Hair conditioning assembly and hair dryer

By designing the conditioning nozzle, conditioning chamber, and air guide in the conditioning component, the hair care oil is made to evaporate in the airflow of the hair dryer and blown onto the hair, solving the problem of low utilization rate of hair care oil and improving the hair conditioning effect and user experience.

CN224330543UActive Publication Date: 2026-06-09SHENZHEN SHUYE INNOVATION TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN SHUYE INNOVATION TECH CO LTD
Filing Date
2025-04-03
Publication Date
2026-06-09

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  • Figure CN224330543U_ABST
    Figure CN224330543U_ABST
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Abstract

This utility model relates to the field of household appliance technology, providing a hair conditioning component and a hair dryer. The hair conditioning component includes a conditioning nozzle, a conditioning chamber, and an air guide. The conditioning nozzle is connected to the hair dryer housing, and an air duct is formed on the conditioning nozzle, with a receiving cavity inside. The conditioning chamber is installed in the receiving cavity, and a conditioning material chamber is formed inside the conditioning chamber, with a flow port communicating with the conditioning material chamber. The air guide is connected to the conditioning nozzle and / or the conditioning chamber, and an air inlet and an air outlet are respectively provided on the air guide. In this embodiment of the utility model, the air outlet is arranged adjacent to the air duct, and the air outlet faces the air outlet path of the air duct. In this way, the air entering the conditioning material chamber causes the hair conditioning oil to evaporate, and the evaporated oil molecules blown out from the air outlet will collect again on the air blowing path of the air duct and then blown onto the user's hair, thereby improving the utilization rate of the hair conditioning oil and enhancing the experience of using a hair dryer for hair conditioning and protection.
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Description

Technical Field

[0001] This utility model belongs to the field of household appliance technology, and in particular relates to a hair conditioning component and a hair dryer. Background Technology

[0002] Hair dryers are a common household item used to dry hair after washing it. Hair dryers typically produce hot air, which, due to its concentrated flow towards the hair, can be quite hot and easily damage the scalp and hair. To improve the effectiveness of hair dryers, some manufacturers use them in conjunction with hair oil. This allows the hair oil to evaporate with the airflow and reach the hair, providing better protection.

[0003] Among related products, the volatile substances produced by hair oil have a low utilization rate on the hair, resulting in an insignificant hair care effect and affecting the user experience. Utility Model Content

[0004] In view of this, the present invention provides a hair conditioning component and a hair dryer to solve the problem of low utilization rate of hair care oil affecting the user experience.

[0005] To solve the above problems, the technical solution of this utility model is implemented as follows:

[0006] A hair conditioning component includes: a conditioning nozzle connected to the housing of a hair dryer, the conditioning nozzle having an air duct communicating with the air outlet of the hair dryer, and a receiving cavity formed inside the conditioning nozzle; a conditioning chamber connected to the conditioning nozzle and installed inside the receiving cavity, the conditioning chamber having a conditioning material cavity for containing hair care essential oil, and a flow port on the conditioning chamber communicating with the conditioning material cavity; and an air guide located in the receiving cavity and connected to the conditioning nozzle and / or the conditioning chamber, the air guide having an air inlet and an air outlet respectively; at least a portion of the air flowing out of the air duct sequentially enters the conditioning material cavity through the air inlet and the flow port, and the air in the conditioning material cavity sequentially flows out through the flow port and the air outlet; wherein the air outlet is arranged adjacent to the air duct, and the air outlet faces the air outlet path of the air duct.

[0007] In some embodiments, the air guide includes: a body, configured as annular, with the air inlet located on the body; the body being connected to the humidifying nozzle and / or the humidifying chamber; and a top cover, disposed above the body, connected to the body, and having a gap between the top cover and the body forming the air outlet.

[0008] In some embodiments, multiple air inlets are provided, and each air inlet is distributed at intervals along the contour shape of the body.

[0009] In some embodiments, the air guide further includes a support ring protruding in a direction away from the humidification chamber, the support ring being connected to the body via a support rod, and the top cover and the support ring being connected by a snap-fit ​​structure.

[0010] In some embodiments, at least the outline shape of the top cover is the same as the outline shape of the air duct.

[0011] In some embodiments, the humidifying nozzle is used to form an air guide slope on the inner wall of the air duct, the air guide slope being inclined toward the air guide member to guide the airflow in the air duct toward the air inlet.

[0012] In some embodiments, the angle of inclination of the air guide slope relative to the central axis of the receiving cavity is 3° to 15°.

