KR102341500B1 - Air deflector assembly, air guide mechanism, blower and air conditioner - Google Patents

Abstract

The air guide assembly installed at the air outlet portion of the air conditioner includes a first air deflector 213 and a second air deflector 212; The first air deflector 213 is for guiding the outlet air stream of the air conditioner to be swept up and down; The second air deflector 212 is installed at the upper position of the air outlet of the air conditioner and is located above the first air deflector 213, and the second air deflector 212 guides the outlet air to blow only toward the ground. do. In addition, it relates to an air guide mechanism, a blower, and an air conditioner including the air deflector assembly, and the air deflector assembly can effectively solve the problem that the ground drop effect of the outlet air is lowered.

Description

Air deflector assembly, air guide mechanism, blower and air conditioner

This application has priority to the Chinese patent application entitled "Air Deflector Assembly and Air Conditioner" with the application number 2016 10264160.6, filed on April 25, 2016, and the application number 201610390786.1, filed on June 01, 2016 , claiming priority to a Chinese patent application entitled "Air conditioner, blower and air guide mechanism thereof", the entirety of which is incorporated herein by reference.

The present invention relates to the field of air conditioning technology, and more particularly, to an air deflector assembly, an air guide mechanism, a blower, and an air conditioner.

In the prior art, a blower is generally installed in the upper part of the air conditioner housing (at the position of the upper head part). Due to the limitation of the internal space, the conventional air deflector structure cannot implement an effective wind guiding effect, and the air conditioner cannot ensure that the outlet air is blown toward the ground, so that the ground dropping effect of the outlet air is deteriorated. In addition, in current air conditioners, when blowing, the airflow of the outlet air is attached to the inner wall of the air conditioner, and can be aggregated on the upper part of the air conditioner along the inner wall. Although it can be drawn out, the outlet air flow at the top of the air conditioner is still condensed and cannot be discharged, so that the airflow amount of the air conditioner is reduced and the blowing efficiency of the air conditioner is lowered, which affects the use of the user.

Chinese Patent Publication CN 104566899 A (published on April 29, 2015)

Accordingly, there is a need to provide an air deflector assembly, an air guide mechanism including the air deflector assembly, a blower including the air guide mechanism, and an air conditioner including the blower.

An air deflector assembly installed at a vent of an air conditioner, comprising: a first air deflector assembly rotatably installed to guide an outlet air stream of the air conditioner to be swept up and down; and a second air deflector installed at an upper position of the air outlet of the air conditioner and positioned above the first air deflector to guide the outlet air stream to be blown only toward the ground.

In one embodiment, the first air deflector and the first air deflector are installed in parallel, the second air deflector is rotatably installed, and the second air deflector is rotatable only in a direction toward the ground .

In one embodiment, an upper brace is installed on the side facing away from the ground of the second air deflector, and the upper brace is to prevent the second air deflector from rotating in a direction facing the ground. .

In one embodiment, the upper holding device is a torsion spring installed on a rotation shaft of the second air deflector, and the torsion spring is for restricting rotation of the second air deflector only in a direction toward the ground.

In one embodiment, a connection device is provided between the first air deflector and the second air deflector, so that when the first air deflector rotates in the ground direction, the second air deflector rotates in the ground direction at the same time drive

In one embodiment, the connecting device is connected to the first air deflector, the first connecting rod having a guide hole extending along the moving direction at one end facing the second air deflector is installed; And the first end is connected to the swinging end side of the second air deflector, the second end includes a second connecting rod slidably installed in the guide hole.

In one embodiment, the second connecting rod includes two cantilevers and is installed in parallel, a latch is fixedly connected between the two cantilevers, and the latch is installed through the guide hole.

In one embodiment, the number of the first air deflectors is plural, the plurality of the first air deflectors are installed in parallel, and the first connecting rod passes through the plurality of the first air deflectors to each of the first air deflectors. 1 It is fixedly connected to the air deflector.

In one embodiment, the air deflector assembly may include: a meshing rack connected to a plurality of first air deflectors and driven; It is connected to the drive output shaft of the motor, further comprising a motor gear meshing with the meshing rack;

Both the meshing rack and the motor gear are located on a side farther from the tuyere of the first air deflector.

An air guide mechanism, comprising: a housing having a hollow accommodation cavity, the air outlet opening of the air conditioner, and the air outlet communicating with the accommodation cavity; and an air deflector assembly installed in the housing, positioned at an upper edge of the air outlet, contactable with an upper portion of the housing, and configured to discharge outlet air condensed on the upper portion of the housing.

In one embodiment, the air deflector assembly is joined to the upper portion of the housing; Alternatively, an edge of the air deflector assembly may abut against an upper portion of the housing.

In one embodiment, the second air deflector is mounted on the housing and is located at an upper edge of the tuyere; the second air deflector may be in contact with an upper portion of the housing, and the second air deflector is for discharging outlet air condensed on the upper portion of the housing; The first air deflector is located in the air outlet.

In one embodiment, the inner surface of the housing and the surface of the second air deflector are smoothly transitioned or located on the same plane.

A blower comprising: an air outlet mask and the air guide mechanism; an air outlet grill is installed on the outlet air mask; The air outlet mask is installed to cover the air guide mechanism, and the air outlet grille corresponds to the tuyere of the air guide mechanism.

An air conditioner comprising: an air conditioner body and the blower; The blower is located above the air conditioner body.

In an air conditioner (round cabinet or square cabinet), a vent is installed at the upper part (head part), and the outlet air of the internal air duct is in close contact with the inner wall of the air duct and blows upward one after another, so that the outlet air of the air duct is located at the upper part of the tuyer (the tuyere). upper side), and accordingly, the air deflector assembly provided by the present invention is based on the conventional sweeping structure, and a second air deflector is added to the upper position of the tuyeres, and the second air deflector is the airflow of the outlet air. is guided to blow toward the ground (i.e., only guides the wind down) and does not move upward, so that the outlet air, which is concentrated at the top of the tuyeres, is guided to flow toward the ground through the second air deflector, and at the same time, the first The structure of the air deflector also guides the airflow upward, and the second air deflector creates a buffering action on the first air deflector, guiding some of the airflow flowing upward to flow downward, thereby optimizing the ground drop effect of the outlet air. This improves the comfort of the air conditioner.

