CN211177368U - Double-open sliding door structure and air conditioner thereof - Google Patents

Abstract

The utility model discloses a two sliding door structures and air conditioner thereof, wherein, two sliding door structures of opening include: the sliding door assembly comprises two sliding doors symmetrically arranged at the air duct outlet, and the driving part comprises an opening and closing driving assembly for driving the sliding doors to extend or retract and a rotation driving assembly for driving the sliding doors to rotate; this application is through opening and shutting drive assembly and rotation driving assembly cooperation, when the air conditioner air guide, and the drive assembly drive sliding door that opens and shuts stretches out to through rotation driving assembly drive sliding door rotation in order to realize sweeping the wind, because the sliding door stretches out the wind channel export under the drive of the drive assembly that opens and shuts, consequently the mobile scope and the rotation angle of sliding door are big, have realized the purpose that the air conditioner is multi-functional, the air supply of wide-angle.

Description

Double-open sliding door structure and air conditioner thereof

Technical Field

The utility model relates to an air conditioner, more specifically say, it relates to a two sliding door structures and air conditioner that open.

Background

The vertical air conditioner is one of air conditioners, and the traditional vertical air conditioner rotates a sliding door assembly for a certain angle distance through a gear rack transmission structure, so that an air outlet is opened or closed, and the structure is complex.

Meanwhile, the wind sweeping function of the traditional vertical air conditioner is usually realized through the wind guide blades in the air outlet, the air supply angle is determined by the rotating angle of the wind guide blades, and the rotating angle of the wind guide blades is limited, so that the wind guide angle range of the traditional vertical air conditioner is limited, and the requirement of large-range air supply cannot be met.

Therefore, the prior art still needs to be improved and developed.

SUMMERY OF THE UTILITY MODEL

The utility model aims at not enough among the prior art, provide a two sliding door structures and air conditioner that open, reach the purpose that realizes that the air conditioner is multi-functional, the air supply of wide-angle.

The above technical purpose of the present invention can be achieved by the following technical solutions:

the utility model provides a two sliding door structures that open, wherein, is in including shell, setting sliding door subassembly on the shell and being used for the drive division of sliding door subassembly motion, the shell includes the front panel and sets up the wind channel export of front panel front end, sliding door subassembly includes that two symmetries set up the sliding door of wind channel exit, the drive division is including being used for the drive the sliding door stretches out or withdraws the drive subassembly that opens and shuts and be used for the drive the rotatory rotation drive subassembly of sliding door.

The double-open sliding door structure is characterized in that the shell further comprises an air duct upper side plate and an air duct lower side plate which are arranged on the inner side of the front panel, and the air duct upper side plate and the air duct lower side plate are respectively arranged at two ends of the air duct outlet; the driving part is arranged on the air duct upper side plate, the sliding door is connected with the driving part through an upper rotating supporting rod, and the sliding door is connected with the air duct lower side plate through a rotating connecting structure.

The double-open sliding door structure is characterized in that the opening and closing driving assembly comprises a driving motor and a connecting seat, the connecting seat comprises a driving base and a driving top cover detachably connected to the driving base, and the driving motor is connected to the driving base through a motor shaft sleeve; the air duct upper side plate is provided with a through hole matched with the motor shaft sleeve, the edge of the through hole is provided with a shoulder, and the shoulder faces towards the direction of the driving motor and is used for axially fixing the motor shaft sleeve.

The double-open sliding door structure, wherein, be provided with on the wind channel curb plate and be used for fixing driving motor's motor screw post and motor support column, the motor support column is used for supporting driving motor, driving motor passes through the fix with screw motor screw post.

The double-open sliding door structure, wherein, the drive base orientation driving motor's one end is provided with connecting sleeve, the one end of motor shaft sleeve pass through flat bit architecture connect in driving motor's pivot, the other end of motor shaft sleeve connect in connecting sleeve.

The double-opening sliding door structure is characterized in that the motor shaft sleeve is inserted into the connecting sleeve, and the motor shaft sleeve is fixedly connected with the connecting sleeve through the locking pin; the motor shaft sleeve is provided with a shaft sleeve hole, the connecting sleeve is provided with a connecting hole, and the locking pin penetrates through the shaft sleeve hole and the connecting hole and is used for enabling the motor shaft sleeve and the connecting sleeve to synchronously rotate.

