Intelligent warming and warm-keeping home cotton boots
By introducing a heating module and intelligent temperature regulation system into the cotton boots, the problems of limited warmth retention and bulkiness of existing cotton boots have been solved, achieving intelligent heating and warmth retention, and improving comfort and safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHEJIANG GEMEIQI SHOES IND CO LTD
- Filing Date
- 2025-04-21
- Publication Date
- 2026-07-07
AI Technical Summary
When existing cotton boots are made to improve their warmth by adding thicker padding or insulating materials, the boots become bulky, affecting wearing comfort and limiting their warmth retention.
It adopts a heating module, including heating elements and electrical connecting wires, combined with a temperature sensor and control module, to achieve intelligent heating adjustment through power supply. It utilizes the high thermal conductivity and electrical conductivity of carbon fiber or graphene materials, combined with a waterproof and wear-resistant outer layer and a skin-friendly inner layer, to achieve intelligent temperature rise and warmth preservation.
It improves warmth retention, enhances wearing comfort, reduces the bulkiness of the shoes, has a temperature self-regulating function, reduces the risk of burns, and improves safety and ease of use.
Smart Images

Figure CN224461178U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the technical field of cotton boots, and in particular to a smart, warm-insulating home cotton boot. Background Technology
[0002] Cotton boots are a type of footwear that typically have an inner lining made of animal fur and cotton fibers. They provide excellent warmth and are suitable for wearing in cold winters, offering warmth and comfort and reducing the likelihood of frostbite.
[0003] In related technologies, cotton boots mainly improve their warmth by thickening the filling or using insulating materials, but this can easily lead to bulky shoes, affect wearing comfort, and have limited warmth retention, so improvements are needed. Utility Model Content
[0004] To improve the warmth retention of cotton boots, this application provides a smart heating and warmth-retaining home cotton boot.
[0005] The intelligent heating and warmth-insulating home cotton boots provided in this application adopt the following technical solution:
[0006] A smart, heated, and warm indoor cotton boot includes a shoe body, which includes a sole and an upper. A heating module is provided in the shoe body. The heating module includes a heating element and a wire electrically connected to the heating element. The wire is connected to a power source. Both the sole and the upper include an outer layer, a middle layer, and an inner layer. The outer layer is made of a waterproof and wear-resistant material. The middle layer includes a heat-insulating filling layer. The inner layer is made of a skin-friendly fabric. The heating element is evenly distributed in the inner layer.
[0007] By adopting the above technical solution, when using these cotton boots, simply insert your foot into the shoe and then connect the power cord. The heating element will then heat up, raising the temperature inside the shoe. The insulating filling layer prevents heat from escaping from the shoe to the outside, the skin-friendly inner fabric enhances wearing comfort, and the waterproof and abrasion-resistant outer material protects the heating module from moisture or damage, extending the lifespan of the cotton boots. Compared to increasing warmth through thicker filling, this method avoids making the shoes bulky, resulting in greater wearing comfort. The heating element provides continuous heat after being powered on, further enhancing the boots' warmth.
[0008] Optionally, the device also includes a temperature sensor and a control module disposed in the shoe body. The temperature sensor is disposed in the inner layer, and the control module is electrically connected to both the heating module and the temperature sensor. The control module is used to adjust the power of the heating module according to the feedback signal from the temperature sensor.
[0009] By adopting the above technical solution, when wearing these cotton boots, the temperature sensor monitors the temperature inside the shoe in real time and transmits the temperature data to the control module. The control module adjusts the efficiency of the heating module according to the temperature inside the shoe. When the temperature inside the shoe is too low, the control module increases the power of the heating module to raise the temperature inside the shoe; when the temperature inside the shoe is too high, the control module reduces the power of the heating module to lower the temperature inside the shoe, reducing the risk of burns caused by excessively high temperatures inside the shoe.
[0010] Optionally, the control module includes a display screen and adjustment buttons, and the outer layer of the shoe upper near the heel has mounting holes for the display screen and adjustment buttons to extend out of the shoe body.
