Breast massage device

By spatially separating different therapeutic components in the breast massage device and using cooling plates and heat dissipation modules to achieve independent operation of hot and cold modes, the problem of mutual interference between therapeutic components in existing devices is solved, thereby improving the device's therapeutic efficiency and user experience.

CN224474560UActive Publication Date: 2026-07-10SHENZHENSHI LUTEJIACHENG SUPPLYCHAIN MANAGEMENT CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHENSHI LUTEJIACHENG SUPPLYCHAIN MANAGEMENT CO LTD
Filing Date
2025-06-18
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing breast massage devices interfere with each other when multiple physiotherapy departments are simultaneously performing physiotherapy functions, resulting in reduced physiotherapy effects and user discomfort, and failing to meet the needs for efficient and comfortable comprehensive physiotherapy.

Method used

Design a breast massage device that forms physical isolation by placing different physiotherapy components in different orientations of the shell, ensuring that functions such as cold compress, hot compress, and vibration massage are spatially separated. Use cooling plates and heat dissipation modules to achieve independent operation of cold and hot functions, and use heat insulation structures and directional heat conduction paths to avoid interference.

Benefits of technology

It enables independent operation of physiotherapy functions such as cold compress, hot compress, and vibration massage, improving the efficiency and comfort of physiotherapy, eliminating functional interference, and meeting users' needs for a comprehensive physiotherapy experience that is efficient and comfortable.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of breast massage equipment, it is related to massager technical field, wherein, breast massage equipment includes shell, the shell includes at least two contact surfaces to breast and apply physiotherapy function, respectively first contact surface and second contact surface;The first contact surface includes first physiotherapy part, and the second contact surface includes second physiotherapy part;At least one of the first physiotherapy part and the second physiotherapy part is cold compress physiotherapy part, for applying cold compress physiotherapy to breast;The first contact surface and second contact surface are located in the two different orientation direction of the shell, so that the first physiotherapy part and the second physiotherapy part simultaneously implement physiotherapy function, and they do not interfere with each other.The technical scheme provided by the utility model can not interfere with each other when multiple physiotherapy parts simultaneously implement physiotherapy, meet the demand of user to efficient comfortable physiotherapy experience.
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Description

Technical Field

[0001] This utility model relates to the field of massager technology, and in particular to a breast massage device. Background Technology

[0002] Existing breast massage devices typically feature multiple treatment sections to provide various therapeutic functions, such as cold compresses, hot compresses, and massage. However, the structural design of these devices lacks a rational spatial layout and functional zoning, leading to interference between these treatment sections when they are simultaneously performing their functions. This interference not only reduces the overall therapeutic effect but may also cause discomfort to the user, limiting the application of existing breast massage devices in various scenarios, especially when combined with other therapies such as cold compresses and massage, thus failing to meet users' needs for an efficient and comfortable therapeutic experience. Utility Model Content

[0003] The main purpose of this invention is to provide a breast massage device that allows multiple physiotherapy departments to perform physiotherapy simultaneously without interfering with each other, thus meeting users' needs for an efficient and comfortable physiotherapy experience.

[0004] To achieve the above objectives, this utility model proposes a breast massage device for applying a physiotherapy function to the breasts. The breast massage device includes:

[0005] The housing includes at least two contact surfaces that apply physical therapy to the breast, namely a first contact surface and a second contact surface;

[0006] The first contact surface includes a first physiotherapy section, and the second contact surface includes a second physiotherapy section;

[0007] At least one of the first physiotherapy unit and the second physiotherapy unit is a cold compress physiotherapy unit, used to apply cold compress physiotherapy to the breast;

[0008] The first contact surface and the second contact surface are located in two different orientations of the housing so that when the first physiotherapy unit and the second physiotherapy unit perform physiotherapy functions at the same time, they do not interfere with each other.

[0009] In one embodiment, the first physiotherapy unit is a cold compress physiotherapy unit, and the second physiotherapy unit is a hot compress physiotherapy unit.

[0010] In one embodiment, the breast massage device includes a cooling device disposed inside the housing and connected to the cold compress therapy section; the breast massage device also includes a heating device disposed inside the housing and connected to the hot compress therapy section.

[0011] In one embodiment, the cooling device includes a cooling plate and a heat dissipation module. The cooling plate is attached to the housing and connected to the cold compress therapy unit. The heat dissipation module is connected to the end of the cooling plate away from the cold compress therapy unit and is used to dissipate the heat generated by the cooling plate.

[0012] In one embodiment, the heating device includes:

[0013] A heating outer shell, wherein the heating outer shell is connected to the housing and spaced apart from the cooling device; and

[0014] A heating element is disposed between the inner wall of the heat-conducting outer shell and the shell, and is used to provide heat to the heat-conducting outer shell.

[0015] In one embodiment, the first contact surface and the second contact surface are located on two surfaces of the housing spacer.

[0016] In one embodiment, a heat insulation structure is provided between the hot compress therapy section and the cold compress therapy section, the heat insulation structure being used to separate the hot compress therapy section and the cold compress therapy section.

[0017] In one embodiment, the first contact surface is provided with a raised mounting position, and the raised mounting position is provided with a cold compress therapy section.

[0018] In one embodiment, there are multiple protruding mounting positions arranged on the surface of the housing, and each protruding mounting position is provided with a cold compress therapy section.

[0019] In one embodiment, the cold compress therapy unit is located at one end of the housing.

[0020] In one embodiment, the housing further has an air inlet and a heat dissipation hole that connect to the external environment, and a ventilation path is formed between the air inlet and the heat dissipation hole;

[0021] The heat dissipation module includes a heat sink and a fan. The heat sink is connected to the cooling chip, and both the heat sink and the fan are located in the ventilation path. The fan is used to dissipate the heat from the heat sink to the external environment.

[0022] In one embodiment, the heat dissipation module further includes a duct shell installed inside the housing, the duct shell being connected to the hot end of the cooling chip; the duct shell is connected to the air inlet and the heat dissipation hole, forming the ventilation path; the outer wall of the fan is sealed against the inner wall of the duct shell to drive fresh air to flow sequentially from the air inlet, the ventilation path and the heat dissipation hole.

[0023] In one embodiment, the exhaust side of the fan is positioned toward the heat sink.

[0024] In one embodiment, the housing is configured as a curved body structure, and the bottom of the housing is a concave side of the curved body structure, with the second physiotherapy unit disposed on the concave side.

[0025] In one embodiment, one of the first physiotherapy unit and the second physiotherapy unit is the cold compress physiotherapy unit, and the other of the first physiotherapy unit and the second physiotherapy unit is the massage physiotherapy unit.

