吊顶式空调内机系统 技术领域 本发明涉及空调领域, 特别地, 涉及一种吊顶式空调内机系统。 背景技术 随着人们生活水平的提高, 装修的要求也越来越高, 暗藏式空调也越来越受到人 们的欢迎, 局部吊顶空调作为暗藏式空调的一种, 比全吊顶式空调更能节省空间, 现 有市场的局部吊顶暗藏室内机一般都采用侧回侧送或下回侧送的气流循环方式, 机组 安装高度为 2.8米左右, 这样机组制热时, 热风侧送后, 跟进热膨胀原理, 热风漂浮 在空间室内上方, 热风难以到达人类活动区域。 房间的热舒适性差。 而且传统机组所 用的风口工程铝框风口或者导叶塑料风口, 这些风口不能闭合, 无法防止虫子、 灰尘 进入机组, 机组可靠性差。 发明内容 本发明目的在于提供一种吊顶式空调内机系统, 以解决传统机组送风方式房间的 热舒适性差的技术问题。 为实现上述目的,本发明提供了一种吊顶式空调内机系统,室内机设置在吊顶内, 系统还包括: 回风口, 设置在吊顶的侧面上; 出风口, 设置在吊顶的底面上; 回风口 处设置有可闭合的回风口装置, 出风口处设置有可闭合的出风口装置。 进一步地, 出风口装置包括出风装置和沿竖直方向可移动地嵌套在出风装置内的 导风部。 进一步地, 导风部包括侧壁, 并且导风部的底部形成有第一出风口。 进一步地, 导风部还包括第二出风口, 设置在侧壁上, 导风部缩回至出风装置内 时第二出风口关闭, 导风部伸出至出风装置外时第二出风口打开。 进一步地, 侧壁包括相对设置的两个第一侧壁和设置在两个第一侧壁之间的两个 第二侧壁, 两个第一侧壁中的至少一个第一侧壁上设置有第二出风口。 进一步地, 导风部上设置有相互独立的第一出风口和第二出风口。
进一步地, 第一出风口设置有导风叶片, 导风叶片为一片, 闭合时可以关闭第一 出风口。 进一步地, 第一出风口设置有多个导风叶片, 多个导风叶片闭合时可以关闭第一 出风口。 进一步地, 室内机设置有贯流风机, 包括蜗壳和风叶, 贯流风机的纵剖面内, 蜗 壳的蜗壳型线包括: 圆弧段, 设置于风机的进风口处; 螺旋线段, 与圆弧段平滑连接, 并朝向风机的出风口方向延伸, 螺旋线段与圆弧段相切于第一连接点8。 进一步地, 蜗壳型线还包括直线段, 设置于贯流风机的出风口处, 并与螺旋线段 相切于第二连接点 A。 进一步地, 室内机的内腔的回风口处设置有蒸发器, 蒸发器可拆卸地设置在室内 机内; 室内机的内腔的回风口配置为适于使蒸发器进出室内机的内腔。 进一步地, 室内机设置有离心风机, 室内机设置有与离心风机相匹配的 V形蒸发 器。 进一步地, 室内机与出风口的连接处设置有密封材料。 本发明具有以下有益效果: 将出风口的方向设置成朝向地面, 使热风能够送至房间内的最低处, 使房间的热 舒适性好, 机组尺寸更小, 节省了空间, 预留更多装修空间, 满足多样化需求。 除了上面所描述的目的、特征和优点之外, 本发明还有其它的目的、特征和优点。 下面将参照图, 对本发明作进一步详细的说明。 附图说明 构成本申请的一部分的附图用来提供对本发明的进一步理解, 本发明的示意性实 施例及其说明用于解释本发明, 并不构成对本发明的不当限定。 在附图中: 图 1是根据本发明的吊顶式空调内机系统的不工作时的示意图; 图 2是根据本发明的吊顶式空调内机系统的第一出风口出风示意图; 图 3 是根据本发明的吊顶式空调内机系统的第一出风口和第二出风口出风示意 图;
图 4是根据本发明的吊顶式空调内机系统的第二出风口出风示意图; 图 5是根据本发明的吊顶式空调内机系统的第一出风口和第二出风口的示意图; 图 6是根据本发明的吊顶式空调内机系统的单个导风叶片的示意图; 图 7是根据本发明的吊顶式空调内机系统的多个导风叶片的示意图; 图 8是根据本发明的吊顶式空调内机系统的出风气流示意图; 图 9是根据本发明的吊顶式空调内机系统的室内机的剖面结构示意图; 以及 图 10 是根据本发明的吊顶式空调内机系统的室内机的蜗壳型线主要控制特征的 示意图。 附图中的附图标记如下: 10、 室内机; 11、 风叶; 12、 蜗壳型线; 121、 圆弧段; 122、 螺旋线段; 123、 直线段; 20、 吊顶; 30、 回风口; 31、 回风口装置; 40、 出风 口; 41、 出风口装置; 411、 出风装置; 412、 导风部; 4120、 侧壁; 4121、 第一出风 口; 4122、 第二出风口; 42、 导风叶片; 50、 密封材料。 具体实施方式 以下结合附图对本发明的实施例进行详细说明, 但是本发明可以由权利要求限定 和覆盖的多种不同方式实施。 参见图 1至图 10, 根据本发明的吊顶式空调内机系统, 室内机 10设置在吊顶 20 内, 还包括回风口 30, 设置在吊顶的侧面上, 出风口 40, 设置在吊顶 20的底面上; 回风口 30处设置有可闭合的回风口装置 31, 出风口 40处设置有可闭合的出风口装置 41。 将出风口的方向设置成朝向地面, 使热风能够送至房间内的最低处, 使房间的热 舒适性好,减小了吊顶 20的宽度,节省了空间,预留更多装修空间,满足多样化需求。 参见图 1至图 5, 室内机 10的最主要特征在于下出风, 室内机 10的出风口 40与 吊顶 20的下面连接形成风道,连接方式可以是风道软接,或者设计制作一个专门连接 室内机 10出风口 40与风口的风管, 这种风管的设计主要依据室内机 10出风口 40及 风口的尺寸, 风管的一头连接在室内机 10的出风口 40上, 一头可以连接到天花上, 风口装入风管, 另外一种是风管连接到风口的近室内机 10 侧, 这两种情况下, 吊顶 20的尺寸会比较大, 为了使吊顶 20高度减小, 我们还发明了在室内机 10及风口之间 设置软海绵的方式来实现密封, 软海绵也可以使用其他软材料代替。出风口 40部件的
安装可以使用螺钉固定在天花上, 或采用卡子固定在天花上, 也可以采用螺钉与卡子 的配合固定在天花上, 或固定在室内机 10上, 当尺寸差别较大时, 可以在回风口 30 位置调节吊装室内机 10的丝杆来调节室内机 10的高低, 来达到所需要的尺寸, 而且 室内机 10与出风口 40之间的密封海绵也有比较微小的高度调节能力。 参见图 1至图 5, 室内机 10的回风口 30设置在室内机 10的侧面上, 与吊顶 20 的侧面开口配合形成回风口 30, 天花的回风口 30可以与室内机 10的回风口 30之间 设置风道连接, 这样就可以保证只从我们设置的回风口 30位置回风; 当局部吊顶 20 密封较好时, 回风可以不设置风道, 室内机 10运转时, 室内机 10的离心风机动作, 在回风口 30形成负压, 局部吊顶 20除了回风口 30之外, 其他部分都是密封的, 只有 回风口 30是非密闭的,这样通过压力差, 自然在室内机 10的回风口 30与天花的回风 口 30之间形成风道流场。 回风口 30部件的安装一般固定在天花上, 当天花与风口尺 寸非常精确时, 也可以固定在室内机 10上。 参见图 1至图 5, 回风口 30处设置有可闭合的回风口装置 31。 出风口 40处设置 有可闭合出风口装置 41。这样可以防止虫子及灰尘在室内机 10关闭时进入室内机 10, 该闭合回风口 30可以是单面板式, 单面板通过旋转打开或关闭,该面板的旋转通过连 杆及推杆的共同运动实现。 回风口装置 31和出风口装置 41的关闭与打开也可以通过 多导风叶片旋转来实现。 出风口 40也可以设计成单导风叶片, 室内机 10工作时, 叶 片伸出, 通过导叶的旋转来实现导风功能。 参见图 1至图 7, 出风口装置 41包括出风装置 411和沿竖直方向可移动地嵌套在 出风装置内的导风部 412。 