DESIGN STRUCTURE FOR GLOVE CAPABLE OF HEATING AROUND FINGERTIP

Abstract

A structure for gloves capable of heating around a fingertip. A heating harness is fastened to a fingertip of a glove through a cloth strip fixing structure. The glove includes a hand back portion and a palm portion. The heating harness is wrapped with insulating material, and sewn in the glove through a cloth casing and a sewn fabric edge. A width of both cloth strip and sewn fabric edge are selected for heating effect and wearing comfort. As an interface of an external power supply, a wiring point is disposed outside the glove, so that usage is simplified. In addition, the present disclosure further includes a temperature controller and a power input wire. A method is to wrap a heating harness and then sew, to ensure production efficiency and product quality. In the present disclosure, a fingertip is heated efficiently and accurately, so that warmth retention performance is improved.

Description

TECHNICAL FIELD

The present disclosure relates to the technical field of heating gloves, and in particular to a design structure for gloves capable of heating around a fingertip.

BACKGROUND

Heating gloves are special gloves with potential value and broad application space in many fields:

• • 1. Outdoor activities and winter sports: The heating gloves are ideal choices for winter outdoor activities and sports such as skiing, mountaineering, and hiking. The heating gloves can keep hands of people warm at an extreme low temperature, to improve the comfort and safety of the activities. For example, hands of a skier may easily become cold during long days of skiing, but the heating gloves can consistently provide the skier with warmth needed.
  • 2. Military and law enforcement applications: In the military and law enforcement fields, people need to work in cold environments. The heating gloves can provide additional warmth, and help to maintain the dexterity and functionality of hands. This is critical for performing precise operations and using weapons.
  • 3. Industry and workplaces: In industries that need to work in cold environments, such as refrigerating houses, food processing, and fisheries, the heating gloves can significantly improve working conditions and work efficiency. The heating gloves can help workers to prevent frostbite on hands while keeping the hands comfortable, to improve overall productivity and safety.
  • 4. Medical and health care: For people suffering from symmetrical asphyxia, arthritis or other diseases causing poor circulation in hands, the heating gloves can provide therapeutic warmth. The heating gloves can help to reduce pain, promote circulation, and improve overall health of the hands.

The heating gloves are integrated with heating elements to provide users with hand warmth in the cold environments. However, these ways to disposing the heating elements always show some disadvantages. As a result, the heating gloves have some shortcomings in comfort, durability, safety, and manufacturing costs.

Specifically, there are three ways to dispose heating elements of common heating gloves:

• • 1. Heating mode in which a heating wire body 100 is directly sewn onto non-woven fabrics 101 as shown in FIG. 1:
  • a: A heating piece 102 is formed by wiring the heating wire body 100 in a shape of five fingers, and then firmly sewing the heating wire body 100 onto the non-woven fabrics 101 in a sewing fixation manner, to form a heating piece 102 in a hand back.
  • b: In terms of fixation, five fingers of the heating piece 102 are sewed and fastened through a fingertip fixing piece 104 and an inner cotton layer 106 on the hand back, to ensure stability.
  • c: The heating wire body 100 is connected to an electronic wire 3, and simultaneously connected to a power wire 107 of a thermostat 105, to control heating and adjusting a temperature.

The advantages are as follows: Processing costs are lowest, and the heating piece is easy to mount on a glove.

The disadvantages are as follows: a: Small partial fixing is performed by a fixing piece. As a result, during wearing, heating pieces are overheated because of wrinkling, falling off, or overlapping. b: The heating wire is only fastened by sewing. As a result, during washing, the heating wire is easy to circle and not stable enough.

• • 2. Fingertip heating mode as shown in FIG. 2:
  • a: For the heating piece 102, the heating wire body 100 is sewn onto the non-woven fabrics 101 whose sizes are the same as that of fingertips, and an FPC element 107 is used as the electronic wire 3 and connected to the heating wire body 100.
  • b. Design is a fingertip heating method for sewing the heating wire body 100 onto a small area of the non-woven fabrics 101, using the FPC is used as an interface with the electronic wire.

The advantages are as follows: Fingers are peripheral blood vessels of a human body, and are ends of blood transportation. Therefore, fingertip heating is a good way to warm the hands.

The disadvantages are as follows: The fingertip heating method has a complex production process, high labor costs, and difficult quality control. Glove processing factories are difficulty to process, and failures are easy to occur.

