CN215982857U - Air-out controlling means and air conditioner of air conditioner - Google Patents

Abstract

The utility model discloses an air-out control device of an air conditioner and the air conditioner, the device comprises: the wind shielding unit is configured to enable a first air outlet of the air conditioner to be opened and a second air outlet of the air conditioner to be closed when the wind shielding unit is located at a first position, so that the air conditioner can exhaust wind in a first wind outlet mode; when the wind shielding unit is located at the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air output mode. According to the scheme, the air supply mode of the air pipe type air conditioning unit is switched according to the air supply mode of the air pipe type air conditioning unit, so that the refrigerating and heating effects are considered at the same time.

Description

Air-out controlling means and air conditioner of air conditioner

Technical Field

The utility model belongs to the technical field of air conditioners, relates to an air outlet control device of an air conditioner and the air conditioner, in particular to an air outlet device of an air duct type air conditioning unit and the air duct type air conditioning unit, and particularly relates to the air outlet device of an indoor air duct type air conditioner and the indoor air duct type air conditioner capable of changing the direction of an air port.

Background

In the related scheme, the air supply modes of the air pipe type air conditioning unit comprise a flat air supply mode and a lower air supply mode. In the use process, the air conditioner can only select a single air supply mode, if a lower air supply mode is adopted during hot air supply, and a flat air supply mode is adopted during cold air supply, but the air pipe type air conditioning unit with the single air supply mode cannot give consideration to the refrigerating and heating effects at the same time.

The above is only for the purpose of assisting understanding of the technical aspects of the present invention, and does not represent an admission that the above is prior art.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an air outlet control device of an air conditioner and the air conditioner, which aim to solve the problems that an air supply mode of an air duct type air conditioning unit is single and refrigeration and heating effects cannot be simultaneously considered, and achieve the effects of switching the air supply mode of the air duct type air conditioning unit according to the air supply mode of the air duct type air conditioning unit and simultaneously considering the refrigeration and heating effects.

The utility model provides an air outlet control device of an air conditioner, wherein the air conditioner is provided with a first air outlet and a second air outlet; the first air outlet can be used for discharging air according to a first air discharging mode; the second air outlet can be used for discharging air according to a second air discharging mode; the air-out controlling means of air conditioner includes: a wind shielding unit; the wind shielding unit is configured to enable a first air outlet of the air conditioner to be opened and a second air outlet of the air conditioner to be closed when the wind shielding unit is located at a first position, so that the air conditioner blows air in a first air outlet mode; when the wind shielding unit is located at the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air outlet mode.

In some embodiments, the first outlet is disposed at a first region of a housing of the air conditioner; the second air outlet is arranged at a second area of the shell of the air conditioner; the number of the first air outlets is N, and the N first air outlets are arranged at a first area of a shell of the air conditioner at intervals; the number of the second air outlets is M, and the M second air outlets are arranged at a second area of the shell of the air conditioner at intervals; n, M, are all positive integers; the wind shielding unit includes: a wind deflector; at least one first vent is arranged on the wind shield at intervals along the arrangement direction of the N first air outlets; at least one second air vent is arranged on the wind shield at intervals along the direction of the M second air vents; in at least one first ventilation opening, if the first ventilation opening is communicated with the first air outlets with the same number in the N first air outlets, at least one first air outlet in the N first air outlets can exhaust air; in at least one second air outlet, if the second air outlet is communicated with the second air outlets with the same number in the M second air outlets, at least one second air outlet in the M second air outlets can exhaust air; wherein at least one of the first and second vents is configured to: under the condition that the first air vents are communicated with the first air outlets with the same number in the N first air outlets, the second air vents are not communicated with the second air outlets with the same number in the M second air outlets; and under the condition that the second air vents are communicated with the second air outlets with the same number in the M second air outlets, the first air vents are not communicated with the first air outlets with the same number in the N first air outlets.

In some embodiments, the wind deflector is disposed inside the first and second regions of the housing of the air conditioner.

In some embodiments, in the wind deflector, the number of the first vents is less than or equal to the number of the first air outlets; and the number of the second air outlets is less than or equal to that of the second air outlets.

In some embodiments, the number of first vents is N-1; the number of the second ventilation openings is M-1, and N is M; and/or the distance between at least one of the first ventilation opening and the second ventilation opening and the shell of the air conditioner is within a set distance range.

In some embodiments, at least one of the first ventilation openings is arranged on the wind shield at equal intervals, and the air opening parameters of the first ventilation openings are the same as those of the first air outlet in the first area; on the wind shield, at least one second ventilation opening is arranged at equal intervals, and the parameters of the second ventilation opening are the same as those of the second ventilation opening in the second area; the tuyere parameters include: tuyere shape, and/or tuyere size; the wind gap size includes: at least one of a tuyere length and a tuyere width; the at least one first ventilation opening and the at least one second ventilation opening are arranged in a staggered mode.