导风部 412包括侧壁 4120, 并且导风部 412的底部形成有 第一出风口 4121。出风口装置 41上设置有第一出风口 4121和第二出风口 4122。第一 出风口 40设置有导风叶片 42。第一出风口 40设置有多个导风叶片 42。为了解决室内 机 10出风吹人不舒服的问题,出风口装置 41设置有升降式双出风口,第一出风口 4121 和第二出风口 4122, 两个出风口可以控制关闭与打开, 也可以处于部分关闭部分打开 的状态; 第一出风口 4121 的关闭与打开通过多导风叶片旋转实现; 第二出风口 4122 的关闭与打开通过升降来实现。伸出时打开, 缩回时关闭; 第二出风口 4122可以是单 方向的也可以是多方向的。 室内机 10的内腔的回风口处设置有蒸发器,蒸发器可拆卸地设置在室内机 10内; 室内机 10的内腔的回风口配置为适于使蒸发器进出室内机 10的内腔。 室内机包括壳 体、 蒸发器和固定组件。 壳体具有壳体内腔、 出风口、 回风口。 蒸发器设置于壳体内 腔中, 并位于回风口处。 固定组件将蒸发器可拆卸地固定于壳体内。 其中, 回风口配 置为适于使蒸发器进出壳体内腔, 固定组件配置为适于从回风口进行操作。 通过将回
风口配置为适于使蒸发器进出壳体内腔, 将固定组件配置为适于从回风口进行操作的 结构, 使工作人员可以通过回风口对固定组件进行拆卸, 从而能够将置于回风口处的 蒸发器取出, 以对空调器内部组件进行维护, 进一歩地, 还可以节省现有技术中的检 修口, 达到提高整体外观效果的目的。 参见图 1至图 4, 室内机可以采用贯流风机, 也可以是离心风机, 贯流风机设计 成吸风式, 离心风机可以设计成吹风式, 也可以设计成吸风式。 优选地, 室内机 10 使用贯流风机。 室内机设置有与贯流风机相匹配的 V形蒸发器。 室内机 10所需的吊 顶 20尺寸小, 吊顶 20尺寸小的原因包括室内机 10尺寸小及出风口 40与室内机 10 之间连接尺寸小。传统风机采用离心风机, 要达到室内机 10所需风量, 离心风机尺寸 比较大, 且离心式出风是间断性的, 为了使蒸发器上的换热风比较均匀, 风机出口与 蒸发器之间必须预留一定的出风扩散均匀区域, 而新设计室内机 10采用贯流风机 +V 字形蒸发器, 贯流风机达到相同的风量, 风机的尺寸比较小, 且贯流风机的风量是连 续的, 不需要风量扩散混合区域, 且贯流风机与蒸发器 V字型开口配合, 可以减小室 内机 10尺寸。 参见图 9和图 10, 室内机 10设置有贯流风机, 包括蜗壳和风叶 11, 贯流风机的 纵剖面内, 蜗壳的蜗壳型线 12包括: 圆弧段 121, 设置于风机的进风口处; 螺旋线段 122, 与圆弧段平滑连接, 并朝向风机的出风口方向延伸, 螺旋线段与圆弧段相切于第 一连接点 B。 蜗壳型线还包括直线段 123, 设置于贯流风机的出风口处, 并与螺旋线 段 122相切于第二连接点 A。 贯流风机包括蜗壳和风叶 11。 在风机的纵剖面内, 蜗壳 的蜗壳型线 12包括: 圆弧段 121、 螺旋线段 122和直线段 123。 其中, 圆弧段 121设 置于风机的进风口处。 螺旋线段 122与圆弧段 121平滑连接。 直线段 123设置于风机 的出风口处并与螺旋线段 122远离圆弧段 121的一端平滑连接。 通过将圆弧段 121、 螺旋线段 122和直线段 123在各个连接点处平滑连接, 可以 减小在连接处产生的突变结构的大小, 甚至避免产生突变结构, 从而能够防止气流流 经上述连接处时形成涡流, 进而能够达到使风机的风量与噪声的比值满足设计需求的 目的。 优选地, 螺旋线段 122与圆弧段 121相切于第一连接点 B。 直线段 123与螺旋线 段 122相切于第二连接点 A。 将上述三段线首尾连接, 以形成平滑的气流引导线, 这 样气流在流动中不容易产生紊流, 从而达到降低噪音的目的。 需要说明的是, 螺旋线段 122的作用是与风叶 11配合形成均匀出气容纳空间,直 线段 123的设计是因为过了螺旋线段 122, 风叶 11已不再起作用, 所以要设计一段直
线段 123来引导气流平稳的流出。 圆弧段 121的作用如下: 风机的螺旋线段 122及直 线段 123都属于出气段, 与出气段相对应有一个进气段, 进气段与出气段的相交点既 是距离风叶 11的最近点, 也是进出气的分界点。本发明实施例中的进气段为了能容纳 更多的气流进入, 将圆弧段 121设计成反向圆弧结构, 即圆弧段 121由第一连接点 B 朝向远离风叶 11的方向弯曲延伸。 当然, 为了使风机的适用范围更广, 上述圆弧段也 可以设计成其他一些平滑过渡的曲线。 参见图 1至图 4, 室内机与出风口 40的连接处设置有密封材料 50。 室内机 10与 风口的配合尺寸的减小是通过海绵来实现的,因为两个硬物之间连接很难保证不漏风, 我们新设计的室内机 10出风口 40面是平面, 可以方面的通过海绵软连接来实现风口 与风道的对接, 相比较传统的软接风道, 吊顶 20空间更小。 参见图 1, 当室内机 10不工作时, 风口可以密闭, 可以防止虫子及灰尘进入室内 机 10内部, 有效的提高室内机 10的可靠性。 从以上的描述中, 可以看出, 本发明上述的实施例实现了如下技术效果: 将出风口的方向设置成朝向地面, 使热风能够送至房间内的最低处, 使房间的热 舒适性好, 风口在机组关闭时闭合, 虫子、 灰尘无法进入机组, 机组可靠性高。 机组 尺寸更小, 节省了空间, 预留更多装修空间, 满足多样化需求。 以上所述仅为本发明的优选实施例而已, 并不用于限制本发明, 对于本领域的技 术人员来说, 本发明可以有各种更改和变化。 凡在本发明的精神和原则之内, 所作的 任何修改、 等同替换、 改进等, 均应包含在本发明的保护范围之内。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the field of air conditioning, and in particular to a ceiling type air conditioner internal system. BACKGROUND OF THE INVENTION With the improvement of people's living standards, the requirements for decoration are getting higher and higher, and hidden air conditioners are more and more popular among people. Partial ceiling air conditioners are one type of hidden air conditioners, which is more economical than full ceiling air conditioners. Space, the existing ceiling hidden indoor unit in the existing market generally adopts the air circulation mode of the side return side or the lower side, and the installation height of the unit is about 2.8 meters, so that when the unit is heating, the hot air side is sent, followed