• • 3. Five-fingers heating method as shown in FIG. 3 and FIG. 4:
  • a: The heating piece 102 has a structure similar to a sandwich. The heating wire body 100 is sandwiched between upper and lower layers of fabrics.
  • b: The upper and lower layers of fabrics each are laminated with a hot melt adhesive film, facing an intermediate heating wire body 100.
  • c: The heating wire 100 is disposed at an upper side of the lower layer of fabrics in a shape of five fingers, and then the upper layer of fabrics is covered at an upper side of the heating wire 100.
  • d: The hot melt adhesive films of the upper and lower layers of fabrics are fused with each other by hot pressing, and the heating wire body 100 is clamped and fastened between the upper and lower layers of fabrics, to form the heating piece 102 through the above steps.
  • e: The manufactured heating piece 102 is sewn onto cotton linings of the glove with threads along outer edges of five fingers of cotton linings of the hand back.

The advantages are as follows: Because the heating piece is sewn along the five fingers of the cotton linings of the gloves by sewing, the heating method is safe and reliable, heating is uniform, and a heating speed is fast.

The disadvantages are as follows: Heating pieces of five fingers of the hand back are sewn on the cotton lining of the hand back along the five fingers. As a result, during wearing, bending, holding or stretching of the fingers or hand palm are slightly affected, and not natural, and even dexterity is affected.

In conclusion, in the conventional technologies, the ways to disposing the heating elements of the heating gloves are significantly challenged in comfort, durability, safety, and manufacturing costs. Specifically, although costs of the heating method for directly sewing the heating piece onto the non-woven fabrics are low, the fixation is not stable enough and is prone to cause problems during wearing. Although the fingertip heating method can effectively provide warmth, the manufacturing process is complex, costs are high, and quality is difficulty to control. Although the five-fingers heating method is safe and reliable, and uniformly heating, dexterity and naturalness of the hands are affected because of the fixing method. Because of such problems, user experience of the heating gloves is reduced, and wide application of the heating gloves are limited in many fields.

Therefore, the technical problem to be solved by the present disclosure is to overcome shortcomings of existing heating gloves in terms of comfort, durability, safety, and manufacturing costs, provide a new improved design for a structure of the heating gloves to improve user experience, reduce manufacturing costs, and enhance durability and safety, and then to promote wider applications of the heating gloves in fields such as outdoor activities, military, industry, and medical care.

SUMMARY

Technical problems to be solved by the present disclosure is to provide a design structure for gloves capable of heating around a fingertip, to overcome shortcomings of heating gloves in terms of comfort, durability, safety, and manufacturing costs in the conventional technologies.

The technical solutions adopted by the present disclosure follows:

A design structure for gloves capable of heating around a fingertip includes a glove body, a heating wire, an electronic wire, and a cloth strip fixing structure, where the cloth strip fixing structure includes a cloth casing and a sewn fabric edge.

The glove body includes a hand back portion and a palm portion that are sewn at an outer edge.

The heating wire includes a heating wire that is wrapped with an insulating material, and an electronic wire that is connected to two ends of the heating wire.

The cloth casing is disposed at outer side of the heating harness, and the sewn fabric edge is fastened to a side of the cloth casing.

The heating harness is fastened in the glove body through the sewn fabric edge.

As a further solution of the present disclosure, the cloth strip fixing structure is formed by folding two long side edges of a cloth strip in half, and sewing is performed at a middle part of the folded cloth strip in a length direction, to form a cloth casing and a sewn fabric edge.

As a further solution of the present disclosure, a width of the cloth strip is greater than 8 mm and less than 20 mm, and a width of the sewn fabric edge is greater than 4 mm.

As a further solution of the present disclosure, the design structure for gloves capable of heating around a fingertip further includes a wiring point, where the heating wire is electrically connected to the electronic wire through the wiring point.

As a further solution of the present disclosure, as an interface for an external power supply, the wiring point is disposed outside the glove body, and the insulating material is a rubber layer.

As a further solution of the present disclosure, the hand back portion and the palm portion of the glove body each include an outer cotton layer and a lining layer. The heating harness is fastened in the glove body through the sewn fabric edge, and the heating harness is in contact with a lining layer of the hand back portion and a lining layer of the palm portion through the cloth strip fixing structure.

