JP2022519799A - Air conditioning outlet assembly and air conditioning including this air conditioning outlet assembly - Google Patents

Abstract

The present invention relates to an air conditioning outlet assembly and air conditioning including the air conditioning outlet assembly. The air conditioning outlet assembly is located in the air passage and an outlet grid holder that includes a suction port end, an outlet end, and an air passage formed between the suction port end and the air outlet end, each of which is located in the air passage. It includes at least one baffle plate that can rotate along the horizontal axis and at least one flap that is located at the outlet end and can rotate along the vertical axis, respectively. Therefore, in the air conditioning blowout assembly of the present invention, the flap is located outside or downstream of the baffle plate. Since the left and right rotation of the flap is no longer affected by the baffle plate and air passage structure, it is possible to eliminate or minimize the blowout blind spots on both the left and right sides of the air conditioner, and this air conditioner has at most 12 different types. A blast mode can be provided. [Selection diagram] Fig. 1

Description

The present invention relates to an air conditioning system, specifically an air conditioning outlet assembly and air conditioning including the air conditioning outlet assembly.

Air conditioning includes, but is not limited to, integrated air conditioning, split air conditioning or central air conditioning systems. Air conditioning can also refer to an indoor unit or a terminal unit of air conditioning. In a regulated space (eg indoors), the regulated air is sucked into the air conditioner and exchanged with a heat exchanger (eg heat exchange coil) to form a cold (cooling) or warm (heating) heat exchange air. Will be done. Such heat exchange air can be blown out directly from the air-conditioning outlet, mixed with natural wind from indoors or outdoors, and blown out from the air-conditioning outlet. In order to control the blowing direction of the heat exchange air or the mixed air, a baffle plate or a vertical flap is usually provided near the air outlet of the air conditioner. The baffle plate is generally mounted horizontally to the air conditioning outlet and can rotate up and down along the horizontal axis under the drive of the drive, thereby blowing air diagonally upward from the air conditioning. , Controls to blow out horizontally or diagonally downward. The plurality of vertical flaps are attached to the inside of the baffle plate (along the direction of viewing from the outside to the inside of the air conditioner), that is, located upstream of the baffle plate along the direction of wind flow. The plurality of vertical flaps are connected by flap connecting rods and can be swung left and right under the drive of a drive device, thereby controlling the air conditioning wind direction to blow to the left or right.

For example, Utility Model No. 208186560 of China discloses a baffle plate and a flap arranged near the air outlet of an air conditioner. Specifically, in this practical proposal, two baffle plates are provided inside the air outlet of the air-conditioning indoor unit, and each baffle plate is arranged in the horizontal direction, and the axis line parallel to the horizontal direction of the air-conditioning indoor unit. It can be rotated around to adjust the vertical blowout direction. Multiple flaps are also placed inside the air outlet of the air conditioning indoor unit and also inside the baffle plate (in other words, located upstream of the baffle plate). In addition, these multiple flaps are spaced around the connecting rods so that they can rotate around the axis, allowing these multiple flaps to swing laterally to the left and right of the air conditioning indoor unit under the drive of a motor. .. However, since the vertical flaps are located inside the baffle plate, the lateral swing of the vertical flaps is limited to the baffle plate and the air passage structure on both the left and right sides, which makes it relatively relatively on both the left and right sides. There is a large blowout blind spot.

Therefore, there is a need for new technical solutions in this area to solve the above problems.

In order to solve the above-mentioned problems in the prior art, that is, to solve the technical problem that the conventional air-conditioned blowout assembly generates a relatively large left and right blowout blind spots, the present invention provides an air-conditioning blowout assembly. , The air conditioning outlet assembly is arranged in the air passage and an outlet grid holder including a suction port end, an outlet end, and an air passage formed between the suction port end and the air outlet end. Each includes at least one baffle plate that can rotate along the horizontal axis and at least one flap that is located at the outlet end and can rotate along the vertical axis, respectively.

In a preferred embodiment of the air conditioning blowout assembly, each of the flaps can be independently controlled and rotated.

In a preferred embodiment of the air conditioning blowout module, the plurality of flaps can result in a uniform blow mode, a partition blow mode, and a manual blow mode.

In a preferred embodiment of the air conditioning blowout assembly, the plurality of flaps are grouped into a plurality of flap compartments to realize the partition ventilation mode with different rotation angles of the flaps in each flap compartment.