[0013] In some embodiments, the hydration nozzle has a through hole that communicates with the receiving cavity so as to push the hydration chamber apart from the hydration nozzle.

[0014] In some embodiments, the humidification nozzle is provided with a first magnetic element, and the humidification chamber and the air guide are respectively provided with a second magnetic element or a ferromagnetic metal; wherein the second magnetic element and the ferromagnetic metal element are attracted to the first magnetic element.

[0015] In some embodiments, the humidifying nozzle includes a frustum portion, and at least a portion of the receiving cavity is formed within the frustum portion; wherein the through hole is formed at one end of the frustum portion facing the housing.

[0016] In some embodiments, the conditioning chamber includes: a chamber body, at least partially installed within the accommodating container, the material protection chamber being formed within the chamber body, and an opening communicating with the material protection chamber at the end of the chamber body away from the blower; a chamber cover, covering the end of the chamber body having the opening, and a flow port being formed on the chamber cover; wherein air flowing out from the air duct enters the material protection chamber through the flow port, and air in the material protection chamber flows out through the flow port.

[0017] This utility model embodiment also provides a hair dryer, including a housing and the hair conditioning component described in any of the above embodiments, wherein the conditioning nozzle is connected to the air outlet end of the housing.

[0018] This utility model provides a hair conditioning component and a hair dryer. The hair conditioning component includes a conditioning nozzle, a conditioning chamber, and an air guide. The conditioning nozzle is connected to the hair dryer housing and has an air duct communicating with the hair dryer's air outlet. An accommodating cavity is formed inside the conditioning nozzle. The conditioning chamber is installed within the accommodating cavity and has a conditioning material cavity for holding hair care oil, with a flow port communicating with the conditioning material cavity. The air guide is connected to the conditioning nozzle and / or the conditioning chamber and has an air inlet and an air outlet. At least a portion of the air flowing out of the air duct enters the conditioning material cavity sequentially through the air inlet and the flow port, while the air in the conditioning material cavity flows out sequentially through the flow port and the air outlet. This utility model embodiment arranges the air outlet adjacent to the air duct, with the air outlet facing the air outlet path of the air duct. In this way, the air entering the conditioning chamber causes the hair oil to evaporate, and the evaporated oil molecules are blown out from the air outlet, where they will gather again on the airflow path and be blown onto the user's hair. This improves the utilization rate of the hair oil and enhances the experience of using a hair dryer to nourish and protect the hair. Attached Figure Description

[0019] Figure 1 This is a three-dimensional structural schematic diagram of the hair conditioning component provided in this embodiment of the utility model;

[0020] Figure 2 This is an exploded view of the hair conditioning component provided in an embodiment of the present invention;

[0021] Figure 3 This is a three-dimensional structural schematic diagram of the air guide provided in this embodiment of the utility model;

[0022] Figure 4 This is a top view of the hair conditioning component provided in this embodiment of the utility model;

[0023] Figure 5 yes Figure 4 Schematic diagram of the cross section at point AA;

[0024] Figure 6 This is a top view of the nutrient chamber provided in this embodiment of the utility model;

[0025] Figure 7 yes Figure 6 A cross-sectional view of section BB.

[0026] Explanation of reference numerals in the attached figures:

[0027] 1. Nourishing component; 11. Nourishing nozzle; 111. Air duct; 112. Receiving cavity; 114. Through hole; 115. Frustum; 116. Air guide slope; 119. Fixing component; 12. Nourishing chamber; 121. Material protection chamber; 122. Flow port; 123. Mounting slope; 124. Chamber body; 1241. Leak-proof groove; 1242. Liquid suction component; 125. Chamber cover; 1250. Flange; 126. Buckle; 127. Protrusion; 128. Material storage component; 13. Air guide component; 131. Air inlet; 132. Air outlet; 133. Body; 134. Top cover; 135. Support ring; 136. Support rod; 14. First magnetic component; 15. Second magnetic component; 16. Ferromagnetic metal component; 17. Sealing ring. Detailed Implementation

[0028] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present utility model and are not intended to limit the present utility model.

[0029] The specific technical features described in the specific embodiments can be combined in any suitable manner without contradiction. For example, different combinations of specific technical features can form different embodiments and technical solutions. To avoid unnecessary repetition, the various possible combinations of the specific technical features in this utility model will not be described separately.

[0030] In the following description, the terms "first," "second," etc., are used merely to distinguish different objects and do not indicate that the objects have the sameness or relationship. It should be understood that the directional descriptions "above," "below," "outside," and "inside" refer to the orientation under normal use conditions, while "left" and "right" refer to the left and right directions shown in the corresponding diagrams, which may or may not be the left and right directions under normal use conditions.

