Highly breathable polo shirt

By adopting a multi-zone distributed breathable structure design in the polo shirt, the problem of insufficient breathability in high-heat areas of the polo shirt is solved, achieving more efficient sweat wicking and heat dissipation, and improving wearing comfort.

CN224386813UActive Publication Date: 2026-06-23JIANGSU HUBAO GROUP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU HUBAO GROUP CO LTD
Filing Date
2025-09-19
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing polo shirts suffer from insufficient breathability in high-heat areas, a monotonous structure, poor sweat-wicking properties, and low wearing comfort.

Method used

It adopts a multi-zone distributed breathable structure design, including the combination of main fabric and highly breathable mesh fabric, gradient breathable areas, central back air duct, underarm air duct structure, double-layer sleeves, micro-perforated breathable membrane in collar, and breathable slits, forming a multi-layer three-dimensional air duct channel to improve local heat dissipation efficiency and comfort.

Benefits of technology

While maintaining the overall design, the sweat-wicking and heat dissipation efficiency and wearing comfort of the polo shirt have been significantly improved, especially in high-temperature environments, effectively alleviating the problem of stuffiness and sweat accumulation under the armpits, thus improving the wearer's practicality and comfort experience.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to clothing processing technical field, concretely relates to a kind of high-breathability POLO shirt including main fabric front piece, high-breathability mesh front piece, main fabric back piece, high-breathability mesh back piece, double-layer sleeve piece, lapel, door front, underarm air guide structure, back center air guide belt and breathable split, main fabric front piece and high-breathability mesh front piece are spliced and set in POLO shirt front body, main fabric back piece and high-breathability mesh back piece are spliced and set in POLO shirt back body, high-breathability mesh front piece and high-breathability mesh back piece are respectively located in the lower area of POLO shirt, double-layer sleeve piece adopts double-layer structure, inner layer is high-breathability layer, outer layer is main fabric, and form underarm air guide structure in underarm part;POLO shirt back center is provided with the back center air guide belt that penetrates shoulder to lower hem;Lower hem is provided with breathable split, the utility model aims at solving the problems, such as insufficient breathability in high heat area, single structure, poor perspiration effect and lower wearing comfort of existing POLO shirt.
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Description

Technical Field

[0001] This utility model relates to the field of clothing technology, and in particular to a highly breathable polo shirt. Background Technology

[0002] In recent years, with people's increasing demands for quality of life and clothing comfort, polo shirts, due to their combination of casual and formal styles, have become a common choice for summer clothing, widely used in daily commutes, outdoor sports, and corporate work attire. However, with the rising summer temperatures and frequent sweating during exercise or prolonged wear, the shortcomings of traditional polo shirts in terms of breathability and moisture-wicking performance have become increasingly prominent. How to improve the breathability and comfort of polo shirts while maintaining their original appearance has become a pressing technical problem to be solved in clothing structural design.

[0003] In existing technologies, most polo shirts are constructed using a single material and a one-piece cut, lacking targeted ventilation design for specific areas. For example, areas where high heat accumulate, such as the armpits, back, and abdomen, are still covered with conventional flat fabric, making it difficult to effectively dissipate heat. The sleeves are mostly single-layered fabrics, lacking airflow channels, which easily leads to sweat accumulation and discomfort during exercise. The hem, placket, and collar areas also use a tightly sealed sewing method, resulting in a single overall heat dissipation path. Although some products attempt to improve breathability by using lighter fabrics or partial perforations, this often comes at the cost of sacrificing crispness and structural support, affecting the overall aesthetics and functionality, and resulting in poor practicality. Therefore, this utility model discloses a highly breathable polo shirt to solve the problems of insufficient breathability in high-heat areas, single-layered structure, poor sweat wicking effect, and low wearing comfort of existing polo shirts. Utility Model Content

[0004] The purpose of this invention is to propose a highly breathable polo shirt to solve the problems of insufficient breathability, simple structure, poor sweat-wicking effect, and low wearing comfort of existing polo shirts in high-heat areas.

[0005] To achieve the above objectives, this utility model provides a highly breathable polo shirt, comprising a main fabric front piece, a highly breathable mesh front piece, a main fabric back piece, a highly breathable mesh back piece, double-layered sleeves, a collar, a placket, underarm ventilation structures, a central back ventilation band, and breathable vents. The main fabric front piece and the highly breathable mesh front piece are joined together on the front of the polo shirt, and the main fabric back piece and the highly breathable mesh back piece are joined together on the back of the polo shirt. The eyepieces are located in the lower part of the polo shirt, forming a ventilation structure. The double-layered sleeves have a double-layered structure, with a highly breathable inner layer and a main fabric outer layer, forming an underarm ventilation structure. This underarm ventilation structure automatically opens for ventilation during underarm movement. The polo shirt has a central back ventilation band that runs from the shoulder to the hem, forming a longitudinal ventilation channel in the back. The hem has a breathable slit to enhance air convection performance.

[0006] Preferably, the main fabric front piece and the high-breathability mesh front piece are joined and sewn together in a curved pattern.

[0007] Preferably, a gradient breathable area is provided between the main fabric back piece and the highly breathable mesh back piece, with the breathability density gradually increasing from top to bottom along the longitudinal direction, in order to work with the central air duct at the back to enhance heat dissipation efficiency.

[0008] Preferably, the double-layered sleeve has a guide slit near the armpit, which is a structure of multiple slits arranged at a backward angle to guide air into the armpit area when the wearer swings their arm.

[0009] Preferably, the underarm air-guiding structure is a V-shaped splicing structure with embedded flexible mesh fabric. The three sides of the underarm air-guiding structure are respectively sewn to the underarm junctions of the front piece, back piece, and sleeve piece to form a three-dimensional ventilation underarm area with automatic opening and closing function.