by thermal expansion. Principle, hot air floats above the space interior, and hot air is difficult to reach the human activity area. The thermal comfort of the room is poor. Moreover, the tuyere engineering aluminum frame tuyere or the vane plastic tuyere used in the conventional unit cannot be closed, and it is impossible to prevent insects and dust from entering the unit, and the unit reliability is poor. SUMMARY OF THE INVENTION An object of the present invention is to provide a ceiling type air conditioner internal system to solve the technical problem of poor thermal comfort of a conventional unit air supply mode room. In order to achieve the above object, the present invention provides a ceiling type air conditioner internal machine system, wherein the indoor unit is disposed in the ceiling, the system further comprises: an air return port disposed on a side surface of the ceiling; the air outlet is disposed on a bottom surface of the ceiling; A closable air return device is arranged at the tuyere, and a closable air outlet device is arranged at the air outlet. Further, the air outlet device includes an air outlet device and an air guiding portion movably nested in the air outlet device in a vertical direction. Further, the air guiding portion includes a side wall, and a bottom portion of the air guiding portion is formed with a first air outlet. Further, the air guiding portion further includes a second air outlet, which is disposed on the side wall, the second air outlet is closed when the air guiding portion is retracted into the air outlet device, and the second air outlet is extended when the air guiding portion is extended outside the air outlet device The tuyere is open. Further, the sidewall includes two opposite sidewalls disposed opposite to each other and two second sidewalls disposed between the two first sidewalls, and the at least one of the two first sidewalls is disposed on the first sidewall There is a second outlet. Further, the air guiding portion is provided with a first air outlet and a second air outlet that are independent of each other. Further, the first air outlet is provided with a wind guide vane, and the air guide vane is one piece, and the first air outlet can be closed when closed. Further, the first air outlet is provided with a plurality of air guiding blades, and when the plurality of air guiding blades are closed, the first air outlet can be closed. Further, the indoor unit is provided with a cross-flow fan, including a volute and a fan blade, and a volute profile of the volute casing includes: a circular arc segment disposed at an air inlet of the fan; a spiral segment, and The arc segment is smoothly connected and extends toward the air outlet of the fan, and the spiral segment is tangent to the arc segment at the first connection point 8. Further, the volute type line further includes a straight line segment disposed at the air outlet of the cross flow fan and tangential to the spiral line segment at the second connection point A. Further, an evaporator is disposed at the air return opening of the inner chamber of the indoor unit, and the evaporator is detachably disposed in the indoor unit; the air return port of the inner chamber of