As a further solution of the present disclosure, the design structure for gloves capable of heating around a fingertip further includes a temperature controller and a power input wire. The temperature controller is disposed on the back hand portion of the glove body, and the electronic wire and the power input wire are electrically connected to the temperature controller separately.

As a further solution of the present disclosure, outer portions of the hand back portion and the palm portion of the glove body each have a casing layer.

A method for processing gloves capable of heating around a fingertip includes:

• • step 1, wrapping a heating harness with a cloth strip, and forming a sewn fabric edge on a side of the cloth strip;
  • step 2, first sewing the heating harness on a hand back portion or a palm portion of a glove body; and
  • step 3, sewing the hand back portion or the palm portion to each other, to form the glove body.

As a further solution of the present disclosure, while the hand back portion or the palm portion are connected to each other by sewing, sewn fabric edges are connected to each other.

Compared with the conventional technologies, the beneficial effect of the present disclosure is that the heating harness is accurately fastened to the fingertip of the glove through a cloth strip fixing structure, to implement efficient heating. The glove includes a hand back portion and a palm portion. The heating harness is wrapped with an insulating material, and sewn in the glove through a cloth casing and a sewn fabric edge. A width of a cloth strip and a width of the sewn fabric edge are specifically selected, so that heating effect and wearing comfort are ensured. As an interface of an external power supply, a wiring point is disposed outside the glove, so that usage is simplified. A processing method is to first wrap a heating harness and then sew, to ensure production efficiency and product quality. In the present disclosure, a fingertip is heated efficiently and accurately, so that warmth retention performance is improved. In addition, due to high comfort and a simplified structure, the design structure for gloves capable of heating around a fingertip is conducive to mass production and application.

Additional aspects and advantages of the present disclosure will be partly provided in the following description, and partly become evident in the following description or understood through the practice of the present disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

To describe the technical solutions in the embodiments of the present disclosure or in the prior art more clearly, the accompanying drawings required for describing the embodiments or the prior art will be described briefly below. Apparently, the accompanying drawings in the following description show some embodiments of the present disclosure, and a person of ordinary skill in the art may still derive other drawings from these accompanying drawings without creative efforts.

FIG. 1 is a schematic diagram of a structure of a heating method in which a heating wire is directly sewn onto non-woven fabrics in the conventional technologies;

FIG. 2 is a schematic diagram of a structure of a fingertip heating method in the conventional technologies;

FIG. 3 a schematic diagram of a structure of a five-fingers heating method in the conventional technologies;

FIG. 4 a schematic diagram of a cross-section of five-fingers heating pieces in FIG. 3 in gloves in the conventional technologies;

FIG. 5 is a schematic diagram of a structure of a heating harness according to the present disclosure;

FIG. 6 is a schematic diagram of a structure when that a cloth strip fixing structure is a cloth strip;

FIG. 7 is a schematic diagram of a structure when a heating harness is wrapped with a cloth strip;

FIG. 8 is a schematic diagram of a structure of a cross-section of a heating harness;

FIG. 9 is a schematic diagram of a structure when FIG. 7 is fitted with an electronic wire;

FIG. 10 is a schematic diagram of a structure when a heating harness is fastened to an outer cotton layer;

FIG. 11 is a B-B sectional view of FIG. 10;

FIG. 12 is a schematic diagram of a structure after an outer cotton layer of a hand back is sewn with an outer cotton layer of a palm;

FIG. 13 is a C-C sectional view of FIG. 12;

FIG. 14 is a schematic diagram of a structure when an electronic wire and a wiring point are located outside an outer cotton layer;

FIG. 15 is an enlarged view of A in FIG. 14;

FIG. 16 is an enlarged view of B in FIG. 14;

FIG. 17 is a schematic diagram of a cross-section of a finger position in FIG. 14;

FIG. 18 is a schematic diagram of a cross-section of a finger position when a casing layer is adopted;

FIG. 19 is a schematic diagram before a cotton lining of a glove is sewn with a casing;

FIG. 20 is a schematic diagram of a heating structure according to the present disclosure;

FIG. 21 is a schematic diagram of a structure according to an embodiment 2 of the present disclosure;

FIG. 22 is an enlarged view of C in FIG. 21;

FIG. 23 is a schematic diagram of a structure when a heating harness having a cloth strip fixing structure is accurately sewn and fastened to an inner lining of fabrics of a hand back (or a palm) along a first sewing thread;

FIG. 24 is a schematic diagram of a structure when an inner lining of a hand back (or a palm) and an inner lining of the palm (or the hand back) are sewn and fastened along a second sewing thread based on FIG. 23; and

FIG. 25 is effect shown after a sewn glove body 1 in FIG. 24 is flipped over.