In some embodiments, the wind deflector is any one of an L-type wind deflector, a ﹂ -type wind deflector and a L-type wind deflector; the any wind deflector is provided with a first baffle and a second baffle; at least one first ventilation opening arranged on the first baffle plate; and the at least one second ventilation opening is arranged on the second baffle plate.

In some embodiments, between the wind deflector and the housing of the air conditioner, a connection mechanism is provided; the connecting mechanism is configured to enable the wind deflector to move along a set moving direction and limit the wind deflector to move towards a direction except the set moving direction; in the set moving direction, the length of the wind shield is smaller than that of the shell of the air conditioner; the setting of the moving direction includes: the air conditioner comprises N first air outlets, M second air outlets and a control device, wherein the control device is used for controlling the air conditioner to be in a state of being in a closed state.

In some embodiments, the connection mechanism comprises: a slot and/or a slide rail.

In some embodiments, a seal is provided between an edge of the wind deflector and the housing of the air conditioner to prevent wind leakage.

In some embodiments, further comprising: a control unit; wherein the control unit is configured to control the wind shielding unit to move; the wind shielding unit is configured to enable a first air outlet of the air conditioner to be opened and a second air outlet of the air conditioner to be closed when the wind shielding unit moves to a first position under the control of the control unit, so that the air conditioner blows air in a first air outlet mode; when the air conditioner moves to the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air output mode.

In some embodiments, the control unit comprises: a drive device and a controller; the driving device includes: a first gear and a second gear; the first gear is arranged on the wind shielding unit and is matched with the second gear in the motor, and the driving device drives the wind shielding unit to move under the driving of the motor; the motor is controlled by the controller.

In some embodiments, the control unit, which controls the movement of the wind shielding unit, includes: identifying an operation mode of the air conditioner under the condition that the air conditioner is started and operated; the operation mode includes: a first mode or a second mode; if the air conditioner operates in a first mode, controlling the wind shielding unit to move so as to control the air conditioner to wind in the first wind outlet mode; if the air conditioner operates in a second mode, controlling the wind shielding unit to move so as to control the air conditioner to wind in the second wind outlet mode; the wind shielding unit can open a first air outlet of the air conditioner and close a second air outlet of the air conditioner when moving to a first position under the control of the control unit, so that the air conditioner can exhaust air according to the first air outlet mode; when moving to the second position, can make the first air outlet of air conditioner closes, and makes the second air outlet of air conditioner opens, so that the air conditioner is according to the air-out of second air-out mode includes: moving to the first position under the control of the control unit in a case where the air conditioner is operated in the first mode; and moving to the second position under the control of the control unit when the air conditioner is operated in the second mode.

In accordance with another aspect of the present invention, there is provided an air conditioner including: the air outlet control device of the air conditioner is described above.

Therefore, according to the scheme of the utility model, the wind shields are arranged inside the panel where the lower air supply outlet and the side air supply outlet of the air pipe type air conditioning unit are positioned, the wind outlets corresponding to the lower air supply outlet and the side air supply outlet are arranged on the wind shields, and only one air supply outlet in the lower air supply outlet and the side air supply outlet can supply air by moving the wind shields, so that the switching between a flat air supply mode and a lower air supply mode is realized; the air supply mode of the air pipe type air conditioning unit is switched according to the air supply mode of the air pipe type air conditioning unit, so that the refrigerating and heating effects are considered at the same time.

Additional features and advantages of the utility model will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

Fig. 1 is a schematic structural diagram of an air outlet control device of an air conditioner according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of an embodiment of an arrangement position of an air inlet of an indoor unit;

FIG. 3 is a schematic structural view of an embodiment of an L-shaped wind deflector and a driving device;

fig. 4 is a schematic structural view of an embodiment of the position of the wind deflector in the indoor unit;

FIG. 5 is a schematic flow chart of an embodiment of a control method for changing the tuyere direction;

fig. 6 is a schematic flow chart illustrating an embodiment of controlling the movement of the wind shielding unit in the air outlet control method of the air conditioner according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be clearly and completely described below with reference to the specific embodiments of the present invention and the accompanying drawings. It is to be understood that the described embodiments are merely exemplary of the utility model, and not restrictive of the full scope of the utility model. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the air supply mode of the air pipe type air conditioning unit, an air outlet of the air conditioner is arranged on the side surface of the air conditioning unit in the flat air supply mode, and air flows out of the air outlet and flows along the direction parallel to a ceiling during air supply. Under the lower air supply mode, the air outlet of the air conditioner is arranged below the air conditioning unit, and air flow supplies air downwards along the direction vertical to the ceiling when air is supplied.