[0026] In one embodiment, the massage therapy unit includes:

[0027] A vibration motor, the vibration motor being installed within the housing; and

[0028] A conductive rubber component, one end of which is connected to the output shaft of the vibration motor, and the other end of which is connected to the housing in a transmission connection;

[0029] The vibration motor is used to drive the conductive rubber component to vibrate, so that the conductive rubber component drives the housing to vibrate, thereby performing a massage operation on the breast.

[0030] The breast massage device of this utility model includes a housing with two contact surfaces facing different directions, namely a first contact surface and a second contact surface. A first treatment section is disposed on the first contact surface, and a second treatment section is disposed on the second contact surface, wherein at least one treatment section is a cold compress treatment section. The two contact surfaces are spatially offset to ensure that the treatment functions do not interfere with each other. This innovative design, by placing the first and second contact surfaces in different positions on the housing, physically separates the treatment sections with different functions, fundamentally eliminating functional interference. This allows users to simultaneously enjoy dual treatments of cold and hot compresses, or a combination of cold compresses and vibration massage. Multiple treatment sections can be administered simultaneously without interference, ensuring that cold compresses and other treatment functions operate independently, meeting users' needs for a highly efficient and comfortable treatment experience, and improving treatment efficiency and comfort. Attached Figure Description

[0031] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.

[0032] Figure 1 Top view of the breast massage device provided by this utility model;

[0033] Figure 2 A bottom view of the breast massage device provided by this utility model;

[0034] Figure 3 A longitudinal sectional view of the breast massage device provided by this utility model;

[0035] Figure 4 Exploded view of the structure of the breast massage device provided by this utility model;

[0036] Figure 5 A longitudinal cross-sectional view of the cooling device of the breast massage device provided by this utility model.

[0037] Explanation of icon numbers:

[0038] 10. Housing; 10a. First therapy section; 10b. Second therapy section; 10c. Raised mounting position; 10d. Air inlet; 10e. Heat dissipation hole; 10f. Ventilation path; 20. Cooling device; 21. Cooling element; 22. Heat dissipation module; 221. Heat sink; 222. Fan; 223. Air duct housing; 30. Heating device; 31. Hot compress housing; 32. Heating element; 40. Massage therapy section; 41. Vibration motor; 42. Conductive adhesive component.

[0039] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation

[0040] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of the present utility model.

[0041] It should be noted that if the embodiments of this utility model involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.

[0042] Furthermore, if the embodiments of this utility model involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or" or "and / or" throughout the text includes three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where both A and B are satisfied simultaneously. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.

[0043] In existing technologies, breast massage devices are typically equipped with multiple treatment sections to achieve different functions, but these sections are prone to interference when operating simultaneously. For example, if the cold and hot compress areas are in the same direction, heat conduction can weaken the cold compress effect; when vibration massage and temperature therapy are combined, mechanical movement may affect the uniformity of temperature distribution. These issues limit the comprehensive application of the device in multiple scenarios and cannot meet users' needs for simultaneous therapy.

[0044] To address the aforementioned issues, the inventors observed that the core reason for the mutual interference between the therapeutic functions of existing devices lies in the spatial overlap of the therapeutic areas. Analysis revealed that distributing the therapeutic components with different functions in different locations within the device, physical isolation can effectively block energy transfer paths. Based on this, they proposed designing the casing as a multi-faceted structure, allowing cold compresses and other therapeutic functions to act on independent areas, while simultaneously creating a natural isolation barrier through directional differences.

[0045] Therefore, please refer to Figures 1 to 5 This application discloses a breast massage device, including a housing 10, which has two contact surfaces facing different directions, namely a first contact surface and a second contact surface. A first treatment section 10a is disposed on the first contact surface, and a second treatment section 10b is disposed on the second contact surface, wherein at least one treatment section is a cold compress treatment section. The two contact surfaces are spatially offset from each other to ensure that the treatment functions do not interfere with each other.

[0046] It should be noted that the simultaneous application of therapeutic functions by the first therapy unit 10a and the second therapy unit 10b does not specifically refer to the situation where the first therapy unit 10a and the second therapy unit 10b must be applied to the breasts simultaneously. Rather, it can refer to a situation where the duration of the functions of the two therapy units overlaps, with one being applied to the breasts while the other is in a preheating or precooling state. For example, if a user initially applies the heating function to the breasts by placing the heating therapy unit 10a on the chest, and then activates the cooling therapy unit 10b during the heating process to precool the breasts, the cooling therapy unit 10b may not be applied to the breasts at this time; it may simply be precooling a surface that is not in contact with the breasts. When the user needs to switch to the cooling function, they can simply flip the massager or change its angle to quickly use the precooled cooling function, thus relieving pain quickly without having to wait for the cooling temperature to reach the desired level, improving the user experience.

[0047] In this embodiment, the housing 10 refers to the supporting structure that encloses the internal components of the device. It can adopt a curved or split design, for example, it can be injection molded from medical-grade plastic, and its surface curvature can be adapted to the curve of the human body. The contact surface refers to the functional area that directly contacts the human body. For example, the first contact surface can be located on the top plane of the housing 10, and the second contact surface can be located on the inclined side surface of the housing 10. The cold compress therapy section refers to the module that achieves the cooling function through temperature conduction. Different orientation directions refer to the spatial angle formed by two contact surfaces, such as: vertical and horizontal directions, two parallel planes, or two non-parallel planes, forming a physical isolation zone through the difference in orientation.

[0048] For example, when the breast massage device is working, the cooling therapy section of the first contact surface lowers the temperature of the contact surface through the cooling plate 21, providing a cooling effect on the breast area; the therapy section of the second contact surface can simultaneously perform a hot compress or vibration massage. Because the two contact surfaces face different directions, a spatial isolation is formed between the cooling area and the heat source or vibration source, blocking the heat transfer path and preventing the cooling area from being heated or affected by vibration, thus maintaining temperature stability. For instance, when the top contact surface of the housing 10 is used for cooling, the heat from the side contact surface is blocked by the internal heat insulation layer of the housing 10, acting only on the side area, thereby achieving simultaneous and independent operation of the two therapy functions.

[0049] In other embodiments, the orientation of the first contact surface and the second contact surface is not limited to the orientation described above.

[0050] Compared to existing technologies, traditional equipment arranges multiple treatment areas on the same plane, causing heat conduction or mechanical vibration to affect each other.

[0051] Through the above technical solution, this solution, by innovatively placing the first and second contact surfaces at different locations on the housing 10, physically separates the physiotherapy sections with different functions, fundamentally eliminating functional interference. This allows users to simultaneously enjoy dual physiotherapy of cold and hot compresses, or a combination of cold compresses and vibration massage. Multiple physiotherapy sections can be administered simultaneously without interference, ensuring that cold compresses and other physiotherapy functions operate independently. This meets users' needs for a highly efficient and comfortable physiotherapy experience, improving the efficiency and comfort of the treatment. Furthermore, this innovative design achieves functional isolation of different physiotherapy sections without the need for additional isolation components, reducing equipment manufacturing costs and structural complexity.