the indoor unit is configured to be adapted to allow the evaporator to enter and exit the inner chamber of the indoor unit. Further, the indoor unit is provided with a centrifugal fan, and the indoor unit is provided with a V-shaped evaporator matched with the centrifugal fan. Further, a sealing material is disposed at a joint between the indoor unit and the air outlet. The invention has the following beneficial effects: The direction of the air outlet is set to face the ground, so that the hot air can be sent to the lowest place in the room, so that the room has good thermal comfort, the unit size is smaller, space is saved, and more decoration is reserved. Space, to meet diverse needs. In addition to the objects, features and advantages described above, the present invention has other objects, features and advantages. The invention will now be described in further detail with reference to the drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a ceiling-type air conditioner internal system according to the present invention when it is not in operation; FIG. 2 is a schematic view of a first air outlet outlet of a ceiling-type air conditioner internal system according to the present invention; A schematic diagram of the first air outlet and the second air outlet of the ceiling type air conditioner internal system according to the present invention; 4 is a schematic view of the second air outlet of the ceiling type air conditioner system according to the present invention; FIG. 5 is a schematic view of the first air outlet and the second air outlet of the ceiling type air conditioner internal system according to the present invention; Figure 7 is a schematic view of a plurality of air guiding vanes of a ceiling type air conditioner internal system according to the present invention; Fig. 7 is a schematic view of a plurality of air guiding vanes according to the present invention; FIG. 9 is a cross-sectional structural view of an indoor unit of a ceiling type air conditioner internal unit system according to the present invention; and FIG. 10 is a worm of an indoor unit of the ceiling type air conditioner internal unit system according to the present invention; Schematic diagram of the main control features of the shell line. The reference numerals in the drawings are as follows: 10, indoor unit; 11, wind blade; 12, volute type line; 121, arc segment; 122, spiral line segment; 123, straight line segment; 20, ceiling; 30, return air outlet 31, air return device; 40, air outlet; 41, air outlet device; 411, air outlet device; 412, air guiding portion; 4120, side wall; 4121, first air outlet; 4122, second air outlet; , guide vane; 50, sealing material. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The embodiments of the present invention are described in detail below with reference to the accompanying drawings. Referring to FIG. 1 to FIG. 10, according to the ceiling type air conditioner internal system of the present invention, the indoor unit 10 is disposed in the ceiling 20, and further includes a return air port 30 disposed on the side of the ceiling, and the air outlet 40 is disposed on the bottom surface of the ceiling 20. The return air outlet 30 is provided with a closable