[0031] It should be noted that the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Unless otherwise specified, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes that element. "A plurality of" means two or more.

[0032] like Figure 1As shown in the illustration, this embodiment of the present invention provides a hair conditioning component 1, which stores hair conditioning oil inside. This hair conditioning oil, when applied to the hair, forms an oil film that protects the hair from high-temperature damage and improves its smoothness. Specifically, the hair conditioning component 1 is typically connected to the air outlet of a hair dryer, allowing the hair conditioning oil to evaporate with the airflow generated by the hair dryer. The evaporated oil molecules are then carried by the airflow to the hair, thus adhering to the hair and achieving the purpose of conditioning and protecting it.

[0033] The term "moisturizing" in the above refers to the deep repair and nourishing effect of hair oil on hair. Applying hair oil to hair can improve the problem of hair damage and frizz that often occurs during high-temperature blow-drying.

[0034] like Figure 1 and Figure 2 As shown, the hair conditioning component 1 provided in this embodiment of the present invention includes a conditioning nozzle 11, a conditioning chamber 12, and an air guide 13. The conditioning nozzle 11 is connected to the housing of the hair dryer. An air duct 111 communicating with the air outlet of the hair dryer is formed on the conditioning nozzle 11, and a receiving cavity 112 is formed inside the conditioning nozzle 11. The air duct 111 and the receiving cavity 112 are not directly connected. The conditioning chamber 12 is connected to the conditioning nozzle 11 and installed in the receiving cavity 112. A conditioning material cavity 121 for containing hair care oil is formed inside the conditioning chamber 12 (see reference). Figure 5 ), and a flow port 122 communicating with the material protection chamber 121 is provided on the nourishing chamber 12 (refer to Figure 5 This allows outside air and air inside the protective material chamber 121 to flow and exchange through the flow port 122.

[0035] Specifically, the air guide 13 is also disposed in the receiving cavity 112 and connected to the conditioning nozzle 11 and / or conditioning chamber 12, thereby fixing the installation position. The air guide 13 is respectively provided with an air inlet 131 and an air outlet 132. At least a portion of the air flowing out of the air duct 111 enters the conditioning chamber 121 sequentially through the air inlet 131 and the flow port 122, while the air in the conditioning chamber 121 flows out sequentially through the flow port 122 and the air outlet 132. In this way, the outside air is exchanged with the air in the conditioning chamber 121, and during the flow exchange, the hair care essential oil evaporates into essential oil molecules, which are then discharged from the air outlet 132 along with the airflow. In this embodiment of the invention, the air outlet 132 is arranged adjacent to the air duct 111, and the air outlet 132 faces the air outlet path of the air duct 111. In this way, the air guide 13 distributes and guides the airflow direction within the air duct 111, causing at least a portion of the air flowing out of the air duct 111 to sequentially enter the conditioning chamber 121 through the air inlet 131 and the flow outlet 122, while the air within the conditioning chamber 121 flows out sequentially through the flow outlet 122 and the air outlet 132. Furthermore, the air outlet 132 faces the air outlet path of the air duct 111, causing the air flowing out of the conditioning chamber 121 to converge again onto the air outlet path of the air duct 111, and be blown onto the user's hair along with other airflow that did not enter the conditioning chamber 121. Thus, the air carrying essential oil molecules can essentially be utilized on the user's hair, effectively preventing the waste of evaporated essential oil molecules and improving the utilization rate of essential oil molecules, achieving the dual purpose of drying and conditioning the hair.

[0036] This utility model provides a hair conditioning component 1, including a conditioning nozzle 11, a conditioning chamber 12, and an air guide 13. The conditioning nozzle 11 is connected to the housing of a hair dryer. An air duct 111 communicating with the air outlet of the hair dryer and a receiving cavity 112 are formed inside the conditioning nozzle 11. The conditioning chamber 12 is installed within the receiving cavity 112, and a conditioning material cavity 121 for containing hair conditioning oil is formed inside the conditioning chamber 12. A flow port 122 communicating with the conditioning material cavity 121 is also provided on the conditioning nozzle 11. The air guide 13 is connected to the conditioning nozzle 11 and / or the conditioning chamber 12, and is provided with an air inlet 131 and an air outlet 132. The air outlet 132 is arranged adjacent to the air duct 111, with the air outlet 132 facing the air duct 111. In this way, when the air carrying essential oil molecules in the conditioning chamber 121 flows out of the air outlet 132, it can be gathered again on the blowing path of the air duct 111 and blown onto the user's hair together, thereby improving the utilization rate of the hair conditioning essential oil, better avoiding the waste of essential oil molecules, and providing good moisturizing and protection for the hair, thus improving the user's experience.