[0011] By adopting the above technical solution, when wearing these cotton boots, users can adjust the required heating temperature by adjusting the buttons. The display screen can show the real-time temperature inside the shoe and the preset heating temperature, thereby realizing real-time adjustment and monitoring of the temperature inside the shoe according to changes in ambient temperature, making it easy to operate.
[0012] Optionally, the heating element is made of carbon fiber material.
[0013] By adopting the above technical solution, carbon fiber material has the characteristics of high electrothermal conversion efficiency, good electrical conductivity, good thermal conductivity and long service life. It can make the heating element heat up evenly. When carbon fiber is working, it emits far-infrared rays. The human body has a high absorption rate of far-infrared rays, which makes the heat loss of the heating element less and the foot comfort high.
[0014] Optionally, the heating element is made of graphene material.
[0015] By adopting the above technical solutions, graphene materials have the characteristics of high thermal conductivity and strong durability, which improves the service life of the heating element, reduces heat loss, and achieves high efficiency and energy saving.
[0016] Optionally, the temperature sensor is a DS18B20 digital temperature sensor.
[0017] By adopting the above technical solution, the DS18B20 digital temperature sensor has the characteristics of small size, strong anti-interference ability, high accuracy and low power consumption. Its small size and placement in the inner layer make it more comfortable for the foot to wear. It can accurately measure the temperature inside the shoe, which makes it easy for the control module to adjust the power of the heating module in real time.
[0018] Optionally, the control module uses an STM32F103 microprocessor.
[0019] By adopting the above technical solution, the STM32F103 microprocessor has the characteristics of supporting multi-channel signal processing and high-precision control. It can simultaneously process the temperature information of the inner side of the shoe transmitted by the temperature sensor and control the heating power of the heating module, making the response speed of the control module and the heating module fast.
[0020] Optionally, the middle layer of the sole is provided with several pressure sensors electrically connected to the control module. The pressure sensors are used to monitor the pressure distribution of the user's foot on various parts of the shoe, so that the control module can realize zoned heating according to the pressure distribution.
[0021] By adopting the above technical solution, when the foot is inserted into the shoe, the pressure sensor detects the pressure in various areas of the shoe and transmits the pressure distribution data to the control module. The control module then adjusts the power of the heating module according to the pressure distribution in each area. The power of the heating element in areas of high pressure is reduced, preventing burns when the foot applies excessive pressure to the shoe, i.e., when in close contact with the shoe. Conversely, the power of the heating element in areas of low pressure is increased, allowing heat to be transferred to the foot through the air, ensuring sufficient heat even when the foot is not in close contact with the shoe. This method of adjusting the heating power ensures even heating of all parts of the foot, reducing the risk of localized burns and improving the safety of wearing cotton boots.
[0022] Optionally, the outer layer of the shoe upper is provided with a charging port for connecting to a power source, and the charging port is electrically connected to the heating module, temperature sensor and control module.
[0023] By adopting the above technical solution, when using cotton boots for warmth, simply insert your feet into the boot and then connect the power supply to the charging port. This will power on the heating module, temperature sensor, and control module, causing the temperature inside the boot to rise and heat your feet.
[0024] Optionally, the charging port is electrically connected to a power storage module, which is electrically connected to the heating module, temperature sensor, and control module.
[0025] By adopting the above technical solution, when it is necessary to walk in the cotton boots, the power supply can be disconnected from the charging port, and walking can proceed. At this time, the energy storage module will supply power to the heating module, temperature sensor, and control module, allowing the cotton boots to heat the feet even when the power is disconnected, without having to be constantly connected to the power source, thus improving the convenience of using the cotton boots. When the charging port is connected to the power source, it will charge the energy storage module, preparing for the next power supply.