air return device 31, and the air outlet 40 is provided with a closable air outlet device 41. The direction of the air outlet is set to face the ground, so that the hot air can be sent to the lowest place in the room, so that the thermal comfort of the room is good, the width of the ceiling 20 is reduced, space is saved, more decoration space is reserved, and various environments are reserved. Demand. Referring to FIG. 1 to FIG. 5, the most important feature of the indoor unit 10 is the lower air outlet. The air outlet 40 of the indoor unit 10 is connected with the lower surface of the ceiling 20 to form a air duct. The connection manner may be a soft joint of the air duct, or a special design is designed. The air duct of the air outlet 40 and the air outlet of the indoor unit 10 is connected. The design of the air duct is mainly based on the size of the air outlet 40 and the air outlet of the indoor unit 10. One end of the air duct is connected to the air outlet 40 of the indoor unit 10, and one end can be connected. On the ceiling, the tuyere is installed in the air duct, and the other is the side of the near indoor unit 10 where the duct is connected to the tuyere. In both cases, the size of the ceiling 20 is relatively large. In order to reduce the height of the ceiling 20, we also In the invention, a soft sponge is provided between the indoor unit 10 and the tuyere to achieve sealing, and the soft sponge may be replaced by other soft materials. Air outlet 40 parts The installation can be fixed on the ceiling with screws, or fixed on the ceiling with a clip. It can also be fixed on the ceiling with the cooperation of screws and clips, or fixed on the indoor unit 10. When the size difference is large, it can be at the return air inlet 30. The position adjustment adjusts the screw of the indoor unit 10 to adjust the height of the indoor unit 10 to achieve the required size, and the sealing sponge between the indoor unit 10 and the air outlet 40 also has a relatively small height adjustment capability. Referring to FIG. 1 to FIG. 5, the air return port 30 of the indoor unit 10 is disposed on the side of the indoor unit 10, and cooperates with the side opening of the ceiling 20 to form a return air port 30, and the return air inlet 30 of the ceiling can be combined with the air return port 30 of the indoor unit 10. The air duct connection is set between the two, so that it can ensure that only the air return port 30 is set back from the air. When the partial ceiling 20 is well sealed, the return air can be set without the air duct. When the indoor unit 10 is running, the indoor unit 10 is centrifuged. The fan acts to form a negative pressure at the return air port 30. The partial ceiling 20 is sealed except for the return air port 30, and only the air return port 30 is non-closed, so that the air return port 30 of the indoor unit 10 is naturally passed through the pressure difference. A wind tunnel flow field is formed between the return air outlet 30 of the ceiling. The installation of the components of the air return port 30 is generally fixed on the ceiling, and when the size of the day flower and the tuyere is very accurate, it can also be fixed on the indoor unit 10. Referring to