In the use process, the air conditioner only has a single air supply mode, such as: when hot air is supplied, a blanket type heating effect can be achieved by adopting a downward air supply mode, and the heating effect is good; when cold air is fed, the flat air feeding mode is adopted, so that the cold air can be prevented from directly blowing to a human body. Therefore, the single air supply mode of the air conditioner can not lead the effect of cold and hot air supply to reach the ideal state.

According to an embodiment of the utility model, an air outlet control device of an air conditioner is provided. Referring to fig. 1, a schematic diagram of an embodiment of the apparatus of the present invention is shown. The air conditioner is provided with a first air outlet and a second air outlet. The first air outlet can be used for discharging air according to a first air-out mode. And the second air outlet can be used for discharging air according to a second air-out mode. The air conditioner is an air duct type air conditioning unit. The first air outlet, such as a side air outlet or a side air inlet. And the second air outlet is an air outlet or a lower air supply outlet. The first air outlet mode is a flat air supply method. The second air outlet mode is an air supply mode as follows. The air-out controlling means of air conditioner includes: a wind shielding unit. The wind shielding unit is matched with the first air outlet and the second air outlet.

The wind shielding unit is configured to enable a first air outlet of the air conditioner to be opened and a second air outlet of the air conditioner to be closed when the wind shielding unit is located at a first position, so that the air conditioner blows air in a first air outlet mode. When the wind shielding unit is located at the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air outlet mode.

Therefore, the scheme of the utility model provides an air outlet control device of an air conditioner, and particularly relates to an indoor air duct machine capable of changing the direction of an air port, namely an indoor air duct machine capable of switching the direction of the air port according to the air supply temperature. By switching the air ports, the defects that the air pipe type air conditioning unit with a single air supply mode cannot simultaneously give consideration to the refrigerating and heating effects are overcome, and the refrigerating and heating effects are simultaneously given consideration to the air pipe type air conditioning unit with the single air supply mode.

In some embodiments, the first outlet is disposed at a first region of a housing of the air conditioner. The second air outlet is arranged at a second area of the shell of the air conditioner. The number of the first air outlets is N, and the N first air outlets are arranged at a first area of the shell of the air conditioner at intervals. The number of the second air outlets is M, and the M second air outlets are arranged at a second area of the shell of the air conditioner at intervals. N, M, are all positive integers.

The wind shielding unit includes: a wind deflector. And at least one first vent is arranged on the wind shield at intervals along the arrangement direction of the N first air outlets. And at least one second air vent is arranged on the wind shield at intervals along the direction of the M second air vents.

In at least one first vent, if the first vent is communicated with the first air outlets with the same number in the N first air outlets, at least one of the N first air outlets can discharge air.

In at least one of the second air outlets, if there is a second air outlet which is communicated with the second air outlets with the same number in the M second air outlets, at least one of the M second air outlets can exhaust air.

Wherein at least one of the first and second vents is configured to:

and under the condition that the first air vents are communicated with the first air outlets with the same quantity in the N first air outlets, the second air vents are not communicated with the second air outlets with the same quantity in the M second air outlets. And under the condition that the second air vents are communicated with the second air outlets with the same number in the M second air outlets, the first air vents are not communicated with the first air outlets with the same number in the N first air outlets.

In some embodiments, the wind shields are disposed inside the first region and the second region of the casing of the air conditioner, so that the overall occupied space of the indoor unit can be saved.

In some embodiments, in the wind deflector, the number of the first vents is less than or equal to the number of the first air outlets. And the number of the second air outlets is less than or equal to that of the second air outlets. Specifically, on the wind deflector, N-1 first vents are arranged at intervals along the arrangement direction of the N first air outlets. And M-1 second air outlets are arranged on the wind shield at intervals along the direction of the M second air outlets.

In some embodiments, the number of first vents is N-1; the number of the second ventilation openings is M-1, and N is M; and/or the distance between at least one of the first ventilation opening and the second ventilation opening and the shell of the air conditioner is within a set distance range.

Fig. 2 is a schematic structural view of an embodiment of an arrangement position of an air inlet of an indoor unit. As shown in fig. 2, in the indoor duct machine capable of changing the direction of the air inlet provided by the solution of the present invention, the indoor unit has a lower air supply outlet and a side air supply outlet, and the air inlets with the same size are alternately arranged in the direction from left to right at a set distance.

In some embodiments, at least one of the first ventilation openings is arranged on the wind deflector at equal intervals, and the air opening parameters of the first ventilation openings are the same as those of the first air outlet in the first area.