The air conditioner, the blower, and the air guide mechanism provided by the present invention have a reasonable structural design, and the air deflector assembly is in contact with the inner surface of the upper part of the housing, so that the outlet air from the upper part of the housing can be discharged along the air deflector assembly, Therefore, the outlet air condensed on the upper part of the housing is discharged due to the Coanda effect, thereby preventing the outlet air from being condensed on the upper part of the housing due to the Coanda effect and affecting the blowing rate, and improving the blowing efficiency of the air guide structure, of the blowing effect is guaranteed, and it becomes possible for users to use it.

In order to make the content of the present invention more easily and clearly understood, the present invention will be described in more detail below in conjunction with the accompanying drawings according to specific embodiments of the present invention. among them,
1 is a structural diagram of an air deflector assembly provided by a first embodiment of the present invention.
Figure 2 is a partial structural diagram when the air deflector assembly provided by the first embodiment of the present invention is mounted on the air conditioner.
3 is an external structural diagram of the air conditioner provided by the first embodiment of the present invention.
4 is a structural diagram of a tuyere portion of the air conditioner of FIG. 3 .
5 is an exploded view of the blower provided by the second embodiment of the present invention.
6 is an explanatory view in which the blower shown in FIG. 5 is mounted on the air conditioner.

In order to make the object, technical solution and advantages of the present invention more clear, the embodiment of the present invention will be described in more detail below in conjunction with the accompanying drawings.

1 to 3 together, a first embodiment of the present invention provides an air deflector assembly installed at a tuyere of an air conditioner, and the air deflector assembly is mainly for guiding the airflow of the outlet air to be swept. The air deflector assembly in the embodiment includes a first air deflector 213 and a second air deflector 212 . The first air deflector 213 is rotatably installed, and the first air deflector 213 is for guiding the outlet air stream of the air conditioner to be swept up and down, and the rotation axis of the first air deflector 213 is in the horizontal direction. is extended The second air deflector 212 is installed at an upper position of the air outlet of the air conditioner, the second air deflector 212 is located above the first air deflector 213, and the second air deflector 212 is an outlet air flow. guide the airflow towards the ground only. All of the vertical directions between the first air deflector 213 and the second air deflector 212 are described according to the direction when the air conditioner is normally disposed.

In an air conditioner (round cabinet or square cabinet), a vent is installed at the upper part (head part), and the outlet air of the internal air duct is in close contact with the inner wall of the air duct and blows upward one after another, so that the outlet air of the air duct is located at the upper part of the tuyer (the tuyere). upper side), and accordingly, the air deflector assembly provided by the present invention is based on the conventional sweeping structure, and a second air deflector is added to the upper position of the tuyeres, and the second air deflector is the airflow of the outlet air. is guided to blow toward the ground (i.e., only guides the wind down) and does not move upward, so that the outlet air, which is concentrated at the top of the tuyeres, is guided to flow toward the ground through the second air deflector, and at the same time, the first The air deflector guides the airflow upward, and the second air deflector has a buffering action on the first air deflector, which can guide some of the upwardly flowing airflow to flow downwardly, thus reducing the effect of ground-dropping of the outlet air. By implementing optimization, the comfort of the air conditioner is improved.

1, the second air deflector 212 is installed in parallel with the first air deflector 213, the second air deflector 212 is rotatably installed, and the second air deflector 212 is It can only rotate in the direction of the ground. The second air deflector 212 may also be suitably rotatable to adjust the direction of the wind guided to the ground.

Preferably, the second air deflector 212 is provided with an upper brace on the side facing away from the ground, and the upper brace is to prevent the second air deflector 212 from rotating in the direction away from the ground. . The upper brace effectively ensures that the second air deflector 212 does not rotate upward, and thus, even when the second air deflector 212 is rotatable, it is possible to guide the wind only toward the ground.

In this embodiment, the upper holding device is a torsion spring 217 installed on the rotation shaft of the second air deflector 212, and the torsion spring 217 is limited to rotate the second air deflector 212 only in the ground direction. it is for

In order to implement the driving force of the second deflector 212 without increasing the structural complexity of the air conditioner, the second air deflector 212 is rotationally driven through the first air deflector 213 . In this embodiment, a connection device is provided between the first air deflector 213 and the second air deflector 212, and when the first air deflector 2143 rotates in the ground direction, the second air deflector 212 Simultaneously drive them to rotate in the direction of the ground. A torsion spring 217 is installed on the rotation shaft of the second air deflector 212 to apply one upward force to the second air deflector 212 , so that under the driving of the first air deflector 213 , the second air deflector The 212 only rotates downward by the action of the connecting device, and does not face upward even when rotating in the opposite direction, so as to ensure the operating state of the second air deflector 212, and to achieve a better ground-falling effect of the outlet air. can be implemented

Specifically, referring to FIG. 1 , the connecting device includes a first connecting rod 216 and a second connecting rod 215 , and the first connecting rod 216 is connected to the first air deflector 213 , A guide hole 2161 extending along the movement direction of the first connecting rod 216 is installed at one end of the first connecting rod 216 toward the second air deflector 212 . The first end of the second connecting rod 215 is connected to one side of the swinging end of the second air deflector 212 , and the second end of the second connecting rod 215 is slidably installed in the guide hole 2161 . .