Figures 1 to 5, a closable return air port means 31 is provided at the return air port 30. A closable air outlet device 41 is provided at the air outlet 40. In this way, insects and dust can be prevented from entering the indoor unit 10 when the indoor unit 10 is closed. The closed return air outlet 30 can be a single-panel type, and the single panel is opened or closed by rotation, and the rotation of the panel is realized by the joint movement of the connecting rod and the push rod. . The closing and opening of the air return port device 31 and the air outlet device 41 can also be achieved by the rotation of the multi-duct air vanes. The air outlet 40 can also be designed as a single air guiding vane. When the indoor unit 10 is in operation, the vane is extended, and the air guiding function is realized by the rotation of the vane. Referring to Figures 1 through 7, the air outlet means 41 includes an air outlet means 411 and an air guiding portion 412 which is movably nested in the air outlet means in a vertical direction. The air guiding portion 412 includes a side wall 4120, and a bottom portion of the air guiding portion 412 is formed with a first air outlet 4121. The air outlet device 41 is provided with a first air outlet 4121 and a second air outlet 4122. The first air outlet 40 is provided with a wind guide vane 42. The first air outlet 40 is provided with a plurality of air guiding blades 42. In order to solve the problem that the indoor unit 10 is uncomfortable, the air outlet device 41 is provided with a lifting double air outlet, a first air outlet 4121 and a second air outlet 4122, and the two air outlets can be controlled to be closed and opened, or The state in which the partially closed portion is opened; the closing and opening of the first air outlet 4121 is realized by the rotation of the plurality of air guide blades; the closing and opening of the second air outlet 4122 is achieved by lifting. Opened when extended, closed when retracted; the second air outlet 4122 may be unidirectional or multi-directional. An evaporator is disposed at the air return opening of the inner chamber of the indoor unit 10, and the evaporator is detachably disposed in the indoor unit 10; the air return port of the inner chamber of the indoor unit 10 is configured to be adapted to allow the evaporator to enter and exit the inner chamber of the indoor unit 10. . The indoor unit includes a housing, an evaporator, and a stationary assembly. The housing has a housing inner cavity, an air outlet, and a return air outlet. The evaporator is disposed in the inner cavity of the housing and is located at the return air opening. The stationary assembly removably secures the evaporator within the housing. Wherein, the return air port is configured to move the evaporator into and out of the housing cavity, and the fixing component is configured to be adapted to operate from the air return port. By going back The tuyere is configured to be adapted to allow the evaporator to enter and exit the housing cavity, and the fixing assembly is configured to be adapted to operate from the return air outlet, so that the worker can disassemble the fixing assembly through the return air outlet, thereby being able