And at least one second ventilation opening is arranged on the wind shield at equal intervals, and the parameters of the second ventilation opening are the same as those of the second ventilation opening in the second area.

The tuyere parameters include: tuyere shape, and/or tuyere size. The wind gap size includes: at least one of a tuyere length and a tuyere width.

Specifically, the lengths of the air openings on the two sides of the wind shield are preferably consistent (for example, the lengths of the first air opening and the second air opening are consistent), the number of the air openings is also preferably consistent (namely, N-1 is equal to M-1), and the maximum number is reached (one air opening is tightly attached to one side), so that the air volume is large, the number of the air openings of the baffle plates is reduced by one by the maximum number, and if no air opening is tightly attached to one side of the casing (namely, the number of the air openings is not the maximum), the number of the baffle plates is tested to be consistent with the number of the casing. In addition, if the number of the air ports is reduced, the air ports are distributed in a staggered mode and cannot be overlapped.

The number of the air ports is the same as that of the side faces below the air ports, generally, about 2-5 air ports are arranged on each side, too small air ports can cause too large obstruction in the air flow outlet process, too much air ports can cause complex processing, and noise cannot be guaranteed. The interval between the air ports is the same as the length of the air ports. The air openings at the two sides of the wind shield can be rectangular or square. The length of the air ports on the two sides of the wind shield is determined by the number of the air ports and the length of the unit; the width of the air openings at the two sides of the wind shield is determined by the height of the unit. The sizes (i.e. the lengths and the widths) of the air openings at the two sides of the air deflector can be consistent or inconsistent, and are preferably consistent.

The at least one first ventilation opening and the at least one second ventilation opening are arranged in a staggered mode.

The length of the wind shield is shorter than the length of the unit by the distance of one air port, the hollow part on the wind shield is the same as the air port in size, when the position of the wind shield meets the requirement that the air port on one side is overlapped with the hollow part, the air port on the other side is staggered with the hollow part, and only one side of the air ports on the two sides can be opened simultaneously.

In some embodiments, the wind deflector is any one of an L-type wind deflector, a ﹂ -type wind deflector and a L-type wind deflector. The any wind deflector has a first flap and a second flap.

At least one said first vent is disposed on said first baffle. And the at least one second ventilation opening is arranged on the second baffle plate.

Fig. 3 is a schematic structural diagram of an embodiment of an L-shaped wind deflector and a driving device. As shown in fig. 3, the wind deflector may be an L-shaped wind deflector. The length of deep bead is shorter than the casing of tuber pipe air conditioning unit, and it has the fretwork position with the wind gap size of tuber pipe air conditioning unit to distribute on two faces of deep bead, and when being in a certain air supply state, the wind gap on the tuber pipe air conditioning unit corresponding surface coincides with the fretwork position of deep bead, and this face wind gap air-out, another side wind gap is blocked by the deep bead simultaneously.

In some embodiments, a connection mechanism is provided between the wind deflector and the housing of the air conditioner. The connecting mechanism is configured to enable the wind deflector to move along a set moving direction and limit the wind deflector to move towards a direction except the set moving direction; in the set moving direction, the length of the wind shield is smaller than that of the shell of the air conditioner. For example: the length of the wind deflector is smaller than that of the shell of the air conditioner along the direction from the end A to the end B.

The setting of the moving direction includes: the air conditioner comprises N first air outlets, M second air outlets and a control device, wherein the control device is used for controlling the air conditioner to be in a state of being in a closed state. N first air outlet, if N the direction of arranging of first air outlet. M first air outlet, if M the direction of arranging of second air outlet. N and M may be the same or different.

In some embodiments, the connection mechanism comprises: a slot and/or a slide rail.

Referring to the example shown in fig. 3, the panels of the indoor unit, on which the wind inlets are distributed, are respectively provided with one-side slots, which play the role of the restraint of the wind deflector and the role of the guide rail. For example: one side clamping groove is arranged on a lower panel of the indoor unit, wherein the lower panel is provided with a lower air supply outlet, the lower panel can move in the direction of the guide rail, and the wind shield can be restrained from moving on the lower panel in the directions except the direction of the guide rail. The side panel of the indoor unit with side air outlets is provided with a side clamping groove which can move in the direction of the guide rail and can restrain the wind shield from moving on the side panel in the direction except the direction of the guide rail.