[0037] In some embodiments, such as Figure 3As shown, the air guide 13 includes a body 133 and a top cover 134. The body 133 is annular, with an air inlet 131 formed on it. The body 133 is connected to the moisturizing nozzle 11 and / or the moisturizing chamber 12. The top cover 134 is positioned above the body 133, connected to it, and has a gap forming an air outlet 132. Specifically, the body 133 is configured to match the contour shape of the moisturizing chamber 12 for installation connection. The body 133 and the top cover 134 are not completely fitted together, but have a gap forming the air outlet 132. This allows essential oil molecules volatilized in the protective chamber 121 to flow directly out from the air outlet 132. The connection between the main body 133 and the top cover 134 can be achieved by forming a ring-shaped support structure on the main body 133 for the top cover 134 to be snapped on or glued, or by using a support rod for connection and fixation. Of course, the main body 133 and the top cover 134 can also be formed by integral molding, offering various configuration options and good flexibility.

[0038] In some embodiments, such as Figure 3 As shown, multiple air inlets 131 are provided, and each air inlet 131 is distributed at intervals along the outline of the body 133. In this way, the arrangement of each air inlet 131 makes the body 133 form a grid. The grid air intake method can effectively reduce the generation of air intake noise and improve the comfort of use. Moreover, the surrounding air inlets 131 can achieve air intake in all circumferential positions, thereby increasing the air volume entering the hair care chamber 121 and thus improving the evaporation efficiency of the hair care oil.

[0039] Specifically, the top cover 134 is spaced apart from the body 133, thus forming a gap between them. This gap is located above each air inlet 131, becoming the air outlet 132 for the airflow exiting from the protective material cavity 121. In this configuration, the air outlets 132 are continuously distributed along the contour of the body 133. That is, the air outlets 132 are arranged circumferentially around the body 133, matching the contour of the air duct 111, thereby enabling the air guide 13 to deliver air circumferentially along its contour, resulting in good airflow uniformity. Furthermore, the contour edge of the top cover 134 can be designed as a raised edge, curving away from the body 133, thereby increasing the area of ​​the air outlet 132. This not only increases the airflow volume but also improves the ease of handling the air guide 13 by grasping the raised edge.

[0040] The hair conditioning component 1 provided in this embodiment of the present invention has a dual air outlet structure with air outlet through air duct 111 and air outlet 132. The air flowing out from air outlet 132 is directly gathered into the air outlet path of air duct 111. The air flowing out from the two different positions converges and blows onto the hair together, thereby improving the utilization rate of the volatile hair conditioning oil.

[0041] In some embodiments, such as Figure 2 and Figure 3 As shown, the air guide 13 also includes a support ring 135 protruding away from the humidification chamber 12. The support ring 135 is connected to the body 133 via a support rod 136, and the top cover 134 and the support ring 136 are connected by a snap-fit ​​structure. Specifically, the body 133, the support ring 135, and the support rod 136 can be integrally formed, thereby improving the convenience of manufacturing. As one implementation scheme, a snap-fit ​​structure can be formed by providing a snap hole on the support ring 135 and a snap hook on the top cover 134. In this way, the snap hook and the snap-fit ​​can be connected to fix the top cover 134 to the support ring 135, which is convenient for assembly. Of course, the installation and fixation between the top cover 134 and the support ring 135 can also be achieved by screw-type fasteners or adhesive, etc., with various connection methods.

[0042] like Figure 3 As shown, the support rod 136 is disposed between the support ring 135 and the body 133, and at least two are evenly disposed thereon, so as to stably support the support ring 135. The overall structure of the air guide 13 formed has good stability and sufficient structural strength to ensure the reliability and service life of use.

[0043] In some embodiments, among the outline shapes of the body 133 and the top cover 134, at least the outline shape of the top cover 134 is the same as the outline shape of the air duct 111. Specifically, since the outline edge of the top cover 134 affects the path of the air outlet 132, at least the outline shape of the top cover 134 is the same as the outline shape of the air duct 111, so that the outline shape of the air outlet 132 and the outline shape of the air duct 111 remain substantially the same. In this way, the air blown out of the air outlet 132 will flow onto the air outlet path of the air duct 111, realizing the convergence of air from different directions and improving the effect of air outlet convergence.