The double-open sliding door structure is characterized in that the upper rotating support rod is arranged on the sliding door, and the rotating drive assembly comprises a rotating motor arranged in the drive base and a rotating connecting piece connected between the rotating motor and the upper rotating support rod; and a circumferential positioning structure is arranged between the rotary connecting piece and the upper rotary supporting rod.

Two divisions of sliding door structures, wherein, circumference location structure is including setting up expansion connector and setting on the swivelling joint spare are in on the swivel support pole and with the locating hole that expansion connector block is connected, the cross-section of expansion connector is the polygon setting, the locating hole with the cross-sectional shape of expansion connector is the same.

The double-open sliding door structure comprises a rotary connecting structure and a sliding door, wherein the rotary connecting structure comprises a lower rotary supporting rod and a rotary connecting rod, the lower rotary supporting rod is arranged on the sliding door, and the rotary connecting rod is arranged between the lower rotary supporting rod and the lower side plate of the air duct; one end of the rotary connecting rod is rotatably connected with the lower side plate of the air duct through a rotary shaft sleeve, and the other end of the rotary connecting rod is rotatably connected with the lower rotary supporting rod.

An air conditioner comprising the double-opening sliding door structure as described in any one of the above.

To sum up, the utility model discloses following beneficial effect has:

the utility model discloses a drive assembly and the cooperation of rotary drive subassembly open and shut, when the air conditioner air guide, drive assembly drive sliding door stretches out to through the rotation of rotary drive assembly drive sliding door in order to realize sweeping the wind, because the sliding door stretches out the air flue export under drive assembly's that opens and shuts drive, therefore the mobile scope and the rotation angle of sliding door are big, have realized the purpose that the air conditioner is multi-functional, the air supply of wide-angle.

Drawings

Fig. 1 is a schematic front structure diagram of the front panel in this embodiment.

Fig. 2 is a schematic view of the internal structure of the front panel in this embodiment.

Fig. 3 is a schematic structural view of the front panel of the present embodiment without the sliding door.

Fig. 4 is an exploded view of the double-opening sliding door structure according to the present embodiment.

Fig. 5 is an enlarged view at a in fig. 2.

Fig. 6 is an enlarged view at B in fig. 2.

Fig. 7 is an enlarged view at C in fig. 3.

Fig. 8 is an enlarged view at D in fig. 3.

Fig. 9 is a schematic view of the sliding door in a closed mode state.

Fig. 10 is a schematic view of another perspective of the sliding door in a closed mode state.

Fig. 11 is a schematic view of the sliding door in a wide-angle blowing mode.

Fig. 12 is a schematic view of the sliding door in a "no wind" mode state.

FIG. 13 is a schematic view of the sliding door in a "comfort" mode

In the figure: 10. a housing; 101. a front panel; 102. a motor screw post; 103. an upper side plate of the air duct; 104. a lower side plate of the air duct; 105. a motor support column; 106. an air duct outlet; 107. a shoulder; 20. a drive section; 201. a drive motor; 202. a motor shaft sleeve; 203. a drive cap; 204. a drive base; 205. a rotating connector; 206. a rotating connecting rod; 207. rotating the shaft sleeve; 208. a locking pin; 209. a rotating electric machine; 30. a sliding door assembly; 301. a sliding door; 302. the support rod is rotated upwards; 303. a lower rotary supporting rod.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

In the description of the present invention, it is to be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing the present invention and for simplicity in description, and are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and "disposed" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or may be connected through the interconnection of two elements or through the interaction of two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Example (b): a double-opening sliding door structure and an air conditioner thereof are disclosed, as shown in fig. 1 to 4, comprising a housing 10, a sliding door assembly 30 and a driving part 20, wherein the sliding door assembly 30 is arranged on the housing 10, and the driving part 20 is used for driving the sliding door assembly 30 to move. The housing 10 includes a front panel 101 and an air duct outlet 106, and the air duct outlet 106 is provided at the front end of the front panel 101 and is used for air conditioning; the sliding door assembly 30 comprises two sliding doors 301, and the two sliding doors 301 are symmetrically arranged at the air duct outlet 106; the driving part 20 includes an opening and closing driving component for driving the sliding door 301 to extend or retract, and a rotation driving component for driving the sliding door 301 to rotate.