In a preferred technical aspect of the air-conditioning blow-out assembly, a low-stage, medium-low stage, medium-high stage, and high-stage ventilation stage can be formed for each flap section depending on the rotation angle of the flap.

In a preferred embodiment of the air conditioning blowout assembly, the flaps can be painted in different colors.

In a preferred technical aspect of the air conditioning blowout assembly, the baffle plate is provided with a plurality of breeze holes extending perpendicular to the surface of the baffle plate and penetrating the thickness of the baffle plate.

In a preferred technical aspect of the air conditioning blown assembly, the baffle plate can generate a breeze blast mode and a non-breath blast mode.

In a preferred technical aspect of the air conditioning outlet assembly, the air conditioning outlet assembly further comprises an outlet panel, the outlet panel is provided with a panel outlet, and the outlet panel is fixed to the outlet end of the outlet grid holder. It can be aligned with the panel outlet and the outlet at the outlet end.

As will be appreciated by those skilled in the art, the air conditioning blowout assembly of the present invention includes a blowout grid holder, a baffle plate and flaps. The flaps are rotatably arranged to the left and right at the outlet end of the outlet grid holder, and the baffle plate is rotatably arranged up and down in the air passage located upstream of the outlet end, so that it is viewed from the outside of the air conditioner. And the flap is located on the outside or downstream of the baffle plate. Since the left and right rotation of the flap is no longer affected by the baffle plate and the air passage structure, it is possible to eliminate or minimize the blowout blind spots on both the left and right sides of the air conditioner.

Preferably, each flap can be independently controlled and rotated, which allows the user to simultaneously meet more different needs for blowout.

Preferably, the flaps are grouped into a plurality of flap compartments to achieve the purpose of compartment ventilation.

Multiple flaps can result in uniform ventilation mode, partition ventilation mode, and manual ventilation mode. Further, in the partition ventilation mode, it is possible to form a low stage, a middle low stage, a middle high stage, and a high stage ventilation stage. Therefore, six different ventilation modes can be formed based solely on the flaps.

Preferably, since the baffle plate is provided with a plurality of breeze holes, the baffle plate can provide a breeze blowing mode and a non-breeze blowing mode. Furthermore, by combining the blast mode that can be provided by the baffle plate and the blast mode that can be provided by the flap, 12 different blast modes can be formed, that is, in the breeze blast mode and the non-breath blast mode, respectively, 6 types depending on the flap. Different ventilation modes can be provided.

Preferably, the flaps can be painted in different colors to form a rainbow-like flap to meet the user's unique customization needs.

The present invention further provides air conditioning including any one of the air conditioning outlet assemblies described above. Since the flaps are located on the outside of the baffle plate, the air-conditioning blind spot can be eliminated or minimized, and various ventilation modes can be provided to meet the user's unique ventilation needs. Can be done.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
It is a perspective view of the Example of the air-conditioning blowout assembly which concerns on this invention. It is a front view which shows the Example of the flap of the air-conditioning blowing assembly which concerns on this invention. It is a left side view which shows the example of the flap of the air conditioning blowout assembly which concerns on this invention. It is a front view which shows the Example of the baffle plate of the air-conditioning blowing assembly which concerns on this invention. It is a rear view which shows the Example of the baffle plate of the air-conditioning blowing assembly which concerns on this invention. It is a side view which shows the Example of the baffle plate of the air-conditioning blowing assembly which concerns on this invention. It is a perspective view which shows the Example of the blowout grid holder of the air-conditioning blowout assembly which concerns on this invention. It is a front view which shows the Example of the blowout grid holder of the air-conditioning blowout assembly which concerns on this invention. It is a perspective view which shows the Example of the blowout grid holder of the air-conditioning blowout assembly which concerns on this invention. It is a right-side view which shows the Example of the blowout grid holder of the air-conditioning blowout assembly which concerns on this invention. FIG. 8 is a sectional view taken along the line AA showing an embodiment of a blowout grid holder of the air-conditioning blowout assembly according to the present invention shown in FIG. It is a perspective view of another embodiment of the air-conditioning blowout assembly which concerns on this invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. Those skilled in the art will appreciate that these embodiments illustrate the technical principles of the invention and do not limit the scope of protection of the invention.

In the description of the present invention, the terms "top", "bottom", "left", "right", "front", "rear", "inside", "outside", "top", "bottom", etc. The term for orientation or positional relationship is based on the orientation or positional relationship shown in the drawings and is merely for ease of explanation, and the device or component has a specific orientation or is specified. It does not indicate that it must be configured and operated in the orientation of, and cannot be understood as a constraint on the present invention. The terms "first", "second", "third", and "fourth" are used only for explanatory purposes, but should be understood as indicating relative importance or suggestive. Can't.