When the first air deflector 213 rotates downward, the first connecting rod 216 also moves downward, and the inner wall of the guide hole 2161 is supported by the second end of the second connecting rod 215 , the second The connecting rod 215 also moves downward, and the second connecting rod 215 further pulls the second air deflector 212 to overcome the elastic force of the torsion spring, and the second air deflector 212 also rotates downward. , thereby realizing the simultaneous operation of the first and second air deflectors to guide the airflow to flow toward the ground. When the first air deflector 213 rotates upward under the driving of the motor, that is, it is necessary to blow upward to some extent, the first connecting rod 216 also moves upward, and the process of moving the first connecting rod 216 In, the second end of the second connecting rod 215 slides all the way in the guide hole (2171). The length of the guide hole 2161 is set to a length that does not touch the second air deflector 212 when the first connecting rod 216 moves upward to the limit. Therefore, the first connecting rod 216 and the second connecting rod 215 prevent the second air deflector from rotating only downward and not in the opposite direction through this configuration.

Specifically, the structure of the second connecting rod 215 is as follows: The second connecting rod 215 includes two cantilevers 2151 installed in parallel, and a latch 2152 between the two cantilevers 2151 . ) is fixedly connected, and the latch 2152 is installed through the guide hole 2141 . The latch 2152 forms the second end of the second connecting rod 215 , and this structure of the latch 2152 facilitates detachment.

In order to increase the wind guiding effect, in the air guide assembly of this embodiment, the first air deflectors 213 are installed in parallel, and the first connecting rod 216 passes through the plurality of first air deflectors 213 , respectively. It is fixedly connected to the first air deflector 213 of the , and only the shape structure of the two first air deflectors 213 is shown in FIG. 1 . The first connecting rod 216 installed through the front end of the first air deflector 213 ensures stability during the movement of the first air deflector 213 .

At the same time, the air deflector assembly further includes a meshing rack 2142 and a motor gear 2141, the meshing rack 2142 is driven and connected to the plurality of first air deflectors 213, and the motor gear 2141 is a motor It is connected to the output shaft of the drive, and between the motor gear 2141 and the meshing rack 2142 is meshed. Both the meshing rack 2142 and the motor gear 2141 are located on the far side from the air outlet of the first air deflector 213, and the meshing rack 2142 and the motor gear 2141 are disposed on the rear side of the air outlet. In the process of the meshing rack 2142 moving up and down, the teeth of the rack are engaged with the circular shaft on the rear side of the first air deflector 213 and move up and down, and the first air deflector 213 moves up and down along its rotation axis. drive to rotate

3 and 4, the first embodiment of the present invention further provides an embodiment of the air conditioner. The air conditioner includes a housing 211 , and the air outlet 2111 of the air conditioner is installed on the housing 211 . The air conditioner further includes the air deflector assembly of the above embodiment, the air deflector assembly is installed at the air outlet 2111 portion, and the second air deflector in the air deflector assembly is located above the air outlet 2111 . Among them, FIG. 2 shows the shape structure of the air conditioner tuyere 2111. In general, the tuyeres 2111 of the air conditioner all have a grill, and the air deflector assembly is installed in the grill.

In the air conditioner (round cabinet or rectangular cabinet) provided by the first embodiment of the present invention, a vent is installed on the upper part (head part), and the outlet air of the internal air duct is in close contact with the inner wall of the air duct and blows upward one after another. The outlet air of the duct is more concentrated at the upper position of the tuyere (upper side of the tuyeres), and the air deflector assembly provided by the present invention is based on the conventional sweeping structure, and as a result of adding a second air deflector at the upper position of the tuyeres, the second Since the air deflector guides the airflow of the outlet air to be blown towards the ground (i.e., only guides the wind down) and not to travel upward, the outlet air that is concentrated at the top of the tuyere flows towards the ground through the second air deflector. At the same time, the structure of the first air deflector also guides the airflow upward, and the second air deflector creates a buffering action on the first air deflector, and guides some of the airflow flowing upward to flow downward, so that the outlet air The comfort of the air conditioner is improved by realizing the optimization of the effect of falling on the ground.

5 and 6, the second embodiment of the present invention provides an air guide mechanism 110 installed in the blower 100 of the air conditioner. By allowing the outlet air concentrated in the upper part of the air conditioner to be discharged through the air guide mechanism 110 provided by the second embodiment of the present invention, the airflow amount of the air conditioner is guaranteed, and further, the blowing effect is ensured.

In one embodiment, the air guide mechanism 110 includes a housing 111 and a blower plate. The housing 111 has a hollow storage cavity, and the blower plate is located in the storage cavity. A tuyere is further opened in the housing 111 , and the tuyere communicates with the storage cavity, so that the outlet air of the air conditioner enters the housing cavity of the housing 111 of the air guide mechanism 110 and is discharged through the tuyere. At the same time, the blower plate is mounted on the air outlet, and by guiding the outlet air, blowing of the air conditioner becomes possible.

Specifically, the blower plate may be mounted on the housing 111 and positioned at the upper edge of the air outlet, and the blower plate may be in contact with the upper portion of the housing 111 . In other words, a gap does not exist between the blower plate and the upper portion of the housing 111 , or a gap does not exist between a portion of the blower plate and the upper portion of the housing 111 . The contact between the blower plate and the upper portion of the housing 111 includes two modes: a surface-to-surface contact method and a line-to-surface contact method. Between the blower plate and the housing 111 is a surface-to-surface contact, that is, the surface of the blower plate is joined to the inner surface of the upper portion of the housing 111, and the upper portion of the housing 111 due to the Coanda effect The condensed outlet air may be discharged along the blower plate.

The blower plate is for discharging the condensed outlet air on the upper part of the housing 111 . Due to the Coanda effect, the outlet air of the air conditioner is attached to the inner wall of the air duct, and the outlet air rises along the inner wall of the air duct to the air guide mechanism 110 of the blower 100, and the air guide mechanism 110 is located in the storage cavity of the housing 111 of the Also, due to the Coanda effect, the outlet air may adhere to the inner surface of the housing 111 and aggregate on the upper portion of the housing 111 . At this time, since the blower plate and the inner surface of the upper portion of the housing 111 are in contact with each other, the outlet air continues to move along the surface of the blower plate, so that the outlet air can be discharged. The air guide mechanism 110 of the present invention implements the discharge of the outlet air from the upper part of the air conditioner through contact between the blower plate and the upper part of the housing 111, and can prevent the outlet air from being agglomerated on the upper part of the air conditioner. The amount of air blowing is improved, and the blowing effect is ensured, making it possible for users to use it.