REFERENCE NUMERALS

• • glove body 1, heating wire 2, electronic wire 3, cloth strip fixing structure 4, cloth casing, 5, sewn fabric edge 6, hand back portion 7, palm portion 8, wiring point 9, temperature controller 10, outer cotton layer 11, lining layer 12, casing layer 13, insulation sheath 14, heating harness 15, sewing thread 16, hand sewing thread 17, power input wire 18, first sewing thread 19, second sewing thread 20, wrist portion 21, hand back fabric layer 22, palm fabric layer 23.

DETAILED DESCRIPTION OF EMBODIMENT

The technical solutions in the embodiments of the present disclosure will be clearly and completely described below. Apparently, the described embodiments are merely a part of, not all of, the embodiments of the present disclosure. All other embodiments obtained by a person of ordinary skill in the art based on embodiments of the present disclosure without creative efforts should fall within the protection scope of the present disclosure.

Refer to FIG. 5 to FIG. 25. An embodiment of the present disclosure provides a design structure for gloves capable of heating around a fingertip. The design structure includes a glove body 1, a heating wire 2, an electronic wire 3, and a cloth strip fixing structure 4. The cloth strip fixing structure 4 includes a cloth casing 5 and a sewn fabric edge 6.

The glove body 1 includes a hand back portion 7 and a palm portion 8. The hand back portion 7 and the palm portion 8 are connected by sewing, to ensure integrity and durability of the glove body 1.

The heating wire 2 is a high-quality heating wire 2 that is wrapped with an insulating material, and an electronic wire that is connected to two ends of the heating wire 2. The heating wire and the electronic wire form a heating harness 15. The heating harness 15 is cleverly placed inside the glove along outer edges of five fingers as shown in the figure, to achieve more accurate heating on the glove body 1, in particular to a fingertip area. Therefore, a structure that heats around the fingertip is formed.

To better fasten the heating harness 15 in the glove, the cloth strip fixing structure 4 is disposed. This structure is formed by folding a cloth strip in half, and sewing is performed at a middle part of the folded cloth strip in a length direction, to form a cloth casing 5 and a sewn fabric edge 6.

Two long side edges of the cloth strip are folded in half, and sewn at a position close to a middle part of the cloth strip in a length direction of the cloth strip, to form the cloth casing 5 and the sewn fabric edge 6. This design ensures that the heating harness 15 more stable, and improves comfort and durability of the glove.

The cloth strip may be a cloth strip whose width is more than 8 mm and less than 20 mm, to ensure that the cloth strip can provide sufficient fixing strength without affecting dexterity of the glove because of an excessive size. Meanwhile, a width of the sewn fabric edge 6 is greater than 4 mm, to facilitate sewing.

In addition, the design structure for gloves capable of heating around a fingertip has a wiring point 9. The wiring point 9 is a wiring structure that is known to those of ordinary skill in the art and is used to electrical connection of the circuit. The wiring point 9 is an electrical connection point between the heating wire 2 and the electronic wire 3, and is an interface for an external power supply. The wiring point 9 is disposed on an outer portion of the glove body 1, and an insulation sheath is used as an insulating material, to ensure safety during use.

The hand back portion 7 and the palm portion 8 of the glove body 1 each include an outer cotton layer 11 and a lining layer 12, to provide sufficient warmth and comfort. The heating harness 15 is fastened in the glove body 1 through the sewn fabric edges 6, and is in close contact with a lining layer 12 of the hand back portion 7 and a lining layer 12 of the palm portion 8, to ensure that heat is quickly and uniformly transferred to the fingertips.

The temperature controller 10 is disposed on the hand back of the glove body 1, so that a user can conveniently adjust the temperature at any time. The electronic wire 3 and the power input wire are electrically connected to the temperature controller 10 separately, to provide the user with convenient use experience.