In the description of the present invention, the terms "mounting", "installation", "connection", and "connection" should be understood in a broad sense unless there is a clear provision or limitation, for example, in fixed connection. It may be a removable connection, an integral connection, a direct connection, or an indirect connection by an intermediate medium, which is a communication inside the two elements. You may. A person skilled in the art can understand the specific meanings of the above-mentioned terms in the present invention depending on the specific circumstances.

In order to solve the technical problem of the left and right blowout blind spots due to the conventional air conditioning blowout assembly, the present invention provides the air conditioning blowout assembly 1. The air-conditioning outlet assembly 1 is arranged in the outlet grid holder 14 including the suction port end 141e, the air outlet end 141a, and the air passage formed between the suction port end 141e and the air outlet end 141a, and the air passage. Each includes at least one baffle plate 13 that can rotate along the horizontal axis and at least one flap 12 that is located at the outlet end 141a and can rotate along the vertical axis, respectively.

FIG. 1 is a perspective view of an embodiment of an air conditioning blowout assembly according to the present invention. As shown in FIG. 1, in one or more embodiments, the air conditioning blowout assembly 1 includes a blowout panel 11, a plurality of flaps 12, a baffle plate 13 and a blowout grid holder 14. The outlet panel 11 is attached to the outer surface of the outlet end 141a (see FIGS. 7-8) of the outlet grid holder 14. At the intermediate position of the outlet panel 11, a panel outlet (not shown) is provided so as to be aligned with the outlet end 141b of the outlet end 141a and to allow the wind to be blown out from the panel outlet.

FIG. 2 is a front view showing an embodiment of the flap of the air-conditioning outlet assembly of the present invention, and FIG. 3 is a left side view showing an embodiment of the flap of the air-conditioning outlet assembly of the present invention. As shown in FIGS. 2 and 3, in one or more embodiments, each flap 12 includes a flap body 121, a first flap rotating shaft 122, and a second flap rotating shaft 123. In one or more embodiments, the flap body 121 has a substantially rectangular plate-like structure, which has a substantially flat front and back surface. When the flap 12 is positioned in the vertical direction, the two short sides of the flap body 121 are formed with an upper edge and a lower edge, respectively, and the first flap rotation shaft 122 and the second flap rotation shaft 123 are respectively of the flap body 121. Located on the upper and lower edges. For example, as shown in FIG. 3, pedestals are formed on each of the upper and lower edges, and these two pedestals are formed on the rear surface of the flap body 121 and extend outward perpendicular to the rear surface. The first flap rotation shaft 122 and the second flap rotation shaft 123 are formed on the corresponding pedestals, respectively, and extend vertically outward from the corresponding pedestals (direction away from the upper edge or the lower edge). Therefore, the first and second flap rotation axes 122 and 123 are parallel to the flap body 121. The first flap rotation shaft 122 and the second flap rotation shaft 123 are rotatably provided about the same axis line, and rotate around the first axis line C1, for example. Optionally, the second flap rotary shaft 122 is provided so that it can be connected to a drive device such as a motor to drive and rotate the flap. Alternatively, the flap body 12 may adopt other shapes such as a square or a leaf-like blade.

In one or more embodiments, the plurality of flaps 12 can also be applied in different colors. The user can customize the flap 12 and paint it in different colors based on his or her individual needs, thereby making the air conditioning look even more beautiful and satisfying the user's specific aesthetic needs. can.

FIG. 4 is a front view showing an embodiment of a baffle plate of an air-conditioning blowout assembly according to the present invention, and FIG. 5 is a rear view showing an embodiment of a baffle plate of the air-conditioning blowout assembly according to the present invention. Is a side view showing an embodiment of a baffle plate of an air conditioning blower assembly according to the present invention. As shown in FIGS. 4 to 6, the baffle plate 13 includes a baffle plate main body 131, a breeze hole 133 formed in the baffle plate main body 131, and a baffle plate rotating shaft. In one or more embodiments, the baffle plate body 131 is a substantially rectangular thin plate, having a substantially flat front surface 132 and a substantially flat rear surface 134. Alternatively, if desired, the baffle plate body 131 may adopt a square or other suitable shape.

