bottom of the convex windowsill 101 on the upper layer; the main functions of the solar clothes airing rack are placing an air conditioner outdoor unit, facilitating clothes airing and storing, ventilating and insulating and solar power generation. Specifically, at least one side of the outdoor space 103 is provided with an outdoor ventilating fan 111 near the bottom, and the outdoor ventilating fan 111 is located below the elevation airing bars 114. Preferably, two outdoor ventilation fans 111 are respectively arranged at two sides of the bay window outdoor space 103 near the bottom to enhance ventilation in the airing area and accelerate drying.

Further, it should be noted that, as shown in fig. 6, 7 and 8, side translucent solar photovoltaic panels 112 are provided at both sides of the elevating clothes airing bar 114, and the side translucent solar photovoltaic panels 112 are also located at a position above the outdoor ventilating fan 111. The lifting clothes-horse 114 adopts an electric lifting clothes-horse, when the L-shaped movable window 114 is in an opening state, the outdoor space 103 of the convex window is vertically communicated with the indoor space 102 below, and the lifting clothes-horse 114 can be lowered to a position 600mm away from the top surface of the convex window platform 101, so that clothes can be hung conveniently.

In one embodiment, as shown in fig. 2 and 3, at least one end of the protruding windowsill 101 is configured as an outdoor unit platform 106, an outdoor unit station 107 is disposed above the outdoor unit platform 106 for installing an outdoor unit, and an inner wall of the outdoor unit station is provided with a refrigerant pipe hole 108 communicating with the indoor space. The outdoor unit of the air conditioner installed in the indoor unit 123 of the air conditioner is connected with the outdoor unit of the air conditioner installed in the outdoor unit 107 of the air conditioner through the pipeline passing through the refrigerant pipe hole 108 in the shortest distance, so that energy is saved.

In addition, an openable access door 109 is arranged on at least one side of the air conditioner outdoor unit position 107, and the access door 109 is positioned below the indoor ventilating fan 119, so that the air conditioner outdoor unit can be conveniently overhauled and maintained. The air conditioner outdoor unit position 109 is creatively arranged at the bottom position of the bay window platform 101 from the top to the upper layer of the glass window, has certain concealment and does not block the bay window for ventilation.

In one embodiment, as shown in fig. 2, 3, 4, 5 and 6, a plurality of translucent solar photovoltaic panels 105 are arranged side by side up and down, and the solar photovoltaic panels 106 are of a translucent design and have a certain lighting function. In addition, it is worth noting that the translucent solar photovoltaic panels 105 arranged side by side up and down are generally arranged in an inclined manner, and a ventilation gap of 100mm is reserved between the upper side and the lower side, so that ventilation and rain prevention are facilitated.

The embodiments of the present invention have been described in detail, but the embodiments are merely examples, and the present invention is not limited to the embodiments described above. Any equivalent modifications or alterations to this practice will occur to those skilled in the art and are intended to be within the scope of this invention. Accordingly, equivalent changes and modifications made without departing from the spirit and scope of the present invention should be covered by the present invention.

Claims (19)

1. The utility model provides a convenient clothing ventilation heat-proof photovoltaic building integration gable convex window is stored up in sunning, its characterized in that, this gable convex window (100) including correspond arrange in protruding windowsill (101) in every floor gable outside with can overturn set up in upper and lower two L type activity window (113) between protruding windowsill (101), wherein:

the L-shaped movable window (113) divides the bay window space into an upper part and a lower part, and the front surface of the indoor space (102) at the lower part is provided with an opaque solar photovoltaic panel (104); a lifting clothes-horse (114) is transversely arranged in the outdoor space (103) at the upper part, and a plurality of semitransparent solar photovoltaic panels (105) are arranged at the ventilation opening on the front surface of the outdoor space (103).

2. The photovoltaic building integrated gable convex window of claim 1, wherein the cross section of the convex windowsill (101) is of an L-shaped structure, the height from the floor is 400-800mm, and the height of the raised windowsill is 400-800 mm.