In some embodiments, a seal is provided between an edge of the wind deflector and the housing of the air conditioner to prevent wind leakage. Fig. 4 is a schematic structural view of an embodiment of the position of the wind deflector in the indoor unit. As shown in fig. 4, an L-shaped wind deflector is used: the wind shield is shorter than the unit shell, hollow positions of the air openings are distributed on two surfaces of the wind shield, when the wind shield is in a certain air supply state, the air openings on the corresponding surface of the air pipe type air conditioning unit coincide with the hollow positions of the wind shields, the air outlets of the surface are exhausted, and meanwhile the air openings of the other surface are blocked by the wind shield. The edge of the wind shield is provided with sealing materials for preventing air leakage.

In some embodiments, further comprising: a control unit.

Wherein the control unit is configured to control the wind shielding unit to move.

The wind shielding unit is configured to enable a first air outlet of the air conditioner to be opened and a second air outlet of the air conditioner to be closed when the wind shielding unit moves to a first position under the control of the control unit, so that the air conditioner blows air in the first air outlet mode. When the air conditioner moves to the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air output mode.

Specifically, when in the hot air mode, the mode is switched to the lower air blowing mode. When the air conditioner is in a cold air mode, the air conditioner is switched to a flat air supply mode, and the refrigerating and heating effects are best by adopting a corresponding air supply mode after different air supply temperatures are detected.

In some embodiments, the control unit comprises: a drive device and a controller. The driving device includes: a first gear and a second gear. The first gear, such as a straight gear, arranged on the wind shielding unit is matched with the second gear in the motor, and the driving device drives the wind shielding unit to move under the driving of the motor. The motor is controlled by the controller.

One end of the wind shield is connected with a section of straight gear for linkage with the driving device. In the scheme of the utility model, the wind shield driving device is provided with a driving device, the driving device consists of a motor and a circular gear, the motor drives the gear to rotate and is linked with a straight gear of the wind shield, so that the wind shield moves along the clamping groove from left to right or from right to left, and the motor is controlled by a program. Like this, realize switching the wind gap through translation L type baffle, the mode is comparatively stable when realizing that the wind gap switches, and the motion trail is short and simple, and the structure is also more firm. The motor can use a stepping motor, and the angle and the distance can be adjusted by using the stepping motor like an air deflector of an air conditioner.

Wherein, the motor can just reverse, and the position is being close to one side curb plate, reduces the influence to the wind field. The spur gear is slightly longer than the length of a single tuyere. For example: on the premise of not affecting the function of switching the air outlet mode, the influence on the wind field is reduced as much as possible, and the end close to the casing A, B is preferred.

In some embodiments, the control unit, which controls the movement of the wind shielding unit, includes: the control unit is specifically further configured to identify an operation mode of the air conditioner, that is, identify an air supply mode of the air conditioner, such as directly identifying the air supply mode in a control logic of the air conditioner, when the air conditioner is turned on and operated. The operation mode includes: a first mode or a second mode. And if the air conditioner operates in a first mode, controlling the wind shielding unit to move so as to control the air conditioner to wind in the first wind outlet mode. And if the air conditioner operates in a second mode, controlling the wind shielding unit to move so as to control the air conditioner to wind in the second wind outlet mode. A first mode, such as a cooling mode. A second mode, such as a heating mode.

And the wind shielding unit can enable the first air outlet of the air conditioner to be opened and enable the second air outlet of the air conditioner to be closed when the wind shielding unit moves to the first position under the control of the control unit, so that the air conditioner can output wind in the first wind outlet mode. When moving to the second position, can make the first air outlet of air conditioner closes, and makes the second air outlet of air conditioner opens, so that the air conditioner is according to the air-out of second air-out mode includes: the wind shielding unit is particularly configured to move to the first position under the control of the control unit when the air conditioner operates in the first mode; and moving to the second position under the control of the control unit when the air conditioner is operated in the second mode.

FIG. 5 is a flowchart illustrating an embodiment of a control method for changing the tuyere direction. As shown in fig. 5, the control method for changing the tuyere direction includes:

step 1, after the air conditioner is started, the air conditioner starts to supply air, and different air supply modes are started.

And 2, obtaining a self air supply mode, if the self air supply mode is adopted, using a lower air supply mode to perform carpet type heating, sending a corresponding signal, operating a driving device to enable a motor to rotate to drive a circular gear to rotate, enabling a wind shield to move to a first position such as an X1 position according to the matched rotation between the gears, and at the moment, enabling a hollowed part of the wind shield to coincide with a lower air supply opening of the unit, and blocking a side air supply opening. If the cold wind mode, then use the mode of flat air supply, prevent that cold wind from directly blowing to the people, cause the sense of blowing, send signal operation drive structure, make the deep bead move to the second position like X2 position, at this moment, the deep bead fretwork department and the side air feed mouth coincidence of unit, and the lower air feed mouth is blocked.