Referring to FIGS. 4 and 5, in one or more embodiments, the front surface 132 of the baffle plate body 131 is adjacent because the plurality of breeze holes 133 are evenly arranged in the plurality of rows and columns. The distance L1 between the breeze holes 133 is the same. These breeze holes 133 vertically penetrate the thickness of the baffle plate main body 131 from the front surface 132 of the baffle plate main body 131 to reach the rear surface 134. Further, when the length of the baffle plate main body 131 exceeds a certain size, the breeze holes 133 in the baffle plate main body 131 are, for example, two breeze hole sections, three breeze hole sections, or more. The distance between adjacent breeze compartments is greater than the distance between adjacent breeze pores so that they can be divided into a plurality of breeze compartments, such as a breeze compartment. As shown in FIGS. 4 and 5, in one or more embodiments, the breeze holes 133 have four breeze holes 133a, a second breeze hole 133b, a third breeze hole 133c, and a fourth breeze hole 133d. It is divided into breeze holes. The distance L2 between adjacent breeze compartments should be greater than L1. Each boutlet compartment may contain the same number of breeze holes, depending on the actual needs. For example, it may include breeze holes 133 arranged in the same row and column. It may also include a different number of breeze holes 133. Therefore, they line up in different rows and / or columns. Further, in order to guarantee the strength of the baffle plate, it is necessary to keep a certain distance L3 between the breeze hole 133 and the peripheral edge of the baffle plate main body 131, and this distance is, for example, about 8 mm, and the adjacent breeze holes are adjacent to each other. It should be greater than the distance L1 between 133.

Referring to FIGS. 5 and 6, a plurality of baffle plate rotating shafts (for example, two or more) are formed on the rear surface 134 of the baffle plate main body 131, and these baffle plate rotating shafts form a coaxial cable. Therefore, it can be rotated around the same axis. In one or more embodiments, five baffle plate rotation shafts are formed on the rear surface 134. That is, the first baffle plate rotating shaft 135a, the second baffle plate rotating shaft 135b, the third baffle plate rotating shaft 135c, the fourth baffle plate rotating shaft 135d, and the fifth baffle plate rotating shaft 135e. The first baffle plate rotating shaft 135a and the fifth baffle plate rotating shaft 135e are arranged at two opposite short side ends of the baffle plate main body 131, respectively. It also extends outward from the corresponding short side edge. The second baffle plate rotating shaft 135b is provided in a section corresponding to the distance between the first breeze hole section 133a and the second breeze hole section 133b, and the third baffle plate rotating shaft 135c is a second breeze hole. The fourth baffle plate rotating shaft 135d is provided in a section corresponding to the distance between the section 133b and the third breeze hole section 133c, and the fourth baffle plate rotating shaft 135d is the distance between the third breeze hole section 133c and the fourth breeze hole section 133d. It is installed in the section corresponding to the distance. Optionally, the extension direction of the second baffle plate rotation shaft 135b and the third baffle plate rotation shaft 135c is the same as that of the first baffle plate rotation shaft 135a, and the extension of the fourth baffle plate rotation shaft 135d. The direction is the same as that of the fifth baffle plate rotating shaft 135e. Alternatively, the stretching direction of these baffle plate rotation shafts may be configured in another stretching direction, if necessary. For example, the stretching direction of the third baffle plate rotating shaft 135c and the fourth baffle plate rotating shaft 135d is the same as that of the fifth baffle plate rotating shaft 135e, and the stretching direction of the second baffle plate rotating shaft 135b is. , The direction is the same as that of the first baffle plate rotating shaft 135a. Further, it is necessary to secure the strength of the baffle plate by keeping a certain distance between the breeze hole 133 and the adjacent baffle plate rotation shaft.

FIG. 7 is a perspective view showing an embodiment of an air-conditioning blowout assembly blowout grid holder according to the present invention, and FIG. 8 is a front view showing an example of an air-conditioning blowout assembly blowout grid holder according to the present invention. FIG. 9 is a perspective view showing an embodiment of an air-conditioning blowout assembly blowout grid holder according to the present invention, and FIG. 10 is a right side view showing an example of an air-conditioning blowout assembly blowout grid holder according to the present invention. FIG. 11 is a cross-sectional view taken along the line AA showing an embodiment of the blowout grid holder of the air conditioning blowout assembly according to the present invention shown in FIG. As shown in FIGS. 7-11, the outlet grid holder 14 includes an outlet end 141a, a suction port end 141e, and an air passage extending between the outlet end 141a and the suction port end 141e. As shown in FIGS. 7 and 8, an outlet 141b is formed at the outlet end 141a. The outlet 141b corresponds to the panel outlet in the outlet panel 11, and may have the same size, for example. A suction port is formed at the suction port end 141e (not shown in the figure), whereby when the suction port end 141e is joined to the outlet passage inside the air conditioner, the suction port is provided with heat exchange air. Allows flow from to the air passage. With reference to FIGS. 9-11, in one or more embodiments, the air passage is surrounded by a left wall 141c, a right wall 141f, a front wall 141d and a rear wall 141g, based on the orientation shown in FIG. It has a substantially rectangular flow cross section. Alternatively, the air passage may use a flow section of a different shape depending on the actual needs.