It is worth mentioning that the casing layer 13 is separately disposed at outer portions of the hand back portion 7 and the palm portion 8 of the glove body 1, for example, the casing layer 13 may be a leather layer. This belongs to the extended embodiments known to those of ordinary skill in the art. This design improves overall aesthetics of the glove, and further enhances durability and protective properties of the glove.

In terms of a processing method, a technological process for the design structure for gloves capable of heating around a fingertip includes: firstly, wrapping a heating harness 15 with a cloth strip, in the and forming a sewn fabric edge 6 on a side of the cloth strip; secondly, first sewing the heating harness 15 on a hand back portion 7 or a palm portion 8 of a glove body 1; and finally, sewing the hand back portion 7 or the palm portion 8 to form an intact glove body 1. In this process, the sewn fabric edges 6 are sewn to enable the whole glove to be more solid and durable.

Embodiment 1

FIG. 5 describes the heating harness 15 in details.

The heating harness 15 is based on a heating wire 2 (a heating strip) wrapped with an insulation sheath 14. Two ends of the heating wire 2 are fastened to an electronic wire 3, to form an intact heating harness 15. This structure ensures efficiency and safety of heating.

FIG. 6 shows a selected fabric specification.

To ensure solidity and comfort of the heating harness 15, a cloth strip whose width is between 8 mm and 20 mm is used to wrap the heating harness 15. This width range ensures a sufficient wrapping area and ensures lightness and dexterity of the glove.

FIG. 7 and FIG. 8 shows wrapping and fastening of a cloth strip. FIG. 7 is a schematic diagram of a structure when a heating harness is wrapped with a cloth strip. FIG. 8 is a schematic diagram of a cross-section of a heating harness.

The wrapping steps are delicate and rigorous: Firstly, the selected cloth strip is tightly wrapped on the heating wire 2 which has been protected by the sheath. Secondly, the cloth strip is sewed and fastened through a professional stitching technology, to ensure that the cloth strip is perfectly adhered to the heating wire 2. Finally, a cloth edge whose size is at least 4 mm is disposed on the other side of the heating wire 2, to subsequently sew and fasten the heating harness onto the cotton lining at a same of the hand back and palm along the outer edges of the fingers. In addition, to clearly show positional and structural relationships, there are relatively large gaps between the various components. However, in actual processing, those of ordinary skill in the art should know that the various components are tightly fitted with each other, which belong to the extended embodiment as known to those of ordinary skill in the art.

FIG. 9 is a schematic diagram of a structure that a cloth strip is wrapped on a heating harness.

To ensure accurate transmission of heat and comfort of the glove, after the cloth strip is wrapped on the heating harness 15, a sewn fabric edge 6 whose size is at least 5 mm is specifically disposed. This design enables the heating harness 15 to be accurately sewn and fastened to the cotton lining at the seam of the hand back and the palm along the outer edges of the five fingers, to implement efficient heating around the fingertips.

FIG. 10 is a schematic diagram of a structure that a heating harness 15 is fastened to a cotton lining.

This step is crucial. Firstly, the heating harness 15 wrapped with the cloth casing 5 is firmly sewn onto either side of the cotton lining of the hand back or the palm through the sewn fabric edge 6. Secondly, after ensuring that a position of the heating harness 15 is accurate, the cotton lining on the other side is sewn and fastened to the heating harness 15. For example, the heating harness 15 may be sewn along the outer edges of the five fingers of the hand back of the cotton lining (as shown in the sewing thread 16 in FIG. 10), and then the cotton lining on the palm side may be sewn with the heating harness 15.

FIG. 11 shows a cross-sectional view of FIG. 10. It can be clearly seen from the cross-sectional view how the heating harness 15 is fastened to the outer edge of the cotton lining on the palm (or the hand back) side. This ensures uniform transmission of the heat, and durability and comfort of the glove.

FIG. 12 and FIG. 13 are schematic diagrams after a cotton lining of a hand back and a cotton lining of a palm are sewn.

The cotton lining of the hand back and the cotton lining of the palm present a perfect oneness (a position of the seam is a hand sewing thread 17 shown in FIG. 12) after being sewn through an accurate sewing technology. Therefore, the heating harness is hidden between the outer cotton layer 11 of the hand back and the outer cotton layer 11 of the palm. This seamless joint enhances overall aesthetics of the glove, and further enhances warmth retention performance and comfort of the glove.

Refer to FIG. 14, FIG. 15, and FIG. 16: The electronic wire 3 and the wiring point 9 are disposed outside the cotton lining.