For example: the air conditioner mainboard logic can know own parameters and commands, can identify own operating modes, and can write related programs if the motor needs to be rotated in the corresponding mode.

And 3, keeping the position of the wind shield unchanged, moving until the air supply mode is detected to be changed, or shutting down the unit, and operating in the way until the unit is shut down.

The X1 position and the X2 position are both positions when the wind deflector moves left and right on the guide rail.

In the above-mentioned embodiment, the quantity in wind gap is also not fixed, can adjust according to the actual demand, and position through the adjustment deep bead can let the unit realize flat air supply or air supply down, and flat air supply is better when sending cold wind, and the side air supply is better when sending hot-blast, and different air supply modes adopt different air supply modes, can let user experience better.

Through a large number of tests, the technical scheme of the utility model is adopted, and the wind shields are arranged inside the panel where the lower air supply outlet and the side air supply outlet of the air pipe type air conditioning unit are arranged, the wind shields are provided with the air outlets corresponding to the lower air supply outlet and the side air supply outlet, and only one air supply outlet in the lower air supply outlet and the side air supply outlet can supply air by moving the wind shields, so that the switching between the flat air supply mode and the lower air supply mode is realized. The air supply mode of the air pipe type air conditioning unit is switched according to the air supply mode of the air pipe type air conditioning unit, so that the refrigerating and heating effects are considered at the same time.

According to the embodiment of the utility model, the air conditioner corresponding to the air outlet control device of the air conditioner is also provided. The air conditioner may include: the air outlet control device of the air conditioner is described above.

Since the processing and functions of the air conditioner of this embodiment are basically corresponding to the embodiments, principles and examples, reference may be made to the related descriptions in the embodiments without being detailed in the description of this embodiment, which is not described herein again.

Through a large number of tests, the technical scheme of the utility model is adopted, and the wind shield is arranged in the panel where the lower air supply outlet and the side air supply outlet of the air duct type air conditioning unit are arranged, the wind shield is provided with the air outlets corresponding to the lower air supply outlet and the side air supply outlet, and only one air supply outlet in the lower air supply outlet and the side air supply outlet can supply air by moving the wind shield, so that the switching between a flat air supply mode and a lower air supply mode is realized, the defect that the air duct type air conditioning unit with a single air supply mode cannot simultaneously give consideration to both the refrigeration and heating effects is solved, and the refrigeration and heating effects are simultaneously given consideration to.

According to the embodiment of the utility model, the air outlet control method of the air conditioner corresponding to the air conditioner is also provided. The air outlet control method of the air conditioner can comprise the following steps: and controlling the wind shielding unit to enable the first air outlet of the air conditioner to be opened and the second air outlet of the air conditioner to be closed when the wind shielding unit is located at the first position, so that the air conditioner can exhaust air according to the first air outlet mode. When the wind shielding unit is located at the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air output mode.

Therefore, the scheme of the utility model provides an air outlet control device of an air conditioner, and particularly relates to an indoor air duct machine capable of changing the direction of an air port, namely an indoor air duct machine capable of switching the direction of the air port according to the air supply temperature. By switching the air ports, the defects that the air pipe type air conditioning unit with a single air supply mode cannot simultaneously give consideration to the refrigerating and heating effects are overcome, and the refrigerating and heating effects are simultaneously given consideration to the air pipe type air conditioning unit with the single air supply mode.

In some embodiments, further comprising: and controlling the wind shielding unit to move so that when the wind shielding unit moves to a first position, the first air outlet of the air conditioner can be opened and the second air outlet of the air conditioner can be closed, so that the air conditioner can exhaust air according to the first air outlet mode. When the air conditioner moves to the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air output mode.

Specifically, when in the hot air mode, the mode is switched to the lower air blowing mode. When the air conditioner is in a cold air mode, the air conditioner is switched to a flat air supply mode, and the refrigerating and heating effects are best by adopting a corresponding air supply mode after different air supply temperatures are detected.

In some embodiments, the specific process of controlling the movement of the wind-shielding unit is described in the following exemplary description.

The following further describes a specific process for controlling the movement of the wind shielding unit with reference to a schematic flow chart of an embodiment of the present invention shown in fig. 6, which includes: step S110 to step S120.

In step S110, in case the air conditioner is turned on and operated, an operation mode of the air conditioner is recognized. The operation mode includes: a first mode or a second mode. And if the air conditioner operates in a first mode, controlling the wind shielding unit to move so as to control the air conditioner to wind in the first wind outlet mode. And if the air conditioner operates in a second mode, controlling the wind shielding unit to move so as to control the air conditioner to wind in the second wind outlet mode. A first mode, such as a cooling mode. A second mode, such as a heating mode.