As shown in FIGS. 7 and 8, the outlet end 141a has a top wall that extends around (not shown) perpendicular to the air passage. This top wall surrounds the outlet 141b and matches the shape of the outlet panel 11. In one or more embodiments, a plurality of outlet panel locking ports 144 are formed on the apex wall along the two opposing long sides of the outlet 141b, eg, atop along each long side. Eight outlet panel locking ports 144 are formed on the wall. These outlet panel locking ports 144 are symmetrical with respect to the vertical center line C2 of the outlet 141b. Therefore, on the back surface of the blowout panel 11, a corresponding lock is made so that the blowout panel 11 is fixed to the blowout end 14a of the blowout grid holder 14 by locking the locking port 144 of the blowout panel and the locking structure. A structure is provided and the lock between the blowout panel lock port 144 and the lock structure is removable. Alternatively, different numbers of blowout panel locking openings may be formed on the top wall, if desired.

Referring to FIGS. 7 and 8, in one or more embodiments, a plurality of baffle plate holders 143 are provided in the air passages of the blowout grid holder 14. If the baffle plates are relatively long, these baffle plate holders can support the baffle plates so that they are not deformed or unstable. Whether or not to install the baffle plate holders and the specific number of baffle plate holders can be determined by the size and / or shape of the baffle plate. In one or more embodiments, three baffle plate holders 143, a first baffle plate holder 143a, a second baffle plate holder 143b, and a third baffle plate holder 143c, are provided in the air passage. As shown in FIG. 7, the first baffle plate holder 143a, the second baffle plate holder 143b, and the third baffle plate holder 143c are arranged apart from each other and in parallel.

Referring to FIG. 11, each baffle plate holder is formed with two protrusions extending on the same side (toward the air outlet end 141a) of the baffle plate holder, and the upper protrusion and the lower protrusion (direction shown in FIG. 11) are formed. A second baffle plate shaft hole 142b is formed in each protrusion so as to penetrate the thickness of the protrusion. The upper protrusions of the three baffle plate holders and the second baffle plate shaft hole 142b in the upper protrusions are arranged on the same vertical axis line (the axis line parallel to the vertical center line C2), and the lower protrusions of the three baffle plate holders and the lower baffle plate holders. The second baffle plate shaft hole 142b in that is also arranged on another vertical axis line (axis line parallel to the vertical center line C2). The upper protrusions of the three baffle holders are used to engage with the same baffle plate, and their lower protrusions are used to engage with another baffle plate. This means that two baffles are placed in the air passage. Alternatively, the specific number of baffle plates can be determined as needed. Each second baffle plate shaft hole 142b on the same vertical axis is the second baffle plate rotation shaft 135b, the third baffle plate rotation shaft 135c, or the fourth baffle plate rotation shaft 135d of one baffle plate 13. It houses the corresponding one of them and is configured to allow the corresponding baffle plate rotation shaft to rotate about this baffle plate shaft hole. Optionally, each baffle rotating shaft is fitted into the corresponding second baffle shaft hole 142b via a bush (not shown).