When the air conditioner is used for supplying air, the driving part 20 drives the sliding door 301 to be opened, the opening and closing driving component drives the sliding door 301 to translate firstly, the sliding door 301 is pushed out of the air duct outlet 106 in a rotating mode, and then the rotating driving component drives the sliding door 301 to rotate. This application is through opening and shutting drive assembly and rotation drive assembly cooperation, and different air supply states are realized to control sliding door 301.

As shown in fig. 4 to 8, the housing 10 further includes an air duct upper side plate 103 and an air duct lower side plate 104, and the air duct upper side plate 103 and the air duct lower side plate 104 are both disposed on the inner side of the front panel 101 and are respectively disposed at the upper end and the lower end of the air duct outlet 106. The driving part 20 is arranged on the air duct upper side plate 103, the sliding door 301 is connected with the driving part 20 through an upper rotary supporting rod 302, and the sliding door 301 is connected with the air duct lower side plate 104 through a rotary connecting structure.

The utility model provides a two structures of opening sliding door 301 include that two symmetries set up the sliding door 301 in the wind channel air outlet department of air conditioner to the air conditioner is inside to be provided with and to open and shut drive assembly and the rotation driving subassembly that corresponds the setting with every sliding door 301, and drive assembly and the rotation driving subassembly that opens and shuts all connect in the sliding door 301 that corresponds through the connecting rod structure, opens with two sliding door 301 in order to realize.

The opening and closing driving assembly comprises a driving motor 201 and a connecting seat, the connecting seat comprises a driving base 204 and a driving top cover 203 detachably connected to the driving base 204, and the driving motor 201 is connected to the driving base 204 through a motor shaft sleeve 202. In this embodiment, the driving cap 203 is connected to the driving base 204 through a bayonet.

The air duct upper side plate 103 is provided with a through hole matched with the motor shaft sleeve 202, the edge of the through hole is provided with a shoulder 107, and the shoulder 107 faces towards the direction of the driving motor 201 and is used for axially fixing the motor shaft sleeve 202. The motor shaft sleeve 202 is matched with the rotating shaft of the driving motor 201, and the shoulder 107 on the air duct upper side plate 103 axially restrains the motor shaft sleeve 202, so that the motor shaft sleeve 202 rotates along with the rotation of the rotating shaft of the driving motor 201.

The air duct upper side plate 103 is provided with a motor screw column 102 and a motor support column 105, the motor screw column 102 is used for fixing the driving motor 201, the motor support column 105 is used for supporting the driving motor 201, and the driving motor 201 is fixed on the motor screw column 102 through screws. In the present embodiment, the front panel 101, the air duct upper side plate 103, the air duct lower side plate 104, the motor screw post 102, and the motor support post 105 are integrally formed by injection molding. The motor screw column 102 and the motor support column 105 are used for fixing and supporting the driving motor 201, and the driving motor 201 is fixed on the motor screw column 102 through screws.

The driving base 204 is provided with a connecting sleeve towards one end of the driving motor 201, one end of the motor shaft sleeve 202 is connected with the rotating shaft of the driving motor 201 through a flat position structure, and the other end of the motor shaft sleeve 202 is connected with the connecting sleeve. The motor shaft sleeve 202 is inserted into the connecting sleeve, and the motor shaft sleeve 202 is fixedly connected with the connecting sleeve through a locking pin 208; the motor shaft sleeve 202 is provided with a shaft sleeve hole, the connecting sleeve is provided with a connecting hole, and the locking pin 208 penetrates through the shaft sleeve hole and the connecting hole and is used for enabling the motor shaft sleeve 202 and the connecting sleeve to synchronously rotate.

The driving base 204 is matched with the extending section of the motor shaft sleeve 202, and the locking pin 208 passes through a connecting hole on the connecting sleeve and a shaft sleeve hole on the motor shaft sleeve 202 to realize the connection between the driving base 204 and the motor shaft sleeve 202, and the driving base 204 rotates along with the rotation of the motor shaft sleeve 202, and the rotation center is the connecting sleeve.

The upper rotary supporting rod 302 is arranged on the sliding door 301, and the rotary driving component comprises a rotary motor 209 arranged in the driving base 204 and a rotary connecting piece 205 connected between the rotary motor 209 and the upper rotary supporting rod 302; a circumferential positioning structure is arranged between the rotary connecting piece 205 and the upper rotary supporting rod 302. The rotating motor 209 rotates and moves with the driving base 204 by an arc distance, the rotating angle is the rotating angle of the driving base 204, and the rotating radius is the distance between the center line of the rotating shaft of the rotating motor 209 and the center line of the rotating shaft of the driving motor 201.