[0052] Please see Figures 1 to 4 This application further proposes that the first physiotherapy section 10a is a cold compress physiotherapy section and the second physiotherapy section 10b is a hot compress physiotherapy section.

[0053] In this embodiment, the cooling therapy section refers to a component that achieves local cooling by lowering the temperature of the contact surface. Specifically, it can be implemented using a semiconductor cooling chip 21 combined with a heat dissipation module 22, transferring heat from the contact surface to the external environment through active cooling. The heating therapy section refers to a component that achieves local heating by raising the temperature of the contact surface. Specifically, it can be implemented using a resistance heating element or a far-infrared heating film, heating the target area by converting electrical energy into heat energy.

[0054] Specifically, the cold compress therapy section and the hot compress therapy section are respectively located on two contact surfaces of the housing 10 facing different directions. When the device is working, the cold compress therapy section and the hot compress therapy section act on adjacent or different areas of the breast, respectively. Because they are located in different spatial directions of the housing 10, the low-temperature area generated by the cold compress and the high-temperature area generated by the hot compress are physically isolated. The heat from the cold compress therapy section is discharged to the external environment through the heat dissipation module 22, while the heat from the hot compress therapy section is concentrated in the target area through heat conduction. There is no direct heat transfer path between the two, thus avoiding the mutual cancellation or interference of cold and hot temperatures.

[0055] Please see Figures 1 to 4 This application further proposes that the breast massage device includes a cooling device 20, which is disposed inside the housing 10 and connected to the cold compress therapy section; the breast massage device also includes a heating device 30, which is disposed inside the housing 10 and connected to the hot compress therapy section.

[0056] In this embodiment, the cooling device 20 refers to a component that achieves a cooling function through active cooling. The heating device 30 refers to a component that generates heat energy through electrothermal conversion. Specifically, the cooling device 20 and the heating device 30 are integrated into independent functional areas of the housing 10. The two devices form an independent temperature control system through the physical separation of the housing 10, and the cooling circuit and the heating circuit maintain a spatial distance to avoid cross-influence of cold and heat energy during conduction.

[0057] Compared to existing technologies, traditional equipment where the cooling and heating modules share the same installation space leads to mutual interference in temperature fields. This solution, through the functional partitioning design within the housing 10, allows the cooling device 20 and heating device 30 to form physically isolated independent working units, enabling the parallel operation of cooling and heating functions. The cooling function maintains a low temperature through active heat dissipation, while the heating function maintains a constant temperature through closed-loop heat conduction. The two functions work collaboratively in a spatially isolated state, improving the therapeutic effect while ensuring the safety of equipment operation.

[0058] Please see Figures 1 to 5 This application further proposes a cooling device 20 including a cooling chip 21 and a heat dissipation module 22. The cooling chip 21 is attached to the housing 10 and connected to the cold compress therapy section. The heat dissipation module 22 is connected to the end of the cooling chip 21 away from the cold compress therapy section and is used to dissipate the heat generated by the cooling chip 21.

[0059] In this embodiment, the cooling chip 21 refers to a semiconductor device that generates electricity based on the Peltier effect. Specifically, it can be implemented using a double-sided metal-ceramic packaged semiconductor cooling chip 21. Its cold end contacts the cooling therapy area to transfer cold energy, and its hot end is connected to the heat dissipation module 22 to dissipate heat. The heat dissipation module 22 refers to an active heat conduction component, which can be implemented using an aluminum heat sink 221 combined with an axial fan 222. The heat sink 221 is attached to the hot end of the cooling chip 21 with thermal grease, and the fan 222 drives airflow to accelerate heat exchange on the surface of the heat sink 221.

[0060] Specifically, the cold end of the cooling pad 21 directly contacts the cooling therapy area, forming a cold transfer path that rapidly lowers the temperature of the cooling area to the target range. The heat generated by the hot end of the cooling pad 21 increases the heat dissipation area through the heat sink 221, and is expelled from the housing 10 by forced convection from the fan 222. The spatial separation of the cooling pad 21 and the heat dissipation module 22 creates physical isolation with opposite directions of heat conduction, preventing heat from being conducted back to the cooling area through the material of the housing 10. The exhaust direction of the fan 222 in the heat dissipation module 22 can be set perpendicular to the surface of the heat sink 221. For example, a centrifugal fan 222 can be used to axially exhaust the hot air in the gaps of the heat sink 221, thereby establishing an efficient heat dissipation channel from the hot end of the cooling pad 21 to the outside of the housing 10.

[0061] This solution uses the directional heat conduction design of the cooling plate 21 and the heat dissipation module 22 to form a spatially isolated heat management path between the cooling area and the heat dissipation area. At the same time, it uses forced convection heat dissipation to improve heat exchange efficiency, achieving the dual effect of stable operation of the cooling function and parallel operation of multiple physiotherapy functions without interference.

[0062] Please see Figures 1 to 4 This application further proposes that the heating device 30 includes a heat-compressing outer shell 31 and a heating element 32. The heat-compressing outer shell 31 is connected to the housing 10 and spaced apart from the cooling device 20. The heating element 32 is disposed between the inner wall of the heat-compressing outer shell 31 and the housing 10.

[0063] In this embodiment, the heating outer shell 31 refers to the heat transfer component used to wrap the heating element 32 and contact the breast. It is connected to the shell 10 to form an independent cavity, and the heat exchange path with the cooling device 20 is blocked by a physical gap. The heating element 32 refers to the element that generates heat energy. Specifically, it can be an electric heating wire or a carbon fiber heating film attached to the inner wall of the heating outer shell 31. Heat is evenly conducted to the contact surface through the heating outer shell 31, and at the same time, the thermal resistance characteristics of the shell 10 material can inhibit the diffusion of heat towards the cooling device 20.

[0064] Specifically, the heating outer shell 31 is fixedly connected to the housing 10 by bolts or clips, forming a space between them. The heating element 32 is encapsulated in this space, and heat is applied directly to the breast tissue through the outer surface of the heating outer shell 31. The cooling device 20 is arranged on the other side of the housing 10, maintaining a distance from the heating outer shell 31. This space is filled with insulating material to form a thermal barrier. When the heating element 32 is powered on, heat is confined within the space between the heating outer shell 31 and the housing 10 for directional transfer, preventing lateral heat conduction from affecting the heat dissipation efficiency of the cooling module.

[0065] Compared to existing technologies, traditional solutions place the hot and cold modules in adjacent areas, leading to cross-interference of heat flow. This solution, however, utilizes a sandwich structure between the heat-applying outer shell 31 and the housing 10 to create a directional heat transfer channel, while simultaneously employing an interleaved layout to cut off the direct heat conduction path between the hot and cold modules. This solution, through the closed sandwich structure formed between the inner wall of the heat-applying outer shell 31 and the housing 10, ensures that heat is transferred only along the contact surface direction.