As shown in FIG. 7, in one or more embodiments, two first baffle plate shaft holes 142a are formed in the left wall 141c of the air passage, and the two first baffle plate shaft holes 142a are formed. Positioned close to the suction port 141e. Based on the orientation shown in FIG. 7, the two first baffle plate shaft holes 142a are located one above each other and the other below, both of which suck in the blowout grid holder 14. Close to the mouth end 141e. The first baffle plate shaft hole 142a located above is aligned with the second baffle plate shaft hole 142b (that is, has the same axis) in the upper protrusion of each baffle plate holder 143, and the first position located below. The baffle plate shaft hole 142a is aligned with the second baffle plate shaft hole 142b in the lower protrusion of each baffle plate holder 143 (that is, has the same axis line). Each first baffle plate shaft hole 142a accommodates the first baffle plate rotation shaft 135a of one baffle plate 13. Referring to FIG. 10, in one or more embodiments, two third baffle plate shaft holes 142c are also formed on the right wall 141f of the air passage, and the positioning of the two third baffle plate shaft holes 142c is performed. Is also close to the outlet end 141e of the outlet grid holder 14. Based on the orientation shown in FIG. 10, these two third baffle plate shaft holes 142c are vertically aligned. The third baffle plate shaft hole 142c located above is aligned with the second baffle plate shaft hole 142b located in the upper protrusion of each baffle plate holder 143, and the third baffle plate shaft hole 142c located below. Is aligned with the second baffle plate shaft hole 142b located in the lower protrusion of each baffle plate holder 143. In one or more embodiments, the third baffle shaft hole 142c can accommodate the fifth baffle rotating shaft 135e of the baffle plate 13, and the fifth baffle rotating shaft 135e is It is configured to be rotatable in the baffle plate shaft hole. Therefore, all the baffle plate rotation axes in each baffle plate 13 are the first baffle plate shaft holes 142a, the second, so that each baffle plate 13 rotates about the axis parallel to the vertical center line C2. It can be received by the corresponding one of the baffle plate shaft hole 142b and the third baffle plate shaft hole 142c, respectively. Alternatively, as the number of baffle plates 13 changes, so does the number of first baffle plate shaft holes 142a in the left wall 141c and the number of third baffle plate shaft holes 142c in the right wall 141f. For example, if the number of the baffle plates 13 is 3, the number of the first baffle plate shaft holes 142a and the number of the third baffle plate shaft holes 142c are both 3. Optionally, each baffle rotating shaft is fitted into the corresponding first and third baffle shaft holes 142a, 142c via a bush (not shown).

Referring to FIG. 9, a plurality of flap shaft holes 145 are formed in the front wall 141d and the rear wall 141g of the air passage, respectively, and these outlet shaft holes 145 are before being positioned at the outlet end 141a of the outlet grid holder 14. The number of flap shaft holes 145 in each of the wall 141d and the rear wall 141g is the same as the number of flaps 12, and each flap shaft hole 145 in the front wall 141d and one corresponding flap shaft hole 145 in the rear wall 141g (shown). Is symmetrical with respect to the vertical axis line C2, thereby accommodating one of the flap rotation axis 122 and the second flap rotation axis 123 of one flap 12, respectively. The first flap rotation shaft 122 and the second flap rotation shaft 123 can be rotated about an axis in these flap shaft holes. In one or more embodiments, the flap shaft hole 145 in the front wall 141d is configured to accommodate the second flap rotating shaft 123 of the flap 12, and the flap shaft hole 145 in the rear wall 141g is a flap. It is configured to accommodate 12 first flap rotation shafts 122. Alternatively, the flap shaft hole 145 in the front wall 141d is configured to accommodate the first flap shaft 122 of the flap 12, and the flap shaft hole 145 in the rear wall 141g is the second flap of the flap 12. It is configured to accommodate the shaft 123. Optionally, the first and second flap rotation shafts 122, 123 can be fitted into the corresponding flap shaft holes, respectively, via bushes (not shown).

When the air conditioning blowout assembly 1 according to the present invention is activated, the baffle plate 13 (generally in the horizontal direction) can provide two blast modes, i.e., a breeze blast mode and a non-breath blast mode. .. In the breeze mode, the baffle plate 13 is driven (for example, by a motor) and rotates so as to be parallel to the flow cross section of the air passage (that is, perpendicular to the wind flow) to block the air passage. The wind blows out through the breeze hole 133 to generate a breeze. Therefore, in the breeze blast mode, the air conditioning assembly can not only prevent the wind from being blown directly to the user, but can also improve the user's comfort by diverging the wind. In the non-breeze blowing mode (also referred to as the normal blowing mode), the baffle plate 13 is driven and rotated up and down so as to form a constant angle (maximum 90 °) with the flow cross section of the air passage, so that the wind is guided. It blows out directly from the upper and lower sides of the plate 13.