The circumference location structure is in including setting up inflation connector and setting on the swivel connected coupler 205 are in on the swivel support pole and with the locating hole that inflation connector block is connected, the cross-section of inflation connector is the polygon setting, the locating hole with the cross-sectional shape of inflation connector is the same.

In this embodiment, the rotation connecting element 205 is preferably a hexagonal crank, and an extending shaft of the rotation motor 209 is matched with a cylindrical hole of the hexagonal crank and is placed into the driving base 204 together for limiting and fixing. The sliding door 301 is connected to the hexagonal crank via the upper rotation support rod 302, and the sliding door 301 rotates with the rotation of the rotation motor 209.

The rotary connecting structure comprises a lower rotary supporting rod 303 and a rotary connecting rod 206, the lower rotary supporting rod 303 is arranged on the sliding door 301, and the rotary connecting rod 206 is arranged between the lower rotary supporting rod 303 and the air duct lower side plate 104; one end of the rotary connecting rod 206 is rotatably connected to the air duct lower side plate 104 through a rotary shaft sleeve 207, and the other end of the rotary connecting rod 206 is rotatably connected to the lower rotary supporting rod 303.

Specifically, the rotating shaft sleeve 207 is connected with a matching hole on the air duct lower side plate 104, rotating shafts are arranged at the upper end and the lower end of the rotating connecting rod 206, the rotating connecting rod 206 is matched with the rotating shaft sleeve 207 through a rotating shaft at the lower end, and the rotating connecting rod 206 is matched with the lower rotating support rod 303 through a rotating shaft at the upper end, so that the sliding door 301 is supported and rotates along with the rotation of the driving base 204.

The state of the sliding door in the closed mode is shown in fig. 9 and 10.

This application opens and shuts drive assembly and rotation driving assembly cooperation control sliding door 301's operating condition through reasonable setting, realizes multi-functionally, the wide-angle air supply.

As shown in fig. 11, when the air conditioner controls the sliding door 301 to open the wide-angle air supply mode, the driving motor 201 drives the driving base 204 to the most lateral side of the air duct outlet 106 through the motor shaft sleeve 202, then the rotating motor 209 drives the sliding door 301 to perform reciprocating rotation motion, and the air sent out from the inside of the air conditioner is sent out from the two sides and the middle of the air duct outlet 106 under the air guiding effect of the sliding door 301, so as to realize 180-degree wide-angle air supply.

As shown in fig. 12, when the air conditioner controls the sliding door 301 to open the "no-wind" blowing mode, the driving motor 201 drives the driving base 204 to the middle position of the air duct outlet 106 through the motor shaft sleeve 202, then the sliding doors 301 on the two sides are closed under the driving of the respective rotating motors 209, so as to block the air blown out from the middle of the air duct outlet 106 and guide the air blown out from the middle of the air duct outlet 106 to the two sides of the air duct outlet 106, at this time, the air blown out from the inside of the air conditioner is blown out only from the two sides of the air duct outlet 106, and the "no-wind" blowing on the front side of the air conditioner is realized.

As shown in fig. 13, when the air conditioner controls the sliding door 301 to open for "comfortable" air supply, the driving motor 201 drives the driving base 204 to the most lateral side of the air duct outlet 106 through the motor shaft sleeve 202, then the sliding doors 301 on both sides are driven by the respective rotating motors 209 to rotate to positions parallel to the front panel 101, and the cold air sent out from the air conditioner is directly blown out from the middle of the air duct outlet 106. Since there is a gap between the sliding door 301 and the front panel 101, when the air conditioner blows air, negative pressure exists in the gap between the sliding door 301 and the front panel 101, and thus indoor hot air is sucked into the middle of the air duct outlet 106 from the gap between the sliding door 301 and the front panel 101. At this time, the cool air sent from the inside of the air conditioner is mixed with the indoor hot air sucked from the gap between the sliding door 301 and the front panel 101, so that the actual outlet air temperature of the air conditioner is reduced, and the 'comfortable' air supply is realized.

An air conditioner comprising the double-opening sliding door structure as described above.