Controlling the wind shielding unit to move to the first position in case that the air conditioner operates in the first mode at step S120; and moving to the second position when the air conditioner is operated in the second mode.

FIG. 5 is a flowchart illustrating an embodiment of a control method for changing the tuyere direction. As shown in fig. 5, the control method for changing the tuyere direction includes:

step 1, after the air conditioner is started, the air conditioner starts to supply air, and different air supply modes are started.

And 2, acquiring a self air supply mode (namely an operation mode), if the hot air mode is adopted, using a lower air supply mode to perform carpet heating, sending a corresponding signal, operating a driving device to enable a motor to rotate to drive a circular gear to rotate, and enabling a wind shield to move to a first position such as an X1 position according to the matched rotation between gears, wherein at the moment, the hollow part of the wind shield is superposed with a lower air supply opening of the unit, and a side air supply opening is blocked. If the cold wind mode, then use the mode of flat air supply, prevent that cold wind from directly blowing to the people, cause the sense of blowing, send signal operation drive structure, make the deep bead move to the second position like X2 position, at this moment, the deep bead fretwork department and the side air feed mouth coincidence of unit, and the lower air feed mouth is blocked.

And 3, keeping the position of the wind shield unchanged, moving until the air supply mode is detected to be changed, or shutting down the unit, and operating in the way until the unit is shut down.

The X1 position and the X2 position are both positions when the wind deflector moves left and right on the guide rail.

In the above-mentioned embodiment, the quantity in wind gap is also not fixed, can adjust according to the actual demand, and position through the adjustment deep bead can let the unit realize flat air supply or air supply down, and flat air supply is better when sending cold wind, and the side air supply is better when sending hot-blast, and different air supply modes adopt different air supply modes, can let user experience better.

Since the processing and functions implemented by the method of this embodiment substantially correspond to the embodiments, principles and examples of the air conditioner, reference may be made to the related descriptions in the foregoing embodiments without being detailed in the description of this embodiment.

Through a large amount of experimental verifications, adopt the technical scheme of this embodiment, through the inside at the lower supply-air outlet of air duct type air conditioning unit and side air supply opening place panel, be provided with the deep bead, be provided with the air outlet that corresponds with supply-air outlet and side air supply opening down on this deep bead, through removing this deep bead, only one supply-air outlet can the air-out in messenger supply-air outlet and the side air supply opening down, after through detecting different supply air temperature, the realization is to flat air supply mode and lower air supply mode's switching, take corresponding air supply mode, make the refrigeration heat effect reach best.

In summary, it is readily understood by those skilled in the art that the advantageous modes described above can be freely combined and superimposed without conflict.

The above description is only an example of the present invention, and is not intended to limit the present invention, and it is obvious to those skilled in the art that various modifications and variations can be made in the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (14)

1. The air outlet control device of the air conditioner is characterized in that the air conditioner is provided with a first air outlet and a second air outlet; the first air outlet can be used for discharging air according to a first air discharging mode; the second air outlet can be used for discharging air according to a second air discharging mode; the air-out controlling means of air conditioner includes: a wind shielding unit;

the wind shielding unit is configured to enable a first air outlet of the air conditioner to be opened and a second air outlet of the air conditioner to be closed when the wind shielding unit is located at a first position, so that the air conditioner blows air in a first air outlet mode; when the wind shielding unit is located at the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air outlet mode.

2. The air outlet control device of the air conditioner according to claim 1, wherein the first air outlet is provided at a first region of a casing of the air conditioner; the second air outlet is arranged at a second area of the shell of the air conditioner; the number of the first air outlets is N, and the N first air outlets are arranged at a first area of a shell of the air conditioner at intervals; the number of the second air outlets is M, and the M second air outlets are arranged at a second area of the shell of the air conditioner at intervals; n, M, are all positive integers;

the wind shielding unit includes: a wind deflector; at least one first vent is arranged on the wind shield at intervals along the arrangement direction of the N first air outlets; at least one second air vent is arranged on the wind shield at intervals along the direction of the M second air vents;

in at least one first ventilation opening, if the first ventilation opening is communicated with the first air outlets with the same number in the N first air outlets, at least one first air outlet in the N first air outlets can exhaust air;

in at least one second air outlet, if the second air outlet is communicated with the second air outlets with the same number in the M second air outlets, at least one second air outlet in the M second air outlets can exhaust air;

wherein at least one of the first and second vents is configured to:

under the condition that the first air vents are communicated with the first air outlets with the same number in the N first air outlets, the second air vents are not communicated with the second air outlets with the same number in the M second air outlets; and under the condition that the second air vents are communicated with the second air outlets with the same number in the M second air outlets, the first air vents are not communicated with the first air outlets with the same number in the N first air outlets.