[0044] In some embodiments, such as Figure 4 and Figure 5As shown, the conditioning nozzle 11 has a guide slope 116 on the inner wall of the air duct 111. The guide slope 116 is inclined towards the guide member 13 to guide the airflow from the air duct 111 into the conditioning chamber 121. In this way, the guide slope 116 can concentrate the airflow from the air duct 111. Through the guidance of the guide slope 116, the airflow from the air duct 111 into the conditioning chamber 121 can be increased. At the same time, the temperature around the conditioning chamber 121 can be increased, thereby increasing the evaporation efficiency of the hair care oil and improving the amount of evaporating hair care oil molecules blown onto the hair, thus achieving a better conditioning effect on the hair.

[0045] In some embodiments, such as Figure 5 As shown, the guide slope 116 is positioned at the air outlet end of the air duct 111, and the inclination angle α of the guide slope 116 relative to the central axis of the receiving cavity 112 is set to 3° to 15°. This placement near the air outlet end allows for proper distribution of the air within the air duct 111, ensuring that a portion of the air enters the conditioning chamber 121 under the guidance of the guide slope 116, thus guaranteeing sufficient airflow into the conditioning chamber 121 and improving the hair care efficiency of the hair oil. Simultaneously, it ensures that the remaining air within the air duct 111 can be directly blown out from the air outlet. Furthermore, the directly blown air creates a negative pressure environment at the air outlet 132, attracting the airflow from the conditioning chamber 121 and ultimately converging it to be blown onto the user's hair, ensuring both hair drying and conditioning. Specifically, the tilt angle α of the guide slope 116 can be any value within the range of 3° to 15°, such as 3°, 7°, 10°, or 13°. Any angle within this range can effectively distribute the airflow within the duct 111. In this embodiment of the invention, the tilt angle α of the guide slope 116 can be set to 8°, thereby not only achieving effective distribution and guidance of the airflow within the duct 111, but also achieving noise reduction, resulting in lower noise levels when the airflow passes through the duct 111, thus improving user comfort.

[0046] In some embodiments, such as Figure 2As shown, the hair conditioning nozzle 11 has a through hole 114 that communicates with the receiving cavity 112, allowing the hair conditioning chamber 12 to be pushed apart from the hair conditioning nozzle 11. Specifically, after the hair conditioning chamber 12 is installed into the receiving cavity 112 of the hair conditioning nozzle 11, it is usually necessary to remove the hair conditioning chamber 12 from the hair conditioning nozzle 11 when it needs to be replaced or hair oil added to it. Therefore, by having a through hole 114 on the hair conditioning nozzle 11, after the hair conditioning chamber 12 is installed into the receiving cavity 112, a portion of the structure of the hair conditioning chamber 12 is located in the through hole 114. Thus, when it is necessary to remove the hair conditioning chamber 12, pressing the portion of the hair conditioning chamber 12 corresponding to the through hole 114 can push the hair conditioning chamber 12, thereby pushing it out from the opening end of the hair conditioning nozzle 11 and removing it. That is, in this embodiment of the utility model, the hydration chamber 12 can be disassembled simply by pressing it. Compared with the structure design of setting through holes 114 for pressing and disassembling by means of threaded connection or adhesive fixation, the overall structure is simple and ingenious, which makes the hydration component 1 easy to disassemble and improves the actual user experience.

[0047] In some embodiments, such as Figure 5 As shown, the humidifying nozzle 11 is equipped with a first magnetic element 14, and one of the humidifying chamber 12 and the air guide 13 is equipped with a second magnetic element 15, while the other is equipped with a ferromagnetic metal element 16; or both the humidifying chamber 12 and the air guide 13 are equipped with ferromagnetic metal elements 16, and both the second magnetic element 15 and the ferromagnetic metal element 16 are attracted to the first magnetic element 14. With this configuration, after the humidifying chamber 12 and the air guide 13 are installed in the receiving cavity 112, the interaction between the first magnetic element 14 and the second magnetic element 15 and / or the ferromagnetic metal element 16 can fix the installation position of the humidifying chamber 12 and the air guide 13, while also facilitating disassembly. This magnetic connection method is simple in structure and has good connection reliability.

[0048] In some embodiments, such as Figure 2 and Figure 5 As shown, the conditioning nozzle 11 includes a frustum 115, with at least a partial receiving cavity 112 formed within it. The frustum 115 is positioned so that it faces the end of the conditioning nozzle 11 connected to the hair dryer housing. Thus, the width of the frustum 115 gradually increases along the airflow direction of the hair dryer, guiding the airflow to gradually diffuse, creating a larger airflow area, increasing the effective area for drying and conditioning the hair. Simultaneously, a through hole 114 is formed at the end of the frustum 115 facing the housing. This allows the conditioning chamber 12 to be disassembled only after the nozzle assembly has been removed from the hair dryer housing, protecting the conditioning chamber 12 from accidental detachment and improving reliability.