In a process of sewing the cotton lining of the hand back to the cotton lining of the palm, sewing is temporarily stopped at the position of the wiring point 9. After the wiring point 9 and the electronic wire 3 are pulled outside of the cotton lining, outer edges of the rest cotton linings are continuously fastened. This avoids feeling of a foreign body during wearing, and greatly improves comfort and convenience of the gloves. As the interface for the external power supply, the wiring point 9 is disposed on the outer portion of the glove body 1 and is tightly wrapped with the insulation sheath, to ensure safety during use.

Refer to FIG. 17 and FIG. 18. In terms of a processing method, the cloth strip is wrapped on the heating harness 15 and sewn along a sewing thread at a position of an arrow A, to form the sewn fabric edge 6 on a side of the cloth strip. Secondly, the heating harness 15 is sewn onto the hand back portion 7 or the palm portion 8 of the glove body 1 along a sewing thread at a position of an arrow B. Finally, the hand back portion 7 and the palm portion 8 are attached to each other along a sewing thread at a position of an arrow C, to form an intact glove body 1. In this process, the sewn fabric edges 6 are sewn, to enable the whole glove to be more solid and durable.

Embodiment 2

Refer to FIG. 21 to FIG. 25. This embodiment provides a liner glove structure. A liner glove means a glove design that is lightweight and thin without an inner insulation layer.

A design method includes the following steps.

1. Fasten a heating harness 15 having a cloth strip fixing structure 4 to a hand back fabric layer 22 of a hand back portion 7 along outer edges of five fingers of the hand back through a sewing technology. This step ensures that the heating harness 15 can be closely fitted to the hand back fabric layer 22, and provide uniformly heating effect for a user.

2. Sew a palm fabric layer 23 of a palm portion 8 with the hand back portion 7 whose heating harness 15 is fastened, to forming an intact glove body 1 (a glove liner). This step enhances integrity of the glove body 1, and ensures that the heating harness 15 is not displaced or dislodged during use.

3. Fasten a wiring point 9, an electronic wire 3, and a temperature controller 10 to a wrist portion 21 in a manner provided in the embodiment 1. This facilitates connection to an external power supply, and ensures safety during use.

Refer to FIG. 23, FIG. 24 and FIG. 25 for a specific design process. The accompanying drawings shown in a process of sewing the heating harness of the liner glove of the present disclosure.

FIG. 23 clearly shows how the heating harness 15 having the cloth strip fixing structure 4 is accurately sewn and fastened to the inner lining of the hand back (or the palm) fabric along the first sewing thread 19.

FIG. 24 further shows how the lining of the hand back (or the palm) and the lining of the palm (or the hand back) are sewn along a second sewing thread 20 based on FIG. 23.

FIG. 25 is effect shown after a sewn glove in FIG. 24 is flipped over. In addition, this flipping operation is a common and widely used technology in fabric sewing. This enables an inner surface and an outer surface of the glove to be interchanged, to better display the glove or subsequently process the glove. Because the specific principle and manner of flipping are well known to those of skill in the art, details are not described herein again.

The beneficial effects of by the present disclosure are fully demonstrated in the following specific application scenarios and manners:

1. Shortcomings in the Background and Innovations of the Present Disclosure

In an existing glove heating technology, the whole palm or the hand back are uniformly heated, but no attention is paid to special needs for the fingertips. Fingertips, as one of the parts of the body that is easiest to feel cold, are particularly in need of additional warming measures in cold environments. However, conventional heating gloves are difficulty to achieve efficient heating on the fingertips due to design or technical limitations.

To resolve the above problems, the present disclosure provide a design structure for a glove capable of heating around a fingertip. Through the carefully designed cloth strip fixing structure 4 and arrangement of the heating harness 15, efficient and precise heating on the fingertips are implemented. This innovative design improves warmth retention performance of the glove, and greatly improves user experience.

2. Beneficial Effect and Significant Progress of the Technical Solution

(1) Efficient and accurate heating on fingertips: Through a special arrangement of the cloth strip fixing structure 4 and the heating harness 15, the present disclosure implements efficient and accurate heating on the fingertips. This design ensures that heat can be directly transferred to the fingertips, to effectively improve warmth retention performance of the glove.