[0026] In summary, this application includes at least one of the following beneficial technical effects:
[0027] 1. The shoe body is heated by a heating module, which raises the internal temperature of the shoe body and thus keeps the feet warm without the need to thicken the shoe body's padding, improving the comfort and warmth when wearing the shoe;
[0028] 2. The temperature sensor can monitor the temperature inside the shoe in real time, so that the control module can adjust the power of the heating module in a timely manner, which increases the applicable temperature range of the cotton boots and improves the safety factor of the cotton boots. Attached Figure Description
[0029] Figure 1 This is an overall structural diagram of Embodiment 1 of this application.
[0030] Figure 2 This is a cross-sectional structural diagram of Embodiment 1 of this application.
[0031] Explanation of reference numerals in the attached figures:
[0032] 1. Shoe body; 11. Shoe sole; 111. Outer layer; 112. Mid-layer; 113. Inner layer; 12. Upper; 2. Heating module; 21. Heating element; 3. Temperature sensor; 4. Control module; 41. Display screen; 42. Adjustment button; 43. Mounting hole; 5. Pressure sensor; 6. Charging port; 7. Energy storage module. Detailed Implementation
[0033] The following is in conjunction with the appendix Figure 1-2 This application will be described in further detail.
[0034] This application discloses an intelligent heating and warming home cotton boot.
[0035] Example 1
[0036] Reference Figure 1 and Figure 2 A smart, heated, and warm indoor cotton boot includes a shoe body 1, which includes a sole 11 and an upper 12. Both the sole 11 and the upper 12 include an outer layer 111, a middle layer 112, and an inner layer 113. The outer layer 111 is made of waterproof and wear-resistant material, providing good moisture resistance and abrasion resistance. The middle layer 112 includes an insulating filling layer, and the inner layer 113 is made of skin-friendly fabric, directly contacting the foot. A heating module 2 is installed inside the shoe body 1, and a temperature sensor 3 is installed in the inner layer 113. The temperature sensor 3 is a 3DS18B20 digital temperature sensor, characterized by high accuracy and low power consumption.
[0037] Reference Figure 2The shoe body 1 houses a control module 4, which uses an STM32F103 microprocessor capable of supporting multi-channel signal processing and offering a fast response speed. The control module 4 includes a display screen 41 and adjustment buttons 42. The outer layer 111 has mounting holes 43 for the display screen 41 and adjustment buttons 42 to extend from the shoe body 1. The display screen 41 displays the real-time temperature inside the shoe body 1 and the preset heating temperature. The adjustment buttons 42 adjust the preset heating temperature, allowing the boot to adapt to changes in ambient temperature and maintain a comfortable temperature for the feet.
[0038] Reference Figure 2 The heating module 2 includes a heating element 21 and wires electrically connected to the heating element 21. The heating element 21 is evenly distributed in the inner layer 113 and is made of carbon fiber material. Carbon fiber material has good thermal conductivity and a long service life, extending the service life of the cotton boots. The wires are connected to a power source. The heating module 2 is electrically connected to the control module 4 and the temperature sensor 3. The control module 4 is used to adjust the power of the heating module 2 according to the feedback signal from the temperature sensor 3, so that the heating module 2 can adjust its heating power according to the actual use effect, improving the flexibility and adaptability of the heating module 2.
[0039] Reference Figure 2 The mid-layer 112 of the sole 11 is equipped with a pressure sensor 5 electrically connected to the control module 4. The pressure sensor 5 can detect the pressure distribution of the user's foot on various parts of the shoe body 1 and transmit the pressure distribution data to the control module 4. The control module 4 then adjusts the heating power of the heating elements 21 in different pressure areas according to the pressure distribution. In this way, the power of the heating elements 21 in the parts of the shoe body 1 that are under high pressure from the foot is reduced, thus reducing the risk of burns to the parts of the foot that are in close contact with the shoe body 1. The power of the heating elements 21 in the parts of the shoe body 1 that are under less pressure from the foot is increased, so that the foot that is not in close contact with the shoe body 1 can also receive sufficient heat, ensuring a warming effect.