[0049] In some embodiments, such as Figure 2 and Figure 5 As shown, along the axial direction of the frustum portion 115, the cross-sectional shape of the portion of the receiving cavity 112 located within the frustum portion 115 is an isosceles trapezoid, and the outer wall surface of the nutrient chamber 12 is provided with a mounting inclined surface 123 (see reference). Figure 7 This design sets the inner wall of the receiving cavity 112 as a slope, while also ensuring that the outer wall of the hydration chamber 12 has an installation slope 123. This structural design, at least during the installation of the hydration chamber 12, provides guidance through the slope, facilitating quick and accurate installation. It also guides the disassembly and separation of the hydration chamber 12 and enhances its overall aesthetics.

[0050] In some embodiments, such as Figure 6 and Figure 7 As shown, the conditioning chamber 12 includes a chamber body 124 and a chamber cover 125. The chamber body 124 is at least partially installed within the receiving cavity 112, and the conditioning oil cavity 121 is formed within the chamber body 124, with an opening at the end of the chamber body 124 furthest from the hair dryer. The chamber cover 125 covers the end of the chamber body 124 with the opening, and a flow port 122 is formed on the chamber cover 125. This configuration creates a hollow internal structure with the chamber cover 125 and chamber body 124. Hair oil is filled into the conditioning oil cavity 121, and the air generated by the hair dryer is blown into the conditioning oil cavity 121 through the air duct 111 and the flow port 122, and then flows out through the flow port 122. The air flowing out of the flow port 122 carries hair oil molecules, which are then blown onto the user's hair by the airflow. The evaporated oil molecules adhere to the hair, thus achieving hair conditioning.

[0051] In some embodiments, such as Figure 2 and Figure 7 As shown, the hair conditioning component 1 also includes a sealing ring 17, which is disposed at the connection between the cap 125 and the body 124 to seal the gap between the body 124 and the cap 125. Specifically, the cap 125 can be connected to the body 124 by means of a snap or threaded connection, and a sealing ring 17 is provided at the connection between the two to prevent hair oil from leaking from the gap between them. The sealing ring 17 can be made of elastic silicone or rubber material, so that it can undergo elastic deformation when the cap 125 and the body 124 are connected, achieving a reliable seal.

[0052] In some embodiments, such as Figure 7As shown, a snap fastener 126 is provided on the bin cover 125, and a protrusion 127 is provided on the inner wall of the bin body 124 that forms the material protection cavity 121. By engaging the snap fastener 126 with the protrusion 127, the bin cover 125 and the bin body 124 can be fixedly connected. Simultaneously, after engagement, a compression sealing ring 17 is formed, thereby sealing the gap between the bin cover 125 and the bin body 124. Specifically, the snap fastener 126 extends from the bottom of the bin cover 125 towards the bottom of the material protection cavity 121, and at least two snap fasteners 126 are provided, symmetrically distributed. The snap fastener 126 has a certain elastic deformation property, and has holes to accommodate the protrusion 127. Therefore, during assembly, by engaging the protrusion 127 into the holes of the snap fastener 126, the bin cover 125 and the bin body 124 can be fixedly connected. The connection structure is simple and has good reliability. Furthermore, both the buckle 126 and the protrusion 127 are located inside the material protection cavity 121. After the assembly of the bin cover 125 is completed, the buckle 126 and the protrusion 127 can be covered, making the bin cover 125 and the bin body 124 a hidden connection, which improves the overall aesthetics.

[0053] In some embodiments, to further prevent leakage of hair oil within the conditioning chamber 121, a leak-proof structure is provided on at least one of the cap 125 and the chamber body 124. Specifically, the leak-proof structure on the cap 125 increases the difficulty of hair oil leakage through the flow port 122, thereby further preventing leakage. By providing the leak-proof structure on the chamber body 124, any leaked hair oil (e.g., through the flow port 122 or from the gap between the chamber body 124 and the cap 125) can be collected, preventing further leakage into the air duct 111. This effectively avoids the problem of leaked hair oil flowing into the air duct 111 and being blown onto the hair as large droplets, thus reducing the hair conditioning effect. Both the cover 125 and the body 124 are equipped with leak-proof structures, which provide double leak-proof function and double protection, further improving the reliability of preventing hair care oil from leaking and / or flowing into the air duct 111.