[0066] The heating element 32 can employ various heating technologies, such as electric heating wire, carbon fiber heating, and graphene heating, offering advantages such as rapid heating, uniform temperature, and long service life. The heating assembly also features a temperature adjustment function, allowing users to adjust the heating temperature according to their needs via the control panel or remote control, ensuring comfort and safety during the heating process.

[0067] The heating pad shell 31 is a soft rubber shell made of high-quality medical-grade silicone material, possessing excellent flexibility and biocompatibility. The soft rubber shell conforms closely to the breast surface, ensuring sufficient heat transfer to breast tissue while providing a comfortable user experience. The surface of the soft rubber shell is specially treated to have a certain coefficient of friction, preventing the heating pad shell 31 from slipping during use and ensuring the heating effect. Furthermore, the soft rubber shell has good weather resistance and aging resistance, maintaining good performance and appearance over long-term use.

[0068] Please see Figures 1 to 4 This application further proposes that the first contact surface and the second contact surface are located on two spaced surfaces of the housing 10.

[0069] In this embodiment, the two spaced surfaces of the housing 10 refer to two independent regions on the housing 10 that are separated from each other and have a spatial distance. Specifically, this can be achieved using planes or curved surfaces on opposite sides of the housing 10. The two surfaces are physically separated by the internal structure or external contour of the housing 10. This spacing allows the two contact surfaces to be spatially separated, avoiding direct contact between the physiotherapy units.

[0070] Specifically, the two contact surfaces are respectively located on different surface areas of the housing 10, for example, one on the front surface of the housing 10 and the other on the rear surface of the housing 10. When the device is working, the two treatment sections act on adjacent or different areas of the breast. Due to the spatial isolation between the contact surfaces, the low temperature of the cold compress treatment section and the high temperature of the hot compress treatment section are not directly conducted through the material of the housing 10, and the mechanical motion of the vibration treatment section is not transmitted to the other treatment section through the structure of the housing 10. Thus, the two treatment functions form independent operating areas in physical space, blocking the mutual interference of energy or motion.

[0071] Through the above technical solution, this application realizes the independent operation of cold compress, hot compress or vibration physiotherapy functions, ensuring the effective transmission of different physiotherapy effects, while avoiding the decrease in physiotherapy effect caused by temperature neutralization or mechanical interference, and improving user comfort and physiotherapy efficiency.

[0072] This application further proposes a technical solution for setting up a heat insulation structure between the hot compress therapy section and the cold compress therapy section.

[0073] In this embodiment, the thermal insulation structure refers to a physical isolation component used to block the heat conduction path, which can be implemented using a polyurethane foam layer or a ceramic fiber board. This structure separates the hot and cold areas into independent temperature zones through a low thermal conductivity material layer, forming a temperature gradient buffer zone inside the equipment.

[0074] Specifically, when the hot compress therapy unit generates high temperature through the heating device 30, the heat insulation structure, due to the low thermal conductivity of its material, inhibits heat diffusion to the cold compress therapy unit. Simultaneously, when the cold compress therapy unit maintains a low temperature through the cooling device 20, the heat insulation structure prevents the transfer of cold energy to the hot compress area. This structure ensures temperature stability for both therapy units within their respective enclosed spaces, preventing cross-interference of hot and cold energy through the metal components of the casing 10 or internal air convection. This allows the hot and cold therapy units to operate as independent units, maintaining their respective set temperature ranges even during synchronous operation.

[0075] Please see Figures 1 to 4 This application further proposes that the first contact surface is provided with a raised mounting position 10c, and the raised mounting position 10c is provided with a cold compress therapy section.

[0076] The raised mounting position 10c refers to a localized raised structure extending outward from the surface of the housing 10, which can be implemented using a hemispherical, cylindrical, or arc-shaped boss structure. This structure forms an independent mounting area through a physical height difference, used to support the cold compress therapy unit and spatially isolate it from adjacent therapy units. The cold compress therapy unit, positioned and supported by the raised mounting position 10c, can directionally transfer cooling energy to the target area.

[0077] Optionally, the raised mounting position 10c is located on the top surface, bottom surface, or side surface of the housing 10. The top surface refers to the area of ​​the housing 10 that contacts the upper side of the breast, and its curvature is adapted to the upper curve of the human breast. The bottom surface refers to the flat or curved area of ​​the housing 10 that contacts the lower edge of the breast, facilitating adjustment of the contact angle according to the user's body shape. The side surfaces refer to the outer surfaces of the housing 10 on both sides or in the front and back directions to accommodate the installation requirements of cooling chips 21 of different sizes.

[0078] Specifically, the three-dimensional structure of the raised mounting position 10c allows for multi-point contact between the cooling therapy unit and the breast surface, increasing the efficiency of cold transfer by increasing contact pressure. The edge contour of the raised mounting position 10c conforms to the curve of the breast, deforming under pressure to expand the contact area. The cooling therapy unit and the raised mounting position 10c are embedded and fixed, for example, by snaps or adhesives, ensuring no displacement during cooling. The height difference of the raised mounting position 10c creates a vertical spatial separation between the cooling therapy unit and other therapy units, blocking the heat transfer path and preventing temperature interference between the cooling area and the heating or vibration areas.

[0079] Through the above technical solution, the cold compress therapy unit of this application obtains stable positioning support through the raised mounting position 10c, improves the efficiency of cold transfer under contact pressure, and maintains its own temperature stability through spatial isolation. This structural design enables multiple therapy functions to work in parallel within a limited space, solving the problems of heat and cold cancellation and vibration transmission interference caused by the planar layout of traditional equipment.

[0080] Please see Figures 1 to 4 This application further proposes that there are multiple protruding mounting positions 10c, which are arranged on the surface of the housing 10, and each protruding mounting position 10c is provided with a cold compress therapy section.

[0081] In this embodiment, the arrangement of multiple protruding mounting positions 10c on the surface of the housing 10 refers to the distribution of multiple protruding mounting positions 10c at preset intervals in the area where the housing 10 contacts the breast, such as in a matrix arrangement or a ring distribution. Their function is to adapt the spatial layout to the curved shape of the breast, ensuring that the cold compress application points effectively adhere to the skin in different areas. Through the above technical solution, this application can expand the cold compress application range to multiple target areas of the breast, achieving precise cold compresses with independent temperature control at multiple points. Simultaneously, the spaced arrangement of the protruding mounting positions 10c suppresses the diffusion of cold energy, ensuring that each cold compress treatment area operates stably without interference.