In addition, the blower plate includes an upper air deflector 112 and a lower air deflector 113 . The housing 111 has a hollow accommodation cavity, and the upper air deflector 112 , the lower air deflector 113 and the driving assembly are all mounted in the accommodation cavity. A tuyere is further opened in the housing 111 , and the tuyere communicates with the accommodation cavity, so that the outlet air of the air conditioner enters the accommodation cavity of the housing 111 of the air guide mechanism 110 , and then is discharged through the air outlet. At the same time, both the upper air deflector 112 and the lower air deflector 113 are mounted on the air outlet, and by guiding the outlet air through the upper air deflector 112 and the lower air deflector 113, the outlet air of the air conditioner is on the ground. It is possible to flow to Of course, the position of the lower air deflector 113 is changeable, for example, it may be installed to be located outside the tuyeres or above the upper air deflector 112 , and the upper air deflector 112 is the housing 111 . It is only necessary to guide the outlet air condensed on the upper part of the housing 111 to the outside. In addition, an air guide member may be further covered on the outside of the air guide mechanism 110 , and the tuyere discharges the outlet air discharged by the upper air deflector 112 through the air guide member.

The upper air deflector 112 may be mounted on the housing 111 and positioned at an upper edge of the air outlet, and the upper air deflector 112 may be bonded to the upper portion of the housing 111 . In other words, one surface of the upper air deflector 112 is in contact with the inner surface of the upper portion of the housing 111 . The upper air deflector 112 may be bonded to the housing 111 , and, of course, the upper air deflector 112 may also be in contact with the housing 111 . The surface where the upper air deflector 112 and the housing 111 are bonded to each other is the position limiting surface, and the other surface of the upper air deflector 112 is the air exhaust surface. The outlet air at the top of the housing 111 may be discharged along the air discharge surface, and the position limiting surface may restrict the upper air deflector 112 from continuing to move to the upper portion of the housing 111 , so that the housing 111 ) The outlet air at the top can move along the air discharge surface, making it possible to discharge the outlet air. In the present embodiment, when the upper air deflector 112 and the upper portion of the housing 111 are bonded to each other, the upper air deflector 112 is in a horizontal state. Of course, when the upper air deflector 112 is bonded to the upper portion of the housing 111 , a predetermined angle may exist between the upper air deflector 112 and the horizontal plane to enable ventilation.

Due to the Coanda effect, the outlet air may be attached to the inner surface of the housing 111 and aggregated on the upper portion of the housing 111 . At this time, the position limiting surface of the upper air deflector 112 is the upper portion of the housing 111 . Because it is bonded to the inner surface, the outlet air continues to move along the positioning surface of the upper air deflector 112 to realize the discharge of the outlet air. The air guide mechanism 110 of the present invention can overcome the problem that the outlet air is concentrated on the upper part of the housing 111 due to the Coanda effect, and through the bonding of the upper air deflector 112 and the upper part of the housing 111 By implementing the discharge of the outlet air at the top of the air conditioner, it is possible to prevent the outlet air from being concentrated in the upper part of the air conditioner, and the airflow amount of the air conditioner is increased, so that the blowing effect is ensured, and it becomes possible for the user to use it.

The lower air deflector 113 is positioned below the upper air deflector 112 , and the lower air deflector 113 is positioned at the air outlet. The driving assembly is connected to the lower air deflector 113 , and the driving assembly drives the lower air deflector 113 . The driving assembly may control the blowing direction of the air guide mechanism 110 by driving the lower air deflector 113 to move upward or downward. In addition, the upward movement or downward movement of the lower air deflector 113 in this embodiment refers to the movement direction of the air guide edge 1131 (the edge adjacent to the outer side of the housing 111) of the lower air deflector 113. points to When the driving mechanism is driven to move the lower air deflector 113 downward, that is, the air guide edge 1131 of the lower air deflector 113 moves downward, and the blowing direction of the tuyeres faces downward. When the driving mechanism is driven to move the lower air deflector 113 upward, that is, the air guide edge 1131 of the lower air deflector 113 moves upward, and the blowing direction of the tuyeres is upward.

As a possible embodiment, the driving assembly includes a motor and an electric part 114 , the motor is connected to the electric part 114 , and the electric part 114 is connected to the lower air deflector 113 . Transmission unit 114 includes a gear 1141 and a rack 1142, the gear 1141 is mounted on the output shaft of the motor, the rack 1142 is meshed with the gear 1141, and also the rack 1142 is connected to the edge of the lower air deflector 113 . The motor drives the gear 1141 to rotate, and the rack 1142 drives the lower air deflector 113 to move.

Specifically, the transmission of the transmission unit 114 is gear-rack transmission, which changes the transmission direction of motion through transmission of the gear-rack, and converts the rotation of the motor in the axial direction into a vertical lifting motion, and lower air By moving the deflector 113 up and down, the air guide mechanism 110 can serve to guide the wind, and furthermore, the blowing effect of the blower 100 is ensured, so that the landing effect of the outlet air of the air conditioner cabinet is reduced. implement Of course, the transmission of the electric part 114 may be a worm-gear transmission or a crank-connecting rod transmission, or other types of transmission. You just need to be able to

The other edge far from the airguide edge 1131 on the lower air deflector 113 is a driving edge 1132 . The gear 1141 is mounted on the output shaft of the motor, the rack 1142 is meshed with the gear 1141 , and the rack 1142 is connected to the driving edge 1132 of the lower air deflector 113 . The motor drives the gear 1141 to move, and further drives the rack 1142 to rotate the lower air deflector 113 . The rotation of the motor drives the gear 1141 to rotate, the gear 1141 drives the rack 1142 meshed with it to make a linear motion, and the linear motion of the rack 1142 is the lower air connected to the rack 1142. It is possible to rotate the deflector 113, so that the lower air deflector 113 can implement a movement to guide the wind. In this embodiment, the linear motion of the rack 1142 is a vertical motion, the gear 1141 drives the rack 1142 to move up and down, and furthermore, the lower air deflector 113 is driven to rotate up and down. Therefore, the wind guide effect of the air guide mechanism 110 is ensured, and further, the ground drop effect of the outlet air of the air conditioner is ensured.