When the air conditioning outlet assembly 1 of the present invention is activated, when the air conditioning is activated, the flap 12 (usually in the vertical direction) generally rotates in a position orthogonal to the outlet panel 11. Then, depending on the needs of the user, the flap 12 can be rotated from a position perpendicular to the blowout panel 11 to the left or right, and can be rotated up to a maximum rotation angle of 80 °, whereby -80 ° to ~. Achieves 80 ° rotation. In one or more embodiments, each flap 12 can be configured to be individually controlled, for example each flap 12 is rotationally driven by an independent motor. Therefore, the plurality of flaps 12 can provide three different ventilation modes, that is, a uniform ventilation mode, a partition ventilation mode, and a manual ventilation mode. In the uniform ventilation mode, all the flaps 12 rotate at the same angle, so that it is guaranteed that the flaps are parallel to each other and deliver uniform air. In the partition blast mode, the purpose of the partition blast is achieved by rotating different angles according to the user's needs. In the manual ventilation mode, the flap can be manually rotated to adjust the angle according to the user's needs to satisfy the user's desired ventilation direction.

FIG. 12 is a perspective view of another embodiment of the air conditioning blowout assembly according to the present invention. FIG. 12 shows an example of implementing the partition ventilation mode. As shown in FIG. 12, in one or more embodiments, the air conditioning blowout assembly 1 includes a first baffle plate 13a and a second baffle plate 13b. The first baffle plate 13a and the second baffle plate 13b are arranged in parallel in the air passage of the blowout grid holder 14. Both the first baffle plate 13a and the second baffle plate 13b can be configured in the same manner as the above-mentioned baffle plate. Continuing with reference to FIG. 12, in one or more embodiments, the flap 12 has four flap compartments along the horizontal direction within the outlet of the blowout panel 11, i.e., first flap compartment 21, second flap. It is divided into a section 22, a third flap section 23, and a fourth flap section 12d. Alternatively, there may be less than four flaps or more than four flaps. In one or more embodiments, each flap compartment further includes four flaps, a first flap 12a, a second flap 12b, a third flap 12c, and a fourth flap 12d. Alternatively, the number of flaps in each flap compartment may be less than four or more than four. In partition ventilation mode, the user can control the ventilation direction of the various flap compartments, for example using a controller. In one or more embodiments, by controlling the rotation angle of each flap within each flap, four ventilation stages of low, medium low, low high, and high can be generated. Specifically, taking the first flap section 21 as an example, in the low ventilation stage, the first flap section 12a is adjusted to rotate 60 ° to the left, and the second flap section 12b is adjusted to rotate 20 ° to the left. Adjusted to rotate, the third flap compartment 12c may be adjusted to rotate 20 ° to the right and the fourth flap compartment 12d may be adjusted to rotate 60 ° to the right. When the first flap section 21 is set to the medium-low ventilation stage, the first flap section 12a is adjusted to rotate 30 ° to the left, and the second flap section 12b is adjusted to rotate 10 ° to the left. The third flap compartment 12c may be adjusted to rotate 10 ° to the right and the fourth flap compartment 12d may be adjusted to rotate 30 ° to the right. Further, when the first flap section 21 is set to the middle and high air blowing stage, the first flap section 12a is adjusted to rotate 30 ° to the right, and the second flap section 12b rotates 10 ° to the right. The third flap compartment 12c may be adjusted to rotate 10 ° to the left and the fourth flap compartment 12d may be adjusted to rotate 30 ° to the left. When the first flap portion 21 is set to the high ventilation stage, the first flap 12a rotates 60 ° to the right, the second flap 12b rotates 20 ° to the right, and the third flap 12c rotates 20 ° to the left. Then, the 4th flap 12d rotates 60 ° to the left. Alternatively, the outlet of each outlet flap can be set to less than four or more than four, and the flap angle of rotation of each outlet can also be redesigned as needed.

In one or more embodiments, 12 different ventilation modes can be formed by combining the ventilation mode provided by the baffle plate 13 and the ventilation mode provided by the flap 12. Specifically, in the ventilation mode provided by the baffle plate 13, six types of ventilation modes, that is, a uniform ventilation mode and four types including a low stage, a middle low stage, a middle high stage, and a high stage are provided by the flap 12. A partition ventilation mode and a manual ventilation mode can be created. In the non-breeze blowing mode provided by the baffle plate 13, the flap 12 can similarly generate the six types of blowing modes.