[0082] Multiple raised mounting positions 10c are spaced apart on the surface of the housing 10, such as the top and sides. Each position independently mounts the cold end of the cooling element 21, allowing different areas of the breast to receive cold compresses simultaneously. The hot ends of the cooling elements 21 are all inserted into a common ventilation path 10f. A fan 222 drives airflow to draw heat in through the air inlet 10d and expel it through the heat dissipation hole 10e, achieving centralized heat processing from multiple cooling elements 21. The design of each raised mounting position 10c connected to the ventilation path 10f allows the low temperature generated by the cold end to be directly conducted to the human body, while the heat from the hot end is uniformly discharged, avoiding local heat accumulation that could affect cooling efficiency.

[0083] Specifically, multiple protruding mounting positions 10c form discretely distributed cooling application points on the surface of the housing 10. Each protruding mounting position 10c has an independently set cooling therapy section that generates low temperature through the cooling plate 21 and transfers the cold energy to the contact surface of the protruding mounting position 10c through the heat-conducting layer.

[0084] In some specific embodiments, the raised mounting position 10c can be wrapped with a metal heat-conducting plate using flexible silicone material to enhance the comfort of contact with the skin; the cooling pad 21 of the cold compress therapy section can be independently connected to the control circuit to achieve differentiated temperature adjustment for different raised mounting positions 10c.

[0085] Please see Figures 1 to 4 This application further proposes that the cold compress therapy section is located at one end of the housing 10.

[0086] In this embodiment, one end of the housing 10 refers to the distal portion of the overall structure of the housing 10, away from the central region. When the cold compress therapy unit is positioned in the distal region of the housing 10, it forms a clear spatial separation from the hot compress or vibration therapy units in other areas of the housing 10. This positioning design reduces the possibility of temperature conduction or mechanical vibration transmission by increasing the physical distance between the cold compress area and other therapy areas. For example, when the hot compress therapy unit is located in the middle of the housing 10, the cold compress therapy unit operates independently at the distal end, and the structure of the housing 10 between them can block the heat diffusion path; when the vibration therapy unit is located on the other side of the housing 10, the cold compress therapy unit at the distal end is not affected by vibration conduction. Thus, different therapy functions are spatially isolated, avoiding a decrease in therapy effect caused by temperature or mechanical interference.

[0087] This solution eliminates cross-interference between different therapeutic functions by independently placing the cold compress therapy section at the end of the housing 10 and using the structure of the housing 10 itself to form an isolation barrier.

[0088] Please see Figures 1 to 5 This application further proposes that the housing 10 also has an air inlet 10d and a heat dissipation hole 10e that connect to the external environment, and a ventilation path 10f is formed between the air inlet 10d and the heat dissipation hole 10e; the heat dissipation module 22 includes a heat sink 221 and a fan 222, the heat sink 221 is connected to the cooling chip 21, and both the heat sink 221 and the fan 222 are located in the ventilation path 10f, and the fan 222 is used to dissipate the heat of the heat sink 221 to the external environment.

[0089] In this embodiment, the air inlet 10d refers to the airflow inlet on the surface of the housing 10, which can be implemented using a circular array of holes or a strip grille structure, used to introduce external air to form an airflow circulation. The heat dissipation hole 10e refers to the airflow outlet on the surface of the housing 10, which can be implemented using a perforated structure symmetrically distributed with the air inlet 10d, together with the air inlet 10d defining the airflow direction. The ventilation path 10f refers to the airflow channel from the air inlet 10d to the heat dissipation hole 10e, which can be implemented using a combination of internal cavities and flow guiding structures in the housing 10, forming a heat exchange space independent of the physiotherapy area. The heat sink 221 refers to a heat-conducting component with an expanded surface area, which can be implemented using an aluminum fin structure, improving heat dissipation efficiency by increasing the contact area with the airflow. The fan 222 refers to an active airflow drive device, which can be implemented using an axial fan or a centrifugal fan, accelerating heat dissipation through forced convection.

[0090] Specifically, when the cooling element 21 operates, the heat generated is conducted to the ventilation path 10f through the heat sink 221. When the fan 222 starts, it creates negative pressure, drawing in outside air through the air inlet 10d and flowing over the surface of the heat sink 221. After absorbing its heat, the air forms a high-temperature airflow, which is ultimately exhausted to the outside of the device through the heat dissipation hole 10e. During this process, the ventilation path 10f completely isolates the heat dissipation area from the treatment area of ​​the breast that is in contact with the housing 10, preventing heat conduction through the housing 10 from affecting the cooling effect. The synergistic effect of the heat sink 221 and the fan 222 creates a directional heat flow, ensuring that the temperature of the hot end of the cooling element 21 remains below the critical value. The physical separation design of the internal space of the housing 10 ensures that the mechanical energy generated by the vibration module does not interfere with the airflow within the ventilation path 10f.

[0091] Compared to existing technologies, traditional devices typically place heat dissipation components and physiotherapy components within the same cavity, leading to heat circulation as the heat dissipation airflow mixes with the internal air. This solution achieves directional heat dissipation by constructing an independent ventilation path 10f, eliminating heat retention within the device and effectively isolating heat exchange between the heat dissipation process and the cold compress physiotherapy area. This prevents heat generated by the cooling element 21 from being conducted to the contact surface through the housing 10. The efficient operation of the heat dissipation module 22 reduces heat accumulation inside the device, providing a more stable working environment for the vibration massage module. The functional zoning design of the housing 10 fundamentally solves the problem of mutual interference when multiple physiotherapy functions are used concurrently.

[0092] Please see Figures 1 to 5 This application further proposes that the heat dissipation module 22 also includes a duct shell 223 installed in the housing 10, the duct shell 223 being connected to the hot end of the cooling chip 21; the duct shell 223 is connected to the air inlet 10d and the heat dissipation hole 10e, forming a ventilation path 10f; the outer wall of the fan 222 is sealed against the inner wall of the duct shell 223 to drive fresh air to flow sequentially from the air inlet 10d, the ventilation path 10f and the heat dissipation hole 10e.

[0093] In this embodiment, the air duct shell 223 refers to a specific structural component installed inside the housing 10. It can be made of a material with certain strength and heat resistance, such as aluminum alloy, to ensure it can withstand the impact of airflow and heat transfer. Through precise machining, it achieves a tight connection with the hot end of the cooling chip 21, thereby efficiently transferring the heat generated by the hot end of the cooling chip 21 into the air duct shell 223. The shape and size of the air duct shell 223 can be optimized according to the internal space and heat dissipation requirements of the housing 10. Its internal structure corresponds to the air inlet 10d and the heat dissipation hole 10e, together forming a complete ventilation path 10f, providing a stable channel for the orderly flow of airflow.