to be placed at the return air outlet. The evaporator is taken out to maintain the internal components of the air conditioner, and further, the maintenance port in the prior art can be saved, and the overall appearance effect can be improved. Referring to Fig. 1 to Fig. 4, the indoor unit can adopt a cross flow fan or a centrifugal fan, and the cross flow fan is designed to be suction type, and the centrifugal fan can be designed as a blower type or a suction type. Preferably, the indoor unit 10 uses a cross flow fan. The indoor unit is provided with a V-shaped evaporator matched to the cross flow fan. The size of the ceiling 20 required for the indoor unit 10 is small, and the reason why the size of the ceiling 20 is small is that the size of the indoor unit 10 is small and the connection size between the air outlet 40 and the indoor unit 10 is small. The conventional fan adopts a centrifugal fan. To achieve the required air volume of the indoor unit 10, the size of the centrifugal fan is relatively large, and the centrifugal air outlet is intermittent. In order to make the heat exchange air on the evaporator relatively uniform, between the fan outlet and the evaporator A certain uniform distribution area of the airflow must be reserved, and the newly designed indoor unit 10 adopts a cross-flow fan + V-shaped evaporator, the cross-flow fan reaches the same air volume, the size of the fan is relatively small, and the air volume of the cross-flow fan is continuous. The air flow diffusion mixing zone is not required, and the cross flow fan cooperates with the V-shaped opening of the evaporator to reduce the size of the indoor unit 10. Referring to Figures 9 and 10, the indoor unit 10 is provided with a cross-flow fan, including a volute and a vane 11, in a longitudinal section of the cross-flow fan, the volute profile 12 of the volute includes: a circular arc segment 121, which is disposed on the fan At the air inlet; the spiral segment 122 is smoothly connected with the arc segment and extends toward the air outlet of the fan, and the spiral segment is tangent to the arc segment at the first connection point B. The volute profile further includes a straight section 123 disposed at the air outlet of the cross flow fan and tangential to the spiral section 122 to the second connection point A. The cross flow fan includes a volute and a vane 11. In the longitudinal section of the fan, the volute profile 12 of the volute includes: a circular arc segment 121, a helical segment 122 and a straight segment 123. Wherein, the arc segment 121 is disposed at the air inlet of the fan. The spiral segment 122 is smoothly connected to the arc segment 121. The straight line segment 123 is disposed at the air outlet of the fan and is smoothly connected to an end of the spiral segment 122 away from the arc segment 121. By smoothly connecting the arc segment 121, the spiral segment 122 and the straight segment 123 at the respective connection points, the size of the abrupt structure generated at the junction can be reduced, and even a catastrophic structure can be avoided, thereby preventing the airflow from flowing through the above junction. When the eddy current is formed, the ratio of the air volume of