[0054] like Figure 7As shown, in some embodiments, the leak-proof structure includes a leak-proof groove 1241 disposed on the container body 124 and a liquid-absorbing element 1242 disposed within the leak-proof groove 1241. The leak-proof groove 1241 is arranged around the outline shape of the container cover 125. Specifically, the dimension of the outline edge of the container body 124 is larger than the dimension of the outline edge of the container cover 125, so that after the container cover 125 is connected to the container body 124, the orthographic projection of the outline edge of the container cover 125 in the vertical direction is located within the area enclosed by the outline edge of the container body 124. Thus, from the projection direction, the leak-proof groove 1241 is located outside the outline edge of the container cover 125. Since a sealing ring 17 is provided at the connection between the container body 124 and the container cover 125, the hair care essential oil that leaks from the protective cavity 121 usually flows out through the flow port 122. Therefore, the anti-leakage groove 1241 is designed to surround the outline of the cover 125, so that no matter which edge of the hair oil leaks from the outlet 122, there is a corresponding anti-leakage groove 1241 to block it, and the leaked hair oil will flow into the anti-leakage groove 1241. Furthermore, an absorbent element 1242 is provided in the anti-leakage groove 1241 to absorb the hair oil flowing into the anti-leakage groove 1241, so that the leaked hair oil can be collected on the absorbent element 1242, further improving the reliability of blocking the leaked hair oil.

[0055] Specifically, in actual use, the conditioning chamber 12 is placed in a side-standing position, which can easily cause hair oil to leak from the bottom edge of the flow port 122. Therefore, by designing the anti-leakage groove 1241 to surround the outline of the chamber cover 125, it is possible to effectively collect the hair oil flowing out through the flow port 122. Moreover, since the anti-leakage groove 1241 is set around the chamber cover 125, even if hair oil leaks from the gap connecting the chamber body 124 and the chamber cover 125, it can be collected through the anti-leakage groove 1241 and the liquid absorption element 1242, resulting in a reliable anti-leakage effect.

[0056] The liquid-absorbing component 1242 can be made of a material that can absorb and store a certain amount of liquid, such as a sponge, resin, or activated carbon. The liquid-absorbing component 1242 can be configured in the same way as the leak-proof groove 1241, or it can be configured as a single independent unit and then filled into the leak-proof groove 1241 as needed, which provides good flexibility in configuration and use.

[0057] In some embodiments, such as Figure 7As shown, the leak-proof structure can also include a flange 1250 provided on the cover 125. The flange 1250 is located at the edge of the cover 125 that forms the flow port 122 and protrudes towards the inner cavity 121. Specifically, the flange 1250 is continuously provided along the contour edge of the flow port 122, and its free end protrudes towards the direction of the inner cavity 121. With this configuration, in the side-standing usage state, the flange 1250 effectively increases the height of the edge of the flow port 122, thereby increasing the difficulty for the hair oil to flow out from the edge of the flow port 122. Moreover, protruding towards the direction of the inner cavity 121 does not reduce the area of ​​the flow port 122, thus not affecting the efficiency of airflow exchange in the inner cavity 121, and therefore not affecting the evaporation effect of the hair oil, enabling effective conditioning of the hair. This leak-proof structure not only effectively prevents the leakage of hair oil, but also ensures the hair conditioning efficiency of the hair oil, demonstrating ingenious design.

[0058] In some embodiments, such as Figure 7 As shown, the conditioning chamber 12 also includes a storage component 128 for storing hair care oil, which is disposed within the conditioning cavity 121. Specifically, the storage component 128 can be made of a material that can absorb and store a certain amount of liquid, such as a sponge, resin, or activated carbon. Moreover, in the direction perpendicular to the axis of the storage component 128 and the conditioning cavity 121, the cross-sectional shapes of the storage component 128 and the conditioning cavity 121 are substantially the same, thereby allowing the storage component 128 to be installed within the conditioning cavity. The outer wall of the storage component 128 and the interior of the conditioning cavity 121 can remain in close contact, and by reducing the size of the storage component 128, an appropriate distance can be maintained between them (such as 1mm-2mm), so that airflow can contact the storage component 128, improving the efficiency of hair care oil treatment. Similarly, the bottom of the storage component 128 can be kept in close contact with the bottom of the protective cavity 121, or a support block can be provided at the bottom of the protective cavity 121 to create a gap between the bottom of the storage component 128 and the bottom of the protective cavity 121, so that airflow can enter the bottom of the storage component 128, which can also increase the amount of hair care oil stored.