[0094] As the core component driving airflow, the fan 222 features a sealed connection between its outer wall and the inner wall of the duct housing 223. This sealing is achieved through methods such as installing rubber sealing rings and applying sealant, ensuring that airflow does not leak from the gap between the fan 222 and the duct housing 223 during operation, thus guaranteeing that the airflow follows a predetermined path. When the fan 222 starts, the negative pressure it generates acts on the air inlet of the ventilation path 10f, causing fresh air from the outside to continuously flow in through the air inlet 10d. Subsequently, the airflow flows smoothly along the ventilation path 10f constructed by the duct housing 223, passing sequentially through the air inlet 10d, the ventilation path 10f, and the heat dissipation hole 10e, ultimately expelling the high-temperature gas that has absorbed heat to the outside of the equipment. This effectively improves the efficiency and accuracy of heat dissipation, ensuring that the heat generated by the cooling element 21 during operation can be dissipated in a timely manner, maintaining its optimal working condition.

[0095] This solution adds an air duct shell 223 inside the housing 10 and cleverly utilizes the sealed contact structure between the fan 222 and the air duct shell 223 to construct an independent and efficient ventilation and heat dissipation channel, allowing fresh air to flow in an orderly manner and carry away heat, greatly enhancing the performance of the heat dissipation module 22 and providing a strong guarantee for the stable operation of the entire equipment.

[0096] Optionally, the duct housing 223 has a mounting port communicating with the protruding mounting position 10c and the ventilation path 10f. A mounting baffle is provided around the periphery of the mounting port. The cooling element 21 is mounted on the protruding mounting position 10c and fixedly secured to the mounting baffle. The mounting port refers to the opening area of ​​the duct housing 223 that communicates with the external structure. Specifically, it can be implemented using a rectangular or circular through-hole structure. This opening penetrates the space between the ventilation path 10f and the protruding mounting position 10c, forming a docking relationship with the cooling element 21. The mounting baffle refers to a protruding structure extending around the edge of the mounting port. Specifically, it can be implemented using injection-molded annular ribs. This structure mechanically constrains the installation position of the cooling element 21. The fixing refers to restricting the spatial freedom of the cooling element 21 through a rigid contact surface. Specifically, it can be achieved by an interference fit between the inner wall of the baffle and the outer edge of the cooling element 21, so that the cooling element 21 is completely constrained in the vertical direction.

[0097] During installation, the cooling plate 21 is first placed on the raised mounting position 10c and then fixed in place by the mounting baffle. The shape and size of the mounting baffle match the shape of the cooling plate 21, ensuring that the cooling plate 21 is effectively constrained in all directions. In addition, the design of the mounting port facilitates the disassembly and replacement of the cooling plate 21. When the cooling plate 21 needs maintenance or replacement, it can be easily removed by simply loosening the mounting baffle, making the operation simple and quick.

[0098] Please see Figures 1 to 5This application further proposes that the exhaust side of the fan 222 is positioned toward the heat sink 221.

[0099] In this embodiment, the exhaust side refers to the side where the fan 222 exits air. Specifically, it can be implemented using the exhaust port of an axial or centrifugal fan, and its function is to guide the airflow directionally to the surface of the heat sink 221. Specifically, the airflow generated by the fan 222 acts directly on the surface of the heat sink 221 from the exhaust side, flowing along the surface of the heat sink 221 and carrying away heat. Because the exhaust side of the fan 222 and the heat sink 221 form a directional convection path, the heat absorbed by the heat sink 221 is forcibly discharged to the external environment, preventing heat accumulation inside the device. The contact efficiency between the surface of the heat sink 221 and the air is improved through the directional flow of air, and the heat generated at the hot end of the cooling element 21 is continuously dissipated, thereby reducing thermal interference to the cold compress therapy area.

[0100] This solution adjusts the orientation of the exhaust side of the fan 222 to concentrate the airflow onto the surface of the heat sink 221, thereby enhancing the synergistic heat dissipation capability of the heat sink 221 and the fan 222 and resolving the mutual interference problem caused by insufficient heat dissipation in multiple physiotherapy modules.

[0101] Please see Figures 1 to 5 Furthermore, this application proposes that the housing 10 is configured with a curved body structure, and the bottom of the housing 10 is a concave side of the curved body structure, with the second physiotherapy part 10b located on the concave side.

[0102] In this embodiment, the curved structure refers to the ergonomic, non-planar shape of the housing 10, which can be achieved using a combination of single and composite curved surfaces. This structure adapts to the curves of the human body, creating a uniform pressure distribution when the device contacts the skin. The recessed side refers to the inward bending of the bottom of the housing 10 to form a receiving space, which can be achieved through a groove structure formed by injection molding. This recessed area provides an independent mounting position for the second physiotherapy unit 10b, avoiding spatial overlap with other functional modules. The second physiotherapy unit 10b refers to a physiotherapy component with cooling, heating, or vibration functions, which can be implemented using components such as a semiconductor cooling chip 21, an electrothermal film, or a micro-vibration motor. This component, through the physical isolation layout of the recessed side, blocks the heat conduction or mechanical vibration transmission paths with other physiotherapy units.

[0103] Specifically, the curved shell 10, through its curvature, forms a matching contact with the contour of the human breast, and the independent space formed on the concave side physically separates the second therapy unit 10b from other functional modules. When the device is running, the cooling or heating generated by the second therapy unit 10b on the concave side is confined to its area, while the continuous surface of the curved structure prevents direct contact between different therapy units. This spatial separation mechanism allows the cooling and massage functions to operate simultaneously without thermal interference or mechanical interference, while the curved structure itself improves wearing comfort by dispersing contact pressure.

[0104] This solution combines a curved shell 10 with a recessed side structure to achieve three-dimensional spatial separation of the physiotherapy functions while maintaining the overall compactness of the device. The optimized shape of the shell 10 creates independent operating spaces for the functional modules, preventing the cancellation of physiotherapy effects caused by temperature conduction. Simultaneously, the curved structure enhances the fit with human tissue, reducing physiotherapy positioning deviations caused by device displacement.

[0105] Please see Figures 1 to 5 This application further proposes that one of the first physiotherapy section 10a and the second physiotherapy section 10b is a cold compress physiotherapy section, and the other of the first physiotherapy section 10a and the second physiotherapy section 10b is a massage physiotherapy section 40.

[0106] In this embodiment, the massage therapy unit 40 refers to a component that achieves massage function through mechanical vibration. The physically isolated functional partition means that the cold compress therapy unit and the massage therapy unit 40 are respectively arranged in different areas of the housing 10 to avoid the mutual conduction of heat and mechanical vibration during their operation.