An engaging portion is installed on the rack 1142 , and a circular shaft is installed on the driving edge 1132 of the lower air deflector 113 . The engaging portion is coupled to the circular shaft, and the movement of the rack 1142 drives the engaging portion to move the circular shaft, thereby rotating the lower air deflector 113 . The rack 1142 is connected to the lower air deflector 113 through the engaging portion, and further drives the lower air deflector 113 to rotate. In this embodiment, the engaging portion on the rack 1142 is similar to the hawk structure, and by firmly matching the rack 1142 and the lower air deflector 113, the reliability of the wind guiding movement of the lower air deflector 113 is ensured. And, further guarantee the wind guide effect of the air guide mechanism (110).

As a point to be explained, the upper air deflector 112 may be movable or may be placed in a horizontal state. When the upper air deflector 112 is in a horizontal state, the position limiting surface of the upper air deflector 112 is joined to the upper part of the housing 111 from start to finish, and the outlet air is discharged along the air blowing surface, so that the air conditioner can blow the air. . At this time, whether the air conditioner is heating or cooling, all of the upper air deflectors 112 in a horizontal state can improve the blowing amount of cold or hot air, so that the blowing effect of the air conditioner is guaranteed, and the performance of the air conditioner is improved.

Of course, the upper air deflector 112 may move, and the upper air deflector 112 may only move in the direction of the lower air deflector 113 . In this way, it is possible to ensure that the outlet air from the upper part of the housing 111 is discharged along the blowing surface of the upper air deflector 112, and to prevent a sudden change in the engagement portion between the blowing surface and the inner surface of the housing 111. , by allowing them to still be in contact with each other, thus ensuring a stable flow of the outlet air, thus allowing blowing.

At the same time, when the upper air deflector 112 moves in the direction of the lower air deflector 113 , that is, when the air conditioner blows downward, the blowing effect of falling to the ground when the air conditioner performs cooling or heating can be improved. In particular, when the air conditioner performs heating, since the density of hot air is smaller than the density of room temperature air, the upper air deflector 112 moves in the direction of the lower air deflector 113 to increase the effect of the hot air outlet air falling to the ground. It is possible to heat the air at room temperature while gradually increasing the hot air, thereby preventing temperature stratification during heating to ensure a heating effect, and to improve comfort during use.

Currently, when an air conditioner blows, the airflow of the outlet air is attached to the inner wall of the air conditioner, concentrated on the upper part of the air conditioner along the inner wall, and the air deflector is oscillating to guide the outlet air of the air duct to be discharged. Since the airflow of the air is still condensed and cannot be discharged, the airflow amount of the air conditioner is reduced, and the blowing efficiency of the air conditioner is lowered, which affects the user's use. The upper air deflector 112 of the air guide mechanism 110 of the present invention is joined to the inner surface of the upper portion of the housing 111 , and in this way, the outlet air at the upper portion of the housing 111 is discharged along the upper air deflector 112 . It is possible to discharge the condensed outlet air on the upper portion of the housing 111 due to the Coanda effect, and prevent the outlet air from condensing on the upper portion of the housing 111 due to the Coanda effect from affecting the blow rate , by improving the blowing efficiency of the air guide mechanism 110 to ensure the blowing effect of the air conditioner, it becomes possible to use the user.

In addition, the number of the lower air deflectors 113 is at least two, and the at least two lower air deflectors 113 are installed in parallel. At least two lower air deflectors 113 are installed in parallel to improve the wind guiding effect of the air guide mechanism 110, and the blower 100 can blow air, and further, the blowing effect of the air conditioner is improved, and the user The comfort during use is improved. In this embodiment, the number of the lower air deflectors 113 is two, and the two lower air deflectors 113 are installed in parallel, and located directly below the upper air deflector 112, the air guide mechanism 110 Blowing becomes possible by ensuring the wind guiding effect of

As a possible embodiment, the inner surface of the housing 111 and the surface of the upper air deflector 112 are smoothly transitioned or located on the same plane. That is, the inner surface of the housing 111 and the blowing surface of the upper air deflector 112 smoothly transition or are located on the same plane. In this way, the outlet air at the upper portion of the housing 111 can move to the blowing surface along the inner surface of the housing 111, so that the outlet air can flow without obstruction, and the airflow can be prevented from being blocked, so that the flow of the outlet air This becomes possible, and the blowing amount is increased, so that it is possible to ensure the blowing effect of the air conditioner.

As a possible embodiment, the upper air deflector 112 is rotatably mounted on the housing 111 , and the upper air deflector 112 is connected to the lower air deflector 113 through a connecting member. The air deflector 113 moves under the driving of the driving assembly, and the upper air deflector 112 moves in the direction of the lower air deflector 113 through the connecting member or is bonded to the upper portion of the housing 111 . A shaft hole is opened at a mounting position corresponding to the upper air deflector 112 of the housing 111 , and rotation shafts are installed at both ends of the upper air deflector 112 , and the rotation shaft is mounted to correspond to the shaft hole. In this way, the upper air deflector 112 is mounted on the shaft hole of the housing 111 through the rotation of the rotating shaft, and it is possible to guide the wind while the upper air deflector 112 rotates. The upper air deflector 112 implements the movement of the upper air deflector 112 toward the lower air deflector 113 through the rotation of the rotating shaft in the shaft hole.