[0040] Reference Figure 2 The outer layer 111 of the shoe upper 12 is provided with a charging port 6, which is electrically connected to the heating module 2, temperature sensor 3, and control module 4. The charging port 6 is used to connect to a power source and is electrically connected to a power storage module 7. The power storage module 7 is located on the outer layer 111 and is electrically connected to the heating module 2, temperature sensor 3, and control module 4. When the boots are not needed for walking, the power source connected to the charging port 6 supplies power to the boots; when walking is required, the power storage module 7 supplies power to the boots, improving the flexibility of using the boots.
[0041] The implementation principle of the intelligent heating and warming home cotton boots in this application embodiment is as follows: When using the cotton boots, first insert your foot into the shoe body 1, then connect the charging port 6 to an external power source. After the heating module 2 is powered on, the heating element 21 generates heat, thereby heating the foot. The temperature sensor 3 can monitor the temperature inside the shoe body 1 in real time, and the control module 4 adjusts the heating power of the heating module 2 according to the actual heating situation, ensuring a stable warming effect inside the shoe body 1. By using the above method to keep the foot warm, there is no need to thicken the padding, improving the comfort and warmth of the cotton boots.
[0042] Example 2
[0043] Reference Figure 2 The difference between this embodiment and Embodiment 1 is that the heating element 21 is made of graphene material.
[0044] The implementation principle of the intelligent heating and warming home cotton boots in this application embodiment is as follows: graphene material has the characteristics of high heating efficiency, good thermal conductivity and good durability, which makes the heating element 21 have a good heating effect and extends the service life of the heating element 21.
[0045] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.
Claims
1. A smart, warm-heating, and heat-insulating home cotton boot, comprising a shoe body (1), wherein the shoe body (1) comprises a sole (11) and an upper (12), characterized in that: The shoe body (1) is provided with a heating module (2), the heating module (2) includes a heating element (21) and a wire electrically connected to the heating element (21). The wire is connected to a power source. The sole (11) and the upper (12) both include an outer layer (111), a middle layer (112), and an inner layer (113). The outer layer (111) is made of waterproof and wear-resistant material. The middle layer (112) includes a heat-insulating filling layer. The inner layer (113) is made of skin-friendly fabric. The heating element (21) is evenly distributed in the inner layer (113). It also includes a temperature sensor (3) and a control module (4) disposed in the shoe body (1). The temperature sensor (3) is disposed in the inner layer (113). The control module (4) is electrically connected to both the heating module (2) and the temperature sensor (3). The control module (4) is used to adjust the power of the heating module (2) according to the feedback signal of the temperature sensor (3). The control module (4) includes a display screen (41) and an adjustment button (42). The outer layer (111) has a mounting hole (43) at the heel of the shoe upper (12) for the display screen (41) and the adjustment button (42) to extend out of the shoe body (1). The middle layer (112) of the sole (11) is provided with several pressure sensors (5) electrically connected to the control module (4). The pressure sensors (5) are used to monitor the pressure distribution of the user's foot on various parts of the shoe body (1) so that the control module (4) can realize zoned heating according to the pressure distribution.
2. The intelligent heating and warming home cotton boots according to claim 1, characterized in that: The heating element (21) is made of carbon fiber material.
3. The intelligent heating and warming home cotton boots according to claim 1, characterized in that: The heating element (21) is made of graphene material.
4. The intelligent heating and warming home cotton boots according to claim 1, characterized in that: The temperature sensor (3) is a digital temperature sensor (3) DS18B20.
5. The intelligent heating and warming home cotton boots according to claim 1, characterized in that: The control module (4) uses a microprocessor STM32F103.
6. The intelligent heating and warming home cotton boots according to claim 1, characterized in that: The outer layer (111) of the shoe upper (12) is provided with a charging port (6) for connecting to a power source. The charging port (6) is electrically connected to the heating module (2), the temperature sensor (3) and the control module (4).
7. The intelligent heating and warming home cotton boots according to claim 6, characterized in that: The charging port (6) is electrically connected to the energy storage module (7), which is electrically connected to the heating module (2), the temperature sensor (3), and the control module (4).