[0107] Specifically, the cooling therapy section and the massage therapy section 40 are respectively positioned independently on the housing 10. The cooling energy generated by the cooling pad 21 during operation is transferred to the contact surface through a local area of ​​the housing 10, while the mechanical vibration generated by the vibration motor 41 is transferred to another area of ​​the housing 10 through the conductive adhesive 42. Because the cooling and massage functions are spatially separated, the heat generated during the heat dissipation process of the cooling pad 21 will not be conducted to the area where the vibration motor 41 is located through the housing 10, and at the same time, the mechanical vibration of the vibration motor 41 will not interfere with the heat dissipation efficiency of the cooling pad 21. Thus, the low-temperature environment required for cooling and the vibration action required for massage can operate synchronously without interference.

[0108] After the cold compress therapy unit is embedded with the raised structure, its cold end surface can directly act on the skin tissue. The massage therapy unit 40 operates in another area within the housing 10, and the mechanical energy it generates is conducted to the contact surface through the housing 10, forming a functional zone with the cold compress therapy unit. This layout allows the cold compress and massage functions to operate independently in space, while also achieving operational integration through the unified housing 10.

[0109] This solution employs a physically isolated functional partition design, ensuring that the cooling and massage modules are completely independent in spatial layout, fundamentally eliminating interference between the two therapy modes. This guarantees the stability of the cooling temperature and the regularity of the massage movements, thereby improving the therapeutic effect and user comfort.

[0110] Optionally, the massage therapy unit 40 can employ a variety of different massage techniques, such as vibration massage, kneading massage, and electrical stimulation massage, to meet the needs of different users.

[0111] Optionally, the massage therapy unit 40 is connected to the housing 10 by a special shock-absorbing structure. This shock-absorbing structure can effectively absorb the vibration energy generated during the movement of the massage therapy unit 40, and prevent the vibration from being transmitted to other parts of the housing 10, thereby improving the user's comfort.

[0112] Please see Figures 1 to 5 This application further proposes that the massage therapy unit 40 includes a vibration motor 41 and a conductive rubber component 42. The vibration motor 41 is installed inside the housing 10. One end of the conductive rubber component 42 is connected to the output shaft of the vibration motor 41, and the other end of the conductive rubber component 42 is connected to the housing 10 for transmission. The vibration motor 41 is used to drive the conductive rubber component 42 to vibrate, so that the conductive rubber component 42 drives the housing 10 to vibrate, so as to perform a massage operation on the breast.

[0113] In this embodiment, the vibration motor 41 refers to a power element that converts electrical energy into mechanical vibration energy. Specifically, it can be implemented using a miniature eccentric rotor motor, which generates periodic centrifugal force through its output shaft. The conductive rubber component 42 refers to a flexible transmission component with elastic deformation capability. Specifically, it can be made of silicone or rubber into a columnar or sheet-like structure, which achieves directional transmission of vibration energy by connecting the vibration source and the load end at both ends.

[0114] Specifically, the vibration motor 41 is fixed in an independent mounting position within the cavity of the housing 10, and its output shaft is physically connected to one end of the conductive adhesive component 42 via a rigid connection or snap-fit. The other end of the conductive adhesive component 42 is connected to the inner wall of the housing 10 via an interference fit or adhesive bonding. When the vibration motor 41 is started, the high-frequency vibration generated by the output shaft is converted into low-frequency vibration waves through the elastic deformation of the conductive adhesive component 42. The material damping characteristics of the conductive adhesive component 42 can absorb some of the high-frequency harmonic energy, reducing the resonance effect on the housing 10. Under the traction of the conductive adhesive component 42, the housing 10 produces local reciprocating motion, which is restricted to the second physiotherapy section 10b region on the concave side of the bottom of the housing 10, while the top region of the housing 10 where the cold compress physiotherapy section is located remains stationary due to the physical isolation of the vibration transmission path.

[0115] This solution uses the flexible transmission design of the conductive adhesive component 42 to add an energy attenuation link in the vibration transmission path, so that the vibration energy is confined to a specific area. At the same time, the physical isolation between the bottom recessed side and the top area of ​​the housing 10 achieves spatial decoupling of the cooling and massage functions.

[0116] In another embodiment of this application, the massage therapy unit 40 is a kneading massage component. This component includes a kneading part capable of performing kneading actions on the breast, thus providing greater stimulation, relieving pain, and achieving a better massage effect. Specifically, the kneading massage component may include a motor and a massage wheel. The massage wheel is rotatably mounted on the housing 10. The motor drives the massage wheel to rotate, causing it to form the kneading part. The side of the massage wheel abuts against the breast, rolling on the breast to perform the kneading action. Alternatively, the kneading massage component may also include a motor, a cam transmission mechanism, and a deflection structure. The motor drives the cam transmission mechanism to rotate, thereby causing the deflection structure to deflect and oscillate. The deflection structure forms the kneading part, abutting against the breast and performing squeezing and friction to achieve the kneading action. In other words, the kneading massage component is a mechanical massage; the kneading part refers to a structure capable of displacement relative to the housing 10, achieving the kneading action through squeezing and friction on the breast.

[0117] In another embodiment, the massage therapy unit 40 is an electrical stimulation massage component, which includes electrical stimulation electrodes that can transmit electrical stimulation to the breast. In this way, by applying pulsed current to the breast, the blood circulation of the breast can be accelerated, which can relieve breast pain. Electrical stimulation can avoid mechanical damage and prevent damage to the breast skin, making it safer and more comfortable.

[0118] It is worth noting that in this embodiment, the breast massage device also includes a control module. The control module uses a PCB board and control buttons for a power button, a cooling button, a heating button, and a massage button, all electrically connected to the PCB board. The PCB board is electrically connected to the massage therapy unit 40, the cooling device 20, and the heating device 30. These control buttons are located on the surface of the housing 10. Users can activate different therapy functions using the control buttons for the cooling, heating, and massage buttons, allowing for targeted selection. Specifically, when a user presses the cooling, heating, or massage button, the PCB board receives the corresponding electrical signal and sends a control command to the massage therapy unit 40, the cooling device 20, or the heating device 30, causing the massage therapy unit 40, the cooling device 20, or the heating device 30 to perform therapy under the control command.

[0119] Users can press one of the control buttons in the cooling device 20, heating device 30, and massage therapy section 40 to perform a single therapy function; alternatively, users can press two or more control buttons simultaneously to perform therapy on multiple therapy sections at the same time, allowing for targeted selection. The cooling button cools one surface of the breast massage device. The heating button heats one surface of the breast massage device. The massage button vibrates the breast massage device in a relatively gentle manner so that users can apply massage to the breasts.

[0120] The breast massage device also includes a power module housed within the casing 10. The power module is electrically connected to the massage therapy unit 40, the cooling device 20, the heating device 30, and the control module, providing power to these components. The power module is a battery, which supplies power to the massage therapy unit 40, the cooling device 20, the heating device 30, and the control module, allowing the breast massage device to operate without mains power, making it more convenient. More specifically, the battery is a rechargeable battery, and the breast massage device has a charging port for charging. Compared to using disposable batteries, this is more economical and environmentally friendly, while ensuring sufficient power output and supply.