[0059] This utility model embodiment also provides a hair dryer, including a housing and the hair conditioning component 1 described in any of the above embodiments, with a conditioning nozzle 11 connected to the air outlet of the housing. Specifically, the conditioning nozzle 11 and the housing are typically detachably connected, such as through threaded connection or magnetic attraction. The hair conditioning component 1 uses the air generated by the hair dryer to evaporate the hair care essential oil inside, and blows the evaporated essential oil molecules onto the user's hair, achieving hair conditioning. By incorporating the aforementioned hair conditioning component 1, the hair dryer not only protects the hair but also allows for easy disassembly of the conditioning chamber 12 for convenient replacement or replenishment of the hair care essential oil, providing ease of use and a superior user experience.

[0060] like Figure 5 As shown in this embodiment of the utility model, a fixing member 119 is provided on the hair conditioning component 1, and the fixing member 119 is a magnetic member that can be attracted to the ferromagnetic metal member 16 in the housing of the hair dryer, thereby realizing a detachable connection between the hair conditioning component 1 and the hair dryer. The connection is convenient and improves the ease of use.

[0061] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions and improvements made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A hair conditioning component, characterized in that, include: A conditioning nozzle is attached to the housing of a hair dryer. The conditioning nozzle has an air duct that communicates with the air outlet of the hair dryer, and a receiving cavity is formed inside the conditioning nozzle. The conditioning chamber is connected to the conditioning nozzle and installed inside the receiving cavity. The interior of the conditioning chamber forms a conditioning material cavity for containing hair care essential oil. The conditioning chamber has a flow port that communicates with the conditioning material cavity. An air guide is located in the receiving cavity and connected to the lubrication nozzle and / or the lubrication chamber. The air guide is provided with an air inlet and an air outlet. At least part of the air flowing out of the air duct enters the material protection cavity in sequence through the air inlet and the flow port. The air in the material protection cavity flows out in sequence through the flow port and the air outlet. The air outlet is located adjacent to the air duct, and the air outlet faces the air outlet path of the air duct.

2. The hair conditioning component as described in claim 1, characterized in that, The air guide component includes: The main body is ring-shaped, and the air inlet is located on the main body; the main body is connected to the humidification nozzle and / or the humidification chamber. A top cover is disposed above the main body, the top cover is connected to the main body, and there is a gap between the top cover and the main body to form the air outlet.

3. The hair conditioning component as described in claim 2, characterized in that, The air inlets are provided in multiple ways, and each air inlet is distributed at intervals along the outline shape of the body.

4. The hair conditioning component as described in claim 2, characterized in that, The air guide also includes a support ring protruding in a direction away from the humidification chamber. The support ring is connected to the body via a support rod, and the top cover and the support ring are connected by a snap-fit ​​structure.

5. The hair conditioning component as described in claim 2, characterized in that, Of the outline shape of the body and the outline shape of the top cover, at least the outline shape of the top cover is the same as the outline shape of the air duct.

6. The hair conditioning component as described in claim 1, characterized in that, The humidifying nozzle is used to form an air guide slope on the inner wall of the air duct. The air guide slope is inclined toward the air guide to guide the airflow in the air duct toward the air inlet.

7. The hair conditioning component as described in claim 6, characterized in that, The angle of inclination of the air guide slope relative to the central axis of the receiving cavity is 3° to 15°.

8. The hair conditioning component as described in claim 1, characterized in that, The hydration nozzle has a through hole that communicates with the receiving cavity, so as to push the hydration chamber to separate from the hydration nozzle.

9. The hair conditioning component as described in claim 8, characterized in that, The humidification nozzle is provided with a first magnetic element, and the humidification chamber and the air guide are respectively provided with a second magnetic element or ferromagnetic metal; Both the second magnetic component and the ferromagnetic metal component are attracted to the first magnetic component.

10. The hair conditioning component as described in claim 8, characterized in that, The humidifying nozzle includes a frustum portion, and at least a portion of the receiving cavity is formed within the frustum portion; wherein the through hole is formed at one end of the frustum portion facing the housing.

11. The hair conditioning component as claimed in claim 1, characterized in that, The nourishing chamber includes: The chamber is at least partially installed within the accommodating container, the material protection chamber is formed within the chamber, and an opening communicating with the material protection chamber is provided at the end of the chamber away from the blower; A bin cover is provided on the end of the bin body that has the opening, and the flow port is opened on the bin cover; The air flowing out of the air duct enters the material protection chamber through the flow port, and the air in the material protection chamber flows out through the flow port.

12. A hair dryer, characterized in that, It includes a housing and a conditioning component as described in any one of claims 1 to 11, wherein the conditioning nozzle is connected to the air outlet end of the housing.