3. The air outlet control device of the air conditioner according to claim 2, wherein the wind deflector is provided inside a first region and a second region of a casing of the air conditioner.

4. The air outlet control device of the air conditioner according to claim 2, wherein in the air baffle, the number of the first vents is less than or equal to the number of the first air outlets; and the number of the second air outlets is less than or equal to that of the second air outlets.

5. The air outlet control device of the air conditioner according to claim 4, wherein the number of the first air vents is N-1; the number of the second ventilation openings is M-1, and N is M; and/or the presence of a gas in the gas,

at least one of the first ventilation opening and the second ventilation opening is within a set distance range from the shell of the air conditioner.

6. The air outlet control device of the air conditioner according to claim 2, wherein at least one first vent is arranged on the wind shield at equal intervals, and the air outlet parameters of the first vent are the same as those of the first air outlet in the first area;

on the wind shield, at least one second ventilation opening is arranged at equal intervals, and the parameters of the second ventilation opening are the same as those of the second ventilation opening in the second area;

the tuyere parameters include: tuyere shape, and/or tuyere size; the wind gap size includes: at least one of a tuyere length and a tuyere width;

the at least one first ventilation opening and the at least one second ventilation opening are arranged in a staggered mode.

7. The air-out control device of the air conditioner according to any one of claims 2 to 6, wherein the air deflector is any one of L-type air deflector, ﹂ -type air deflector and L-type air deflector; the any wind deflector is provided with a first baffle and a second baffle;

at least one first ventilation opening arranged on the first baffle plate; and the at least one second ventilation opening is arranged on the second baffle plate.

8. The air outlet control device of the air conditioner according to any one of claims 2 to 6, wherein a connection mechanism is provided between the wind deflector and a housing of the air conditioner; the connecting mechanism is configured to enable the wind deflector to move along a set moving direction and limit the wind deflector to move towards a direction except the set moving direction; in the set moving direction, the length of the wind shield is smaller than that of the shell of the air conditioner;

the setting of the moving direction includes: the air conditioner comprises N first air outlets, M second air outlets and a control device, wherein the control device is used for controlling the air conditioner to be in a state of being in a closed state.

9. The air outlet control device of the air conditioner according to claim 8, wherein the connection mechanism includes: a slot and/or a slide rail.

10. The outlet control device of the air conditioner according to any one of claims 2 to 6, wherein a sealing member is provided between an edge of the wind deflector and a casing of the air conditioner to prevent air leakage.

11. The air outlet control device of the air conditioner according to any one of claims 1 to 6, further comprising: a control unit; wherein the content of the first and second substances,

the control unit is configured to control the wind shielding unit to move;

the wind shielding unit is configured to enable a first air outlet of the air conditioner to be opened and a second air outlet of the air conditioner to be closed when the wind shielding unit moves to a first position under the control of the control unit, so that the air conditioner blows air in a first air outlet mode; when the air conditioner moves to the second position, the first air outlet of the air conditioner can be closed, and the second air outlet of the air conditioner can be opened, so that the air conditioner can output air according to the second air output mode.

12. The air outlet control device of the air conditioner according to claim 11, wherein the control unit includes: a drive device and a controller; the driving device includes: a first gear and a second gear; the first gear is arranged on the wind shielding unit and is matched with the second gear in the motor, and the driving device drives the wind shielding unit to move under the driving of the motor; the motor is controlled by the controller.

13. The air outlet control device of the air conditioner according to claim 11, wherein the control unit controls the movement of the wind shielding unit, and includes:

identifying an operation mode of the air conditioner under the condition that the air conditioner is started and operated; the operation mode includes: a first mode or a second mode; if the air conditioner operates in a first mode, controlling the wind shielding unit to move so as to control the air conditioner to wind in the first wind outlet mode; if the air conditioner operates in a second mode, controlling the wind shielding unit to move so as to control the air conditioner to wind in the second wind outlet mode;

the wind shielding unit can open a first air outlet of the air conditioner and close a second air outlet of the air conditioner when moving to a first position under the control of the control unit, so that the air conditioner can exhaust air according to the first air outlet mode; when moving to the second position, can make the first air outlet of air conditioner closes, and makes the second air outlet of air conditioner opens, so that the air conditioner is according to the air-out of second air-out mode includes:

moving to the first position under the control of the control unit in a case where the air conditioner is operated in the first mode; and moving to the second position under the control of the control unit when the air conditioner is operated in the second mode.

14. An air conditioner, comprising: the air outlet control device of the air conditioner according to any one of claims 1 to 13.

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