Specifically, the motor of the drive assembly drives the gear 1141 to move the rack 1142 , and the rack 1142 drives the lower air deflector 113 to move. As the rack 1142 moves up and down, the driving edge 1132 far from the air guide edge 1131 of the lower air deflector 113 moves up and down, and further the air guide edge 1131 moves, and also the air guide edge The direction of movement of the 1131 is opposite to the direction of movement of the driving edge 1132 , thereby realizing the blowing of the air guide mechanism 110 .

Also, the movement of the upper air deflector 112 is driven through the lower air deflector 113 . When the driving assembly is driven to move the lower air deflector 113 downward, the lower air deflector 113 may drive the upper air deflector 112 to move toward the lower air deflector 113, and the air guide mechanism 110 ) performs downward blowing. When the driving assembly is driven to move the lower air deflector 113 upward, the upper air deflector 112 is bonded to the upper portion of the housing 111, and by the position limiting action of the position limiting surface of the upper air deflector 112, At this time, the upper air deflector 112 is in a horizontal state all the way and does not move toward the upper part of the housing 111 . At this time, the lower air deflector 113 of the air guide mechanism 110 blows upward, and the upper air deflector 112 of the air guide mechanism 11 blows horizontally.

At the same time, a connection relationship may not exist between the upper air deflector 112 and the lower air deflector 113 . At this time, the movement of the lower air deflector 113 does not affect the movement of the upper air deflector 112, so the upper air deflector 112 is always in a horizontal state, and the air guide mechanism through the lower air deflector 113 Implementing the upward blowing or downward blowing of 110, the upper air deflector 112 blows horizontally all the way. In this embodiment, the upper air deflector 112 and the lower air deflector 113 are connected, and by being connected through a connecting member, the blowing effect of the air guide mechanism 110 is improved, and the upper air deflector 112 is various A blowing mode is provided. When the upper air deflector 112 is in a horizontal state, the upper air deflector 112 performs horizontal ventilation to increase the amount of air blown. When the upper air deflector 112 moves downward, it is possible to further improve the effect of falling on the ground of the outlet air of the air conditioner, so that the user can use it.

In addition, the connecting member further includes a sliding rail 115, one end of the sliding rail 115 is installed in the upper air deflector 112, the other end of the sliding rail 115 is an upper air deflector 112 and lower air It is installed hanging between the deflectors (113). The lower air deflector 113 is connected to the sliding rail 115 , and the driving assembly drives the lower air deflector 113 to move along the sliding rail 115 , and the upper air deflector 112 moves the lower air deflector. By driving to move toward (113), the lower air deflector (113) is brought into contact with the inner surface of the housing (111) or placed in a horizontal state. In other words, the upper air deflector 112 is connected to the lower air deflector 113 through the sliding rail 115 . In this way, when the lower air deflector 113 blows upward, the movement of the lower air deflector 113 does not interfere with the upper air deflector 112, so that the blowing effect of the upper air deflector 112 is not affected. does not Specifically, when the lower air deflector 113 blows upward, the lower air deflector 113 may slide upward along the sliding rail 115 . At this time, the lower air deflector 113 is connected to the upper air deflector 112 . does not affect When the lower air deflector 113 blows downward, the lower air deflector 113 may drive the upper air deflector 112 to move downward along the sliding rail 115 .

In addition, the sliding rail 115 has a first end and a second end installed to face the first end. When the lower air deflector 113 moves to the first stage, the lower air deflector 113 may drive the upper air deflector 112 to move toward the lower air deflector 113 . When the lower air deflector 113 moves along the sliding rail 115 and moves to the second stage, the upper air deflector 112 is joined to the upper portion of the housing 111 .

In other words, when the lower air deflector 113 moves to the first stage, the lower air deflector 113 is placed at the first extreme position, and when the lower air deflector 113 moves to the second stage, the lower air deflector ( 113) is placed in the second extreme position. The first extreme position and the second extreme position may limit movement of the lower air deflector 113 . Specifically, when the lower air deflector 113 is placed in the first extreme position, the lower air deflector 113 may drive the upper air deflector 112 to move toward the lower air deflector 113 . When the lower air deflector 113 is placed between the first extreme position and the second extreme position and at the second extreme position, the upper air deflector 112 is placed in a horizontal state. The first extreme position and the second extreme position are for limiting movement of the lower air deflector 113 .

When the lower air deflector 113 moves to the second extreme position, the lower air deflector 113 cannot continue to move along the sliding rail 115, and the position limiting surface of the upper air deflector 112 is the housing 111 ), the upper air deflector 112 cannot move upward, and thus the upper air deflector 112 can limit the position of the lower air deflector 113, so that the lower air deflector 113 is It is no longer possible to move upward, and at this time, the upper air deflector 112 is in a horizontal state, and the lower air deflector 112 blows upward. When the lower air deflector 113 moves to the first extreme position, the lower air deflector 113 cannot continue to move along the sliding rail 115, and the drive assembly continues to move the lower air deflector 113 downward. At this time, the lower air deflector 113 pulls the upper air deflector 112 down through the sliding rail 115, and moves the upper air deflector 112 downward, so that the upper air deflector 112 is placed in the housing. In contact with the inner surface of (111) to implement the downward blowing.

At the same time, when the lower air deflector 113 reciprocates on the sliding rail 115, that is, when the lower air deflector 113 is placed between the first extreme position and the second extreme position, at this time, the lower air deflector 113 ) does not generate an operating force on the upper air deflector 112, so that the upper air deflector 112 is in a horizontal state.