2. High comfort: The present disclosure uses soft cloth strips and cotton lining materials, and an accurate sewing process, so that the gloves provide efficient heating while maintaining extremely high comfort. In addition, the wiring point 9 and the electronic wire 3 are disposed outside the cotton lining, to avoid the feeling of the foreign body during wearing.

3. Simple structure and ease for production: The design structure of the present disclosure is relatively simple, so that mass production and application are easily implemented. In addition, due to the unique heating method and selection for materials, the gloves are more durable and reliable during use.

4. Wide application scenarios: The design structure for gloves capable of heating around a fingertip provided by the present disclosure are suitable for cold winter outdoor activities, such as skiing and hiking, and suitable for occupational groups that need to work in low temperature environments, such as workers working in refrigerating houses and ice-snow athletes. Due to wide applicability and efficient warmth retention performance, the present disclosure has great market potential.

In conclusion, due to unique design and technical means, the present disclosure implements the design structure for gloves capable of heating around a fingertip. Compared with the conventional technologies, the present disclosure has significant advantages and advances. Due to efficient and accurate heating on the fingertips, high comfort, a simple structure, ease for production, and wide application scenarios, the present disclosure completely satisfies requirements for creativity of the inventive patent.

In the present disclosure, unless otherwise clearly specified, meanings of terms “installed”, “disposed”, “connected with”, “fastened to”, and “rotationally connected” should be understood in a board sense. For example, a connection may be a fixed connection, a removable connection, or an integral connection; may be a mechanical connection or an electrical connection; may be a direct connection or an indirect connection by using an intermediate medium; or may be intercommunication between two components or interaction between two components. Unless otherwise clearly specified, a person of ordinary skill in the art can understand a specific meaning of the term in the present disclosure based on a specific situation.

It is apparent for those skilled in the art that the present disclosure is not limited to details of the above exemplary embodiments, and that the present disclosure may be implemented in other specific forms without departing from the spirit or basic features of the present disclosure. The embodiments should be regarded as exemplary and non-limiting in every respect, and the scope of the present disclosure is defined by the appended claims rather than the above description. Therefore, all changes falling within the meaning and scope of equivalent elements of the claims should be included in the present disclosure.

Claims

1. A design structure for a glove capable of heating around a fingertip, comprising: a glove body, a heating wire, an electronic wire, and a cloth strip fixing structure, wherein the cloth strip fixing structure comprises a cloth casing and a sewn fabric edge;the glove body comprises a hand back portion and a palm portion that are sewn at an outer edge;the heating wire comprises a heating wire that is wrapped with an insulating material, and an electronic wire that is connected to two ends of the heating wire;the cloth casing is disposed at outer side of a heating harness, and the sewn fabric edge is fastened to a side of the cloth casing; andthe heating harness is fastened in the glove body through the sewn fabric edge.

2. The design structure for a glove capable of heating around a fingertip according to claim 1, wherein the cloth strip fixing structure is formed by folding two long side edges of a cloth strip in half, and sewing is performed at a middle part of the folded cloth strip in a length direction, to form a cloth casing and a sewn fabric edge.

3. The design structure for a glove capable of heating around a fingertip according to claim 2, wherein a width of the cloth strip is greater than 8 mm and less than 20 mm, and a width of the sewn fabric edge is greater than 4 mm.

4. The design structure for gloves capable of heating around a fingertip according to claim 1, further comprising a wiring point, wherein the heating wire is electrically connected to the electronic wire through the wiring point.

5. The design structure for gloves capable of heating around a fingertip according to claim 1, wherein as an interface for an external power supply, the wiring point is disposed outside the glove body, and the insulating material is a rubber layer.

6. The design structure for gloves capable of heating around a fingertip according to claim 1, wherein the hand back portion and the palm portion of the glove body each comprise an outer cotton layer and a lining layer, the heating harness is fastened in the glove body through the sewn fabric edge, and the heating harness is in contact with a lining layer of the hand back portion and a lining layer of the palm portion through the cloth strip fixing structure.

7. The design structure for a glove capable of heating around a fingertip according to claim 1, further comprising a temperature controller and a power input wire, wherein the temperature controller is disposed on the back hand portion of the glove body, and the electronic wire and the power input wire are electrically connected to the temperature controller separately.

8. The design structure for a glove capable of heating around a fingertip according to claim 1, wherein outer portions of the hand back portion and the palm portion of the glove body each have a casing layer.