The air conditioner of the present invention including the air conditioner blowout assembly 1 can reach 80 ° at the maximum angle of the flap that can rotate from the position perpendicular to the blowout panel 11 to the left or right, so that the left and right sides of the air conditioner can be reached. Blind spots on both sides are eliminated or minimized, which greatly increases the area of ventilation on both the left and right sides of the air conditioner. In addition, the air conditioning can provide at most 12 different ventilation modes and can be customized to meet the needs of the user. For example, if the user has no special requirements for the air blown from the air conditioner, the uniform air blow mode can be selected, and if the user has different needs for the air blown from the air conditioner, the partition air blow mode can be selected. .. This solves the disadvantage that the air can only be blown in the same direction from the air conditioner at a certain point in time, and also blows air from the air conditioner in a multi-angle, concentrated (or distributed) manner to the wind blown from the air conditioner. You can select the manual ventilation mode if necessary. The partition ventilation mode can also provide four ventilation stages, allowing the user to choose different stages according to their needs to enhance comfort.

Although the technical solutions of the present invention have been described above in relation to the preferred embodiments shown in the drawings, the scope of protection of the present invention covers these specific embodiments so that those skilled in the art can easily understand them. It is clear that it is not limited. Without departing from the principles of the invention, one of ordinary skill in the art may combine the technical features of different embodiments, or may modify or replace the relevant technical features equally, after these changes or replacements. The technical solution of the present invention falls within the scope of protection of the present invention.

1, air-conditioning blowout assembly; 11, blowout panel; 12, flaps; 12a, first flaps; 12b, second flaps; 12c, third flaps; 12d, fourth flaps; 21, first flap compartments; 22, second. Flap section; 23, 3rd flap section; 24, 4th flap section; 121, flap body; 122, 1st flap rotation axis; 123, 2nd flap rotation axis; 13, baffle plate; 13a, 1st flap plate 13b, 2nd baffle plate; 131, baffle plate body; 132, front surface of baffle plate; 133, breeze hole; 133a, 1st breeze hole section; 133b, 2nd breeze hole section; 133c, 3rd breeze Hole section; 133d, 4th breeze hole section; 134, rear surface of baffle plate; 135a, 1st baffle plate rotating shaft; 135b, 2nd baffle plate rotating shaft; 135c, 3rd baffle plate rotating shaft; 135d , 4th baffle plate rotating shaft; 135e, 5th baffle plate rotating shaft; 14, blowout grid holder; 141, blowout grid holder body; 141a, outlet end; 141b, outlet; 141c, left wall; 141d, Front wall; 141e, suction port end; 141f, right wall; 141g, rear wall; 142a, first baffle plate shaft hole; 142b, second baffle plate shaft hole; 142c, third baffle plate shaft hole; 143 , Baffle plate holder; 143a, 1st baffle plate holder; 143b, 2nd baffle plate holder; 143c, 3rd baffle plate holder; 144, blowout panel locking port, 145, flap shaft hole.

Claims (10)

It ’s an air-conditioning outlet assembly.
An outlet grid holder including a suction port end, an air outlet end, and an air passage formed between the suction port end and the air outlet end.
With at least one baffle plate placed in the air passage, each capable of rotating along the horizontal axis.
An air conditioning outlet assembly that is located at the outlet end and includes at least one flap, each capable of rotating along a vertical axis. The air conditioning blowout assembly according to claim 1, wherein each of the flaps can be independently controlled and rotated. The air conditioning blowout assembly according to claim 2, wherein the plurality of flaps can generate a uniform blow mode, a partition blow mode, and a manual blow mode. The air conditioning blowout assembly according to claim 3, wherein the plurality of flaps are grouped into a plurality of flap compartments, and the partition ventilation mode is realized by different rotation angles of the flaps in each flap compartment. The air-conditioning blowing assembly according to claim 4, wherein each flap section can form a low-stage, medium-low stage, medium-high stage, and high-stage ventilation stage depending on the rotation angle of the flap. The air conditioning blowout assembly according to any one of claims 1 to 5, wherein the flaps can be painted in different colors. One of claims 1 to 5, wherein the baffle plate is provided with a plurality of breeze holes extending perpendicular to the surface of the baffle plate and penetrating the thickness of the baffle plate. The air conditioning outlet assembly described in the section. The air conditioning blowout assembly according to claim 7, wherein the baffle plate can generate a breeze blowing mode and a non-breathing blowing mode. The air conditioning outlet assembly further includes an outlet panel, the outlet panel is provided with a panel outlet, and the outlet panel is fixed to the outlet end of the outlet grid holder at the panel outlet and the outlet end. The air conditioning outlet assembly according to any one of claims 1 to 5, wherein the air conditioning outlet assembly can be aligned with the outlet. An air conditioner comprising the baffle plate according to any one of claims 1 to 9.

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