In addition, the connecting member further includes a connecting rod 116 , the connecting rod 116 is connected to the upper air deflector 113 , and the connecting rod 116 has a sliding rail at one end far from the lower air deflector 113 . It is mounted on 115. In other words, the lower air deflector 113 is slidably connected to the sliding rail 115 through the connecting rod 116 . In addition, the number of the lower air deflectors 113 is at least two, and the connecting rod 116 may be connected through the at least two lower air deflectors 113 . The connecting rod 116 matches the movement angle of the at least two lower air deflectors 113 to ensure the blowing effect of the air guide mechanism 110 . In addition, the connecting rod 116 is installed adjacent to the air guide edge 1131 of the lower air deflector 113 . Of course, there may be only the connecting rod 116 as the connecting member, but there may be some influence when the lower air deflector 113 is driven to move the upper air deflector 113 upward, but the air guide mechanism ( 110) is not affected. The connecting member may also have other structures that can ensure that there is no interference in the motion of the lower air deflector 113 and the upper air deflector 113 .

In this embodiment, when the lower air deflector 113 is in a horizontal state, the connecting rod 116 is in the first extreme position. When the lower air deflector 113 blows downward, the driving assembly drives the lower air deflector 113 to continuously move downward from the first extreme position, and the connecting rod 116 drives the sliding rail 115 to move downward. , to move the upper air deflector 112 downward. When the lower air deflector 113 blows upward, the driving assembly drives the lower air deflector 113 to move upward along the sliding rail 115 through the connecting rod 116 .

Preferably, in this embodiment, a hook part is installed on the connecting rod 116 , and a sliding groove is installed on the sliding rail 115 , and the hook part is mounted on the sliding groove and moves along the sliding groove. The hook portion of the connecting rod 116 is mounted on the sliding groove of the sliding rail 115 to ensure stable movement of the connecting rod 116 and further guarantee the wind guiding effect of the lower air deflector 113 . At the same time, the number of connecting rods 116 is equal to the number of sliding rails 115, and there are two in all. The two connecting rods 116 are installed to face the lower air deflector 113 , and the sliding rail 115 is installed to correspond to the connecting rod 116 . The matching of the two connecting rods 116 and the two sliding rails 115 enables the lower air deflector 113 to move stably, and further ensures the wind guiding effect of the lower air deflector 113 .

As a possible implementation, the air guide mechanism 110 further includes a torsion member 117 . The torsion member 117 is mounted on the upper air deflector 112 , and the torsion member 117 brings the upper air deflector 112 into contact with the inner surface of the housing 111 . In this embodiment, the torsion member 117 is a torsion spring. The torsion member 117 is installed on the upper air deflector 112 so that the upper air deflector 112 can be in close contact with the inner surface of the housing 111 by the action of the torsion member 117 , that is, the upper air deflector. By preventing the gap between the upper air deflector 112 and the inner surface of the housing 111, the 112 is in full or partially contact with the inner surface of the housing 111 from beginning to end under the action of the torsion member 117. Guarantee the blowing effect. At the same time, when the lower air deflector 113 blows downward, the driving assembly is driven so that the lower air deflector 113 overcomes the torsional force of the torsion member 117 to move the upper air deflector 112 downward. There is a need. In other words, only when the downward traction force provided by the connecting rod 116 is greater than the torsional force of the torsion member 117, the upper air deflector 112 can only move downward, otherwise, the upper air deflector 112 is always horizontal. In addition, the torsion member 117 may ensure that the upper air deflector 112 is still in a horizontal state even when a minute movement occurs in the lower air deflector 113 .

The blower plate (including the upper air deflector 112 and the lower air deflector 113) in the second embodiment of the present invention is the air deflector assembly (the second air deflector 212 and the second air deflector 212) provided by the first embodiment of the present invention. 1 has the same action as the air deflector 213), that is, the upper air deflector guides the airflow of the outlet air to be blown toward the ground (i.e., only guides the wind downward), and prevents it from flowing upward, so the upper position of the tuyere All of the outlet air of the air duct condensed in the air duct is guided to be blown toward the ground through the upper air deflector. At the same time, the structure of the lower air deflector may guide the airflow upward, and the lower air deflector creates a cushioning action in the upper air deflector, thereby guiding some of the upwardly flowing airflow to flow downward, and thus the ground level of the outlet air. By optimizing the drop effect, the comfort of the air conditioner is improved.

In addition, the gear 1141, the rack 1142, the connecting member (including the sliding rail 115 and the connecting rod 116) and the torsion member 117 in the second embodiment of the present invention are each of the first Since it has the same action as the motor gear 2141, the meshing rack 2142, the connecting device (including the first connecting rod 216 and the second connecting rod 215) and the torsion spring 217 in the embodiment, overlapping here A description is omitted. In addition, the air guide mechanism 110 provided by the second embodiment of the present invention guides the outlet air affected by the Coanda effect, so that the outlet air condensed in the upper part of the housing 111 can be completely discharged, so the amount of air blown This increases, the blowing efficiency is improved, and the blowing effect can be ensured. When the air guide mechanism 110 needs to control the downward blowing, the lower air deflector 113 moves downward, and the upper air deflector 112 downwards through the connecting rod 116 and the sliding rail 115 . By driving to move, the flow direction of the outlet air at the upper portion of the housing 111 can be smoothly changed, thereby improving the overall downward blowing effect. When the air guide mechanism 110 needs to control upward blowing, the lower air deflector 113 moves upward along the sliding rail 115 through the connecting rod 116 to form an upward inclination angle, and blows upward. to implement At this time, the upper air deflector 112 is placed in a horizontal position.

The air guide mechanism 110 provided by the second embodiment of the present invention overcomes the influence due to the Coanda effect of the outlet air, and increases the blowing amount of the air guide mechanism 110, thereby changing the cooling and heating blowing direction of the air conditioner. Good controllable. In particular, when heating is performed with the air conditioner, the downward blowing of the upper air deflector 112 prevents temperature stratification during heating caused by the inability of the outlet air to flow downward, thereby ensuring a heating effect.