To sum up, this application is through opening and shutting drive assembly and rotation drive assembly cooperation, when the air conditioner air guide, and drive assembly drive sliding door that opens and shuts stretches out to through rotation drive assembly drive sliding door rotation in order to realize sweeping the wind, because the sliding door stretches out the wind channel export under drive assembly's that opens and shuts, consequently the mobile scope and the rotation angle of sliding door are big, have realized the purpose that the air conditioner is multi-functional, wide-angle air supply.

It is to be understood that the invention is not limited to the above-described embodiments, and that modifications and variations may be made by those skilled in the art in light of the above teachings, and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims (10)

1. The utility model provides a two sliding door structures that open which characterized in that: including the shell, set up sliding door subassembly on the shell and be used for the drive sliding door subassembly motion's drive division, the shell includes the front panel and sets up the wind channel export of front panel front end, sliding door subassembly includes that two symmetries set up the sliding door in wind channel exit, drive division is including being used for the drive sliding door stretches out or the drive assembly that opens and shuts of withdrawing and is used for the drive the rotatory rotation drive subassembly of sliding door.

2. A double door sliding structure according to claim 1 wherein: the shell also comprises an air duct upper side plate and an air duct lower side plate which are arranged on the inner side of the front panel, and the air duct upper side plate and the air duct lower side plate are respectively arranged at two ends of the air duct outlet; the driving part is arranged on the air duct upper side plate, the sliding door is connected with the driving part through an upper rotating supporting rod, and the sliding door is connected with the air duct lower side plate through a rotating connecting structure.

3. A double-opening sliding door structure according to claim 2, wherein: the opening and closing driving assembly comprises a driving motor and a connecting seat, the connecting seat comprises a driving base and a driving top cover detachably connected to the driving base, and the driving motor is connected to the driving base through a motor shaft sleeve; the air duct upper side plate is provided with a through hole matched with the motor shaft sleeve, the edge of the through hole is provided with a shoulder, and the shoulder faces towards the direction of the driving motor and is used for axially fixing the motor shaft sleeve.

4. A double door sliding structure according to claim 3 wherein: be provided with on the wind channel curb plate and be used for fixing driving motor's motor screw post and motor support column, the motor support column is used for supporting driving motor, driving motor passes through the fix with screw motor screw post.

5. A double door sliding structure according to claim 3 wherein: the drive base moves towards driving motor's one end is provided with connecting sleeve, the one end of motor shaft sleeve pass through flat position structure connect in driving motor's pivot, the other end of motor shaft sleeve connect in connecting sleeve.

6. The double-opening sliding door structure according to claim 5, wherein: the motor shaft sleeve is inserted into the connecting sleeve, and the motor shaft sleeve is fixedly connected with the connecting sleeve through a locking pin; the motor shaft sleeve is provided with a shaft sleeve hole, the connecting sleeve is provided with a connecting hole, and the locking pin penetrates through the shaft sleeve hole and the connecting hole and is used for enabling the motor shaft sleeve and the connecting sleeve to synchronously rotate.

7. A double door sliding structure according to claim 3 wherein: the upper rotating support rod is arranged on the sliding door, and the rotating drive assembly comprises a rotating motor arranged in the drive base and a rotating connecting piece connected between the rotating motor and the upper rotating support rod; and a circumferential positioning structure is arranged between the rotary connecting piece and the upper rotary supporting rod.

8. The double-opening sliding door structure according to claim 7, wherein: the circumference location structure is in including setting up expansion connector and setting on the swivel connected coupler are in on the runing rest and with the locating hole that expansion connector block is connected, the cross-section of expansion connector is the polygon setting, the locating hole with the cross-sectional shape of expansion connector is the same.

9. A double-opening sliding door structure according to claim 2, wherein: the rotary connecting structure comprises a lower rotary supporting rod and a rotary connecting rod, the lower rotary supporting rod is arranged on the sliding door, and the rotary connecting rod is arranged between the lower rotary supporting rod and the lower side plate of the air duct; one end of the rotary connecting rod is rotatably connected with the lower side plate of the air duct through a rotary shaft sleeve, and the other end of the rotary connecting rod is rotatably connected with the lower rotary supporting rod.

10. An air conditioner, characterized in that: comprising a double-opening sliding door structure according to any one of claims 1 to 9.

Images