[0121] In another embodiment, the control module uses a PCB board and a power button and a function knob electrically connected to the PCB board. Users can select the cold compress function, hot compress function, or massage function by rotating the function knob.

[0122] In another embodiment, the control module may also use a PCB board and an interactive screen electrically connected to the PCB board. The interactive screen displays virtual buttons for cold compress function, hot compress function, or massage function. Users can select the corresponding physiotherapy section to perform physiotherapy through the virtual buttons for cold compress function, hot compress function, or massage function on the interactive screen.

[0123] If this breast massage device includes a cooling device 20, a heating device 30, and a massage therapy section 40, the cooling device 20, the heating device 30, and the massage therapy section 40 can be integrated on the three contact surfaces of the housing 10 respectively, to prevent the heat and mechanical vibration of the three devices from being conducted to each other during operation. If this breast massage device includes two of the cooling device 20, the heating device 30, and the massage therapy section 40, the two devices can also be integrated on the two contact surfaces of the housing 10 respectively.

[0124] Breast massage devices also include a data port, which can be a micro USB or mini USB port. Other connection interfaces may also be implemented. The data port enables data transmission and reception. For example, the breast massage device can be controlled via the data port using external devices (such as smartphones, tablets, smartwatches, laptops, or desktop computers). Furthermore, the breast massage device can output treatment data to external devices, such as the type of treatment applied, the duration of treatment, and treatment-related statistics, such as the applied temperature or the current / voltage applied via EMS or TENS.

[0125] In another embodiment, the breast massage device does not include a data port, but instead has a wireless communication module electrically connected to the control module within the housing. The user can send control signals to the control module via the wireless communication module, which can be Bluetooth, NFC, or Wi-Fi.

[0126] In summary, the breast massage device provided by this utility model, through its innovative design and structural layout, organically combines multiple functions such as cold compress, hot compress, and massage. This breast massage device not only effectively relieves breast pain and discomfort and promotes blood circulation in the breasts, but also provides users with a more comprehensive and comfortable care experience. The coordinated work between its various components ensures the stability and reliability of the entire breast massage device during use, giving it broad application prospects and market value.

[0127] The above description is merely an exemplary embodiment of the present utility model and does not limit the patent scope of the present utility model. Any equivalent structural transformations made based on the technical concept of the present utility model and the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included within the patent protection scope of the present utility model.

Claims

1. A breast massage device for applying therapeutic functions to the breast, characterized in that, The breast massage device includes: The housing includes at least two contact surfaces that apply physical therapy to the breast, namely a first contact surface and a second contact surface; The first contact surface includes a first physiotherapy section, and the second contact surface includes a second physiotherapy section; At least one of the first physiotherapy unit and the second physiotherapy unit is a cold compress physiotherapy unit, used to apply cold compress physiotherapy to the breast; The first contact surface and the second contact surface are located in two different orientations of the housing so that when the first physiotherapy unit and the second physiotherapy unit perform physiotherapy functions at the same time, they do not interfere with each other.

2. The breast massage device as described in claim 1, characterized in that, The first physiotherapy section is a cold compress physiotherapy section, and the second physiotherapy section is a hot compress physiotherapy section.

3. The breast massage device as described in claim 2, characterized in that, The breast massage device includes a cooling device, which is disposed inside the housing and connected to the cold compress therapy section; the breast massage device also includes a heating device, which is disposed inside the housing and connected to the hot compress therapy section.

4. The breast massage device as described in claim 3, characterized in that, The cooling device includes a cooling plate and a heat dissipation module. The cooling plate is attached to the housing and connected to the cold compress therapy part. The heat dissipation module is connected to the end of the cooling plate away from the cold compress therapy part and is used to dissipate the heat generated by the cooling plate.

5. The breast massage device as described in claim 3, characterized in that, The heating device includes: A heating outer shell, wherein the heating outer shell is connected to the housing and spaced apart from the cooling device; and A heating element is disposed between the inner wall of the heat-conducting outer shell and the shell, and is used to provide heat to the heat-conducting outer shell.

6. The breast massage device as described in claim 1, characterized in that, The first contact surface and the second contact surface are located on two surfaces of the housing spacer.

7. The breast massage device as described in claim 2, characterized in that, A heat insulation structure is provided between the hot compress therapy section and the cold compress therapy section, and the heat insulation structure is used to separate the hot compress therapy section and the cold compress therapy section.

8. The breast massage device as described in claim 1, characterized in that, The first contact surface is provided with a raised mounting position, and the raised mounting position is provided with a cold compress therapy part.

9. The breast massage device as described in claim 8, characterized in that, The number of the protruding mounting positions is multiple, and the multiple protruding mounting positions are arranged on the surface of the housing. Each of the protruding mounting positions is provided with a cold compress therapy section.

10. The breast massage device as described in claim 1, characterized in that, The cold compress therapy unit is located at one end of the housing.

11. The breast massage device as described in claim 4, characterized in that, The housing also has an air inlet and a heat dissipation hole that connect to the external environment, and a ventilation path is formed between the air inlet and the heat dissipation hole; The heat dissipation module includes a heat sink and a fan. The heat sink is connected to the cooling chip, and both the heat sink and the fan are located in the ventilation path. The fan is used to dissipate the heat from the heat sink to the external environment.

12. The breast massage device as described in claim 11, characterized in that, The heat dissipation module also includes a duct shell installed inside the housing, the duct shell being connected to the hot end of the cooling chip; the duct shell is connected to the air inlet and the heat dissipation hole, forming the ventilation path; the outer wall of the fan is sealed against the inner wall of the duct shell to drive fresh air to flow sequentially from the air inlet, the ventilation path and the heat dissipation hole.

13. The breast massage device as described in claim 11, characterized in that, The exhaust side of the fan is positioned facing the heat sink.

14. The breast massage device as described in claim 2, characterized in that, The housing is configured as a curved body structure, and the bottom of the housing is the concave side of the curved body structure, with the second physiotherapy unit located on the concave side.

15. The breast massage device as described in claim 1, characterized in that, One of the first physiotherapy section and the second physiotherapy section is the cold compress physiotherapy section, and the other of the first physiotherapy section and the second physiotherapy section is the massage physiotherapy section.

16. The breast massage device as described in claim 15, characterized in that, The massage therapy department includes: A vibration motor, the vibration motor being installed within the housing; and A conductive rubber component, one end of which is connected to the output shaft of the vibration motor, and the other end of which is connected to the housing in a transmission connection; The vibration motor is used to drive the conductive rubber component to vibrate, so that the conductive rubber component drives the housing to vibrate, thereby performing a massage operation on the breast.