The third embodiment of the present invention further provides a blower 100 including the air outlet mask 120 and the air guide mechanism 110 in the above embodiment. The air outlet grill 121 is installed in the air outlet mask 120 , the air outlet mask 120 is installed to cover the air guide mechanism 110 , and the air outlet grill 121 is the air outlet grill 121 of the air guide mechanism 110 . Corresponds to the vent. The outlet air of the air guide mechanism 110 is discharged from the air outlet grill 121 of the air outlet mask 120 . The blower 100 implements blowing through the air guide mechanism 110 , and the blowing efficiency is improved by increasing the blowing amount, thereby ensuring the blowing effect of the air conditioner.

A fourth embodiment of the present invention further provides an air conditioner including the air conditioner body and the blower 100 in the above embodiment. The blower 100 is located above the air conditioner body. Also, the air conditioner of the present invention particularly refers to a floor type air conditioner. At the same time, the same or similar centrifugal air duct and its tuyere are installed in the main body of the air conditioner of the present invention.

The outlet air flow of the centrifugal air duct tuyere of the air conditioner has an adhesion action in the volute diffuser section and the volute inner wall, and even after moving to the blower 100, a very strong wall adhesion action continues, and the outlet air is mostly concentrated by rising to the upper part of the housing 111, limited by the structure of the upper part of the housing 111 and guided at a right angle, so that the blowing direction is directed from the vertical upward to the front in a plane, and after the outlet air leaves the tuyere , is blown horizontally forward. Therefore, the air conditioner of the present invention implements the discharge of the outlet air condensed on the upper portion of the housing 111 through the air guide mechanism 110 of the blower 100 to prevent the outlet air from being aggregated on the upper portion of the housing 111 . By preventing it, the blowing amount is increased to improve the blowing efficiency, and to ensure the blowing effect of the air conditioner.

The above embodiment is only for clearly explaining the embodiment to be implemented, and is not intended to limit the implementation method, and for those skilled in the art, other different types of changes or changes may be made based on the above description. It is self-evident that Here, it is not necessary, nor is it necessary to exemplify all embodiments, and obvious changes or variations derived therefrom still fall within the protection scope of the present invention.

Claims (16)

In the air deflector assembly installed in the vent part of the air conditioner,
a first air deflector that is rotatably installed and guides the airflow of the outlet air of the air conditioner to be swept up and down; and
A second air deflector installed at an upper position of the air outlet of the air conditioner and positioned above the first air deflector to guide the airflow of the outlet air to be blown only toward the ground,
The first air deflector and the first air deflector are installed in parallel, the second air deflector is rotatably installed, and the second air deflector is rotatably installed only in a direction toward the ground,
An upper brace is installed on the side facing the ground of the second air deflector, and the upper brace is for preventing the second air deflector from rotating in a direction facing the ground,
Air characterized in that a connection device is provided between the first air deflector and the second air deflector, and when the first air deflector rotates in the ground direction, the second air deflector is simultaneously driven to rotate in the ground direction deflector assembly. delete delete According to claim 1,
The upper holding device is a torsion spring installed on the rotation shaft of the second air deflector, and the torsion spring is for restricting the rotation of the second air deflector only in a direction toward the ground. Air deflector assembly, characterized in that. delete According to claim 1,
The connecting device may include: a first connecting rod connected to the first air deflector and having a guide hole extending along a moving direction at one end facing the second air deflector;
The first end is connected to the swinging end of the second air deflector, the second end of the air deflector assembly characterized in that it comprises a second connecting rod slidably installed in the guide hole. 7. The method of claim 6,
and the second connecting rod includes two cantilevers and is installed in parallel, a latch is fixedly connected between the two cantilevers, and the latch is installed through the guide hole. 7. The method of claim 6,
The number of the first air deflectors is plural, the plurality of first air deflectors are installed in parallel, and the first connecting rod passes through the plurality of first air deflectors and is fixedly connected to each of the first air deflectors Air deflector assembly, characterized in that. 9. The method of claim 8,
The air deflector assembly may include: a meshing rack driven and connected to a plurality of the first air deflectors;
It is connected to the drive output shaft of the motor, further comprising a motor gear meshing with the meshing rack;
An air deflector assembly, characterized in that both the meshing rack and the motor gear are located on a side farther from the tuyere of the first air deflector. In the air guide mechanism,
a housing having a hollow accommodation cavity, the air outlet of the air conditioner being opened, and the air outlet communicating with the accommodation cavity; and
Installed in the housing, located at the upper edge of the air outlet, contactable with the upper portion of the housing, characterized in that it comprises the air deflector assembly according to claim 1 for discharging the outlet air condensed on the upper portion of the housing. air guide mechanism. 11. The method of claim 10,
the air deflector assembly is joined to the upper portion of the housing; or an edge of the air deflector assembly may abut against an upper portion of the housing. 11. The method of claim 10,
the second air deflector is mounted on the housing and is located at an upper edge of the tuyere;
the second air deflector may be in contact with an upper portion of the housing, and the second air deflector is for discharging outlet air condensed on the upper portion of the housing; The first air deflector is an air guide mechanism, characterized in that located in the air outlet. 13. The method of claim 12,
An air guide mechanism, characterized in that the inner surface of the housing and the surface of the second air deflector are smoothly transitioned or located on the same plane. In the blower device,
an air outlet mask and an air guide mechanism according to any one of claims 10 to 13;
an air outlet grill is installed on the outlet air mask; The air outlet mask is installed to cover the air guide mechanism, and the air outlet grille is a blower, characterized in that corresponding to the air outlet of the air guide mechanism. In the air conditioner,
comprising the air conditioner body and the blower according to claim 14;
The blower is an air conditioner, characterized in that located on the upper portion of the air conditioner body. In the air conditioner comprising a housing, the vent is installed on the upper portion of the housing,
The air conditioner further comprises the air deflector assembly according to any one of claims 1, 4, 6 to 9, wherein the air deflector assembly is installed in the air outlet portion, 2 The air deflector air conditioner, characterized in that located in the upper position of the tuyere.

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