3. The gable bay window of claim 1, wherein the interior space (102) constitutes a clothes storage space, and a clothes storage support (115) is transversely disposed therein for receiving a clothes drying rail of the lifting clothes drying rod (114).

4. The building-integrated photovoltaic gable bay window of claim 3, wherein a push-pull louver door (110) is provided on the bay window sill (101) near the inner cavity surface for closing or opening the indoor space (102).

5. The building-integrated photovoltaic gable convex window of claim 1, wherein the cross section of the L-shaped movable window (113) is in an L-shaped structure and is turned around a cross axis arranged transversely.

6. The gable bay window of claim 5, wherein the L-shaped movable window (113) has a vertical frame that is in sealing engagement with the bottom of the bay sill (101) on the upper layer when closed, and a horizontal frame that is slightly tilted downward and in sealing engagement with the front and both sides of the frame of the opaque solar photovoltaic panels (104).

7. The building-integrated photovoltaic gable convex window of claim 6, wherein the L-shaped movable window (113) is turned and opened counterclockwise indoors around the crossing axis thereof in the closed state, and the turning angle is 0-90 °.

8. The building-integrated photovoltaic gable convex window of claim 5, wherein when the L-shaped movable window (113) is in an open state, the vertical window frame of the window is inclined towards the indoor and forms a gap with the bottom of the upper layer of the convex windowsill (101), and the horizontal window frame of the window is inclined towards the outdoor and forms a gap with the window frames of the front and two sides of the opaque solar photovoltaic panels (104).

9. The gable bay window of claim 8, wherein the L-shaped movable window (113) is turned clockwise outdoors around its axis of intersection in the open state, and the angle of the turn is 90-0 °.

10. The PV building-integrated gable convex window of claim 5, wherein the top glass (117) of the L-shaped movable window (113) is disposed at the outdoor position of the window frame.

11. The gable bay window of claim 10, wherein the L-shaped movable window (113) has drainage channels (118) formed on the window frames at both sides of the horizontally arranged roof glass (117).

12. The pv (building integrated) gable bay window of claim 11, wherein the frame of the opaque solar photovoltaic panel (104) on the front side of the L-shaped movable window (113) is laterally opened with a drainage gap (116) corresponding to the top-mounted glass (117).

13. The gable bay window of claim 1, wherein an indoor ventilation fan (119) is disposed on at least one side of the indoor space (102) near the top, and the indoor ventilation fan (119) is disposed below the outdoor ventilation fan (111).

14. The building-integrated photovoltaic gable bay window of claim 1, wherein the bottom of the bay window sill (101) of the upper floor is provided with at least one electric driver (121), and the electric driver (121) is connected to the L-shaped movable window (113) through a soft chain (122).

15. The building-integrated photovoltaic gable bay window of claim 1, wherein the walls on both sides of the indoor space (102) are provided with at least one lifting clothes-horse and a ventilation fan switch (124).

16. The photovoltaic building integrated gable bay window of claim 1, wherein an outdoor ventilation fan (111) is disposed on at least one side of the outdoor space (103) near the bottom, and the outdoor ventilation fan (111) is located below the lifting clothes-horse (114).

17. The gable bay window of claim 1, wherein at least one end of the bay window platform (101) is configured as an outdoor unit platform (106), an outdoor unit location (107) is above the outdoor unit platform (106), and an inner wall of the bay window is provided with a refrigerant pipe hole (108) for communicating with a room.

18. The building-integrated photovoltaic gable bay window of claim 17, wherein the air conditioner outdoor unit (107) is provided with an openable access door (109) on at least one side, and the access door (109) is located below an indoor ventilation fan (119).

19. The building-integrated photovoltaic gable bay window of claim 1, wherein a plurality of the translucent solar photovoltaic panels (105) are arranged side by side up and down with a ventilation gap left therebetween.

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