the fan to the noise can be achieved to meet the design requirements. Preferably, the spiral segment 122 is tangent to the arc segment 121 to the first connection point B. The straight line segment 123 is tangent to the spiral segment 122 to the second connection point A. The above three segments are connected end to end to form a smooth airflow guiding line, so that the airflow is less likely to generate turbulence during the flow, thereby achieving the purpose of reducing noise. It should be noted that the spiral segment 122 functions to cooperate with the blade 11 to form a uniform air accommodating space. The straight segment 123 is designed because the spiral segment 122 is passed, and the blade 11 is no longer functioning, so a straight section is designed. Line segment 123 guides the smooth flow of airflow. The function of the circular arc segment 121 is as follows: The spiral segment 122 and the straight segment 123 of the fan belong to the outlet section, and have an intake section corresponding to the outlet section, and the intersection point of the inlet section and the outlet section is the closest point to the blade 11 It is also the dividing point of the gas. In order to accommodate more airflow in the air intake section in the embodiment of the present invention, the arc segment 121 is designed to have a reverse arc structure, that is, the arc segment 121 is bent from the first connection point B toward the direction away from the blade 11. extend. Of course, in order to make the fan more applicable, the above arc segment can also be designed as other smooth transition curves. Referring to Figs. 1 to 4, a sealing material 50 is provided at the junction of the indoor unit and the air outlet 40. The reduction of the size of the indoor unit 10 and the tuyere is achieved by the sponge, because it is difficult to ensure that there is no air leakage between the two hard objects. Our newly designed indoor unit 10 air outlet 40 is flat, and can be passed through. The soft connection of the sponge is used to realize the docking of the tuyere and the air duct. Compared with the traditional soft air duct, the ceiling 20 has a smaller space. Referring to Fig. 1, when the indoor unit 10 is not in operation, the tuyere can be sealed to prevent insects and dust from entering the interior of the indoor unit 10, thereby effectively improving the reliability of the indoor unit 10. From the above description, it can be seen that the above-mentioned embodiments of the present invention achieve the following technical effects: the direction of the air outlet is set to face the ground, so that hot air can be sent to the lowest point in the room, so that the thermal comfort of the room is good. The tuyere is closed when the unit is closed, and the insects and dust cannot enter the unit, and the unit has high reliability. The unit is smaller in size, saves space, and reserves more room for decoration to meet diverse needs. The above is only the preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes can be made to the present invention. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and scope of the present invention are intended to be included within the scope of the present invention.