[0010] Preferably, the collar has a double-layer structure, with a perforated ventilation membrane sandwiched in the inner layer. The perforated ventilation membrane has multiple micro ventilation holes distributed around its circumference to enhance the heat dissipation performance of the area around the neck.

[0011] Preferably, the placket has a reinforced structure with a microporous ventilation strip sewn inside to guide heat from the chest area out of the placket opening area. The ventilation strip is fixed to the center of the placket by a press-stitch process.

[0012] The beneficial effects of this utility model are:

[0013] This polo shirt features a multi-zone distributed breathable structure. The front and back panels utilize a combination of the main fabric and highly breathable mesh, creating a distinct upper and lower section that allows for excellent airflow in the lower part of the garment, effectively improving localized heat dissipation. The curved seam between the main fabric front panel and the highly breathable mesh front panel ensures a better fit to the chest and abdomen area, enhancing the three-dimensional tailoring while creating a smooth heat dissipation channel. The gradient breathable zones on the back panel, combined with a central back vent, create a longitudinal heat dissipation path from the shoulders to the waist. This actively guides airflow in response to movement, significantly improving back ventilation and sweat-wicking. The underarm area features a three-dimensional V-shaped structure formed by the front, back, and sleeve panels, with embedded flexible mesh fabric. This creates an automatically opening and closing underarm ventilation structure that opens during arm movement, effectively alleviating underarm stuffiness and sweat buildup. The sleeves feature a double-layer design. The inner layer uses breathable material, while the outer layer maintains a uniform fabric. Multiple angled slits near the armpits guide airflow from the sleeves into the armpit area, creating convection channels and further enhancing local air circulation. Furthermore, the polo shirt's collar is a double-layer composite design. The inner layer contains a perforated ventilation membrane, ensuring collar crispness while increasing circumferential heat dissipation around the neck. Micro-perforated ventilation bands inside the placket are secured with press seams, offering excellent concealment and functionality, guiding heat dissipation from the chest area when the placket is open. Breathable vents on both sides of the hem allow for movement during walking or exercise, enhancing air exchange and providing some adjustment. In summary, this highly breathable polo shirt, while maintaining its overall shape, comprehensively improves the wearer's sweat-wicking and heat-dissipating efficiency and comfort in high-temperature environments through the innovative combination of three-dimensional ventilation structures, demonstrating significant practicality and promotional value. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the front view of the present utility model.

[0015] Figure 2 This is a schematic diagram of the rear planar structure of this utility model;

[0016] Figure 3 This is a three-dimensional enlarged structural diagram of the front left side view of this utility model;

[0017] Figure 4 This is an enlarged planar structural diagram of the rear view portion of this utility model.

[0018] The diagram is marked as follows:

[0019] 1. Main fabric front panel; 2. High-breathability mesh front panel; 3. Main fabric back panel; 4. High-breathability mesh back panel; 5. Double-layered sleeve panels; 6. Air-guiding seams; 7. Collar; 8. Placket; 9. Underarm ventilation structure; 10. Center back ventilation band; 11. Breathable vents. Detailed Implementation

[0020] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to specific embodiments.

[0021] This utility model provides, for example Figures 1 to 4 The illustrated highly breathable polo shirt includes a main fabric front panel 1, a highly breathable mesh front panel 2, a main fabric back panel 3, a highly breathable mesh back panel 4, double-layered sleeves 5, a collar 7, a placket 8, underarm ventilation structures 9, a central back ventilation band 10, and a breathable vent 11. The main fabric front panel 1 and the highly breathable mesh front panel 2 are joined together at the front of the polo shirt, and the main fabric back panel 3 and the highly breathable mesh back panel 4 are joined together at the back of the polo shirt. The back panel 4 is located in the lower part of the polo shirt, forming a ventilation structure. The double-layered sleeve panel 5 adopts a double-layer structure, with a highly breathable inner layer and a main fabric outer layer. It also forms an underarm ventilation structure 9 at the underarm area. The underarm ventilation structure 9 automatically opens for ventilation when the underarm moves. The polo shirt has a back center ventilation band 10 that runs from the shoulder to the hem to form a longitudinal ventilation channel at the back. The hem has a breathable slit 11 to enhance the air convection performance of the hem.

[0022] This polo shirt features a multi-zone distributed breathable structure design. The front and back panels utilize a combination of the main fabric and highly breathable mesh fabric to create a distinct upper and lower section, allowing for excellent airflow in the lower part of the garment and effectively improving localized heat dissipation. In particular, the curved splicing between the main fabric front panel 1 and the highly breathable mesh front panel 2 allows the fabric to better conform to the chest and abdomen area, enhancing the three-dimensional tailoring while creating a smooth heat dissipation channel. The gradient breathable area on the back panel, combined with the central back ventilation band 10, achieves a longitudinal heat dissipation path from the shoulders to the waist, actively guiding airflow in accordance with body movement to significantly improve back sweat wicking and ventilation. The underarm area features a three-dimensional V-shaped structure formed by the front, back, and sleeve panels, with embedded flexible mesh fabric, creating an automatically opening and closing underarm ventilation structure 9. This structure automatically opens during arm movement to create a ventilation channel, effectively alleviating underarm stuffiness and sweat buildup. The sleeves feature a double-layer design. The inner layer uses breathable material, while the outer layer maintains a uniform fabric. Multiple angled airflow slits (6) near the armpits guide airflow from the sleeves into the armpit area, creating convection channels and further enhancing local air circulation. Furthermore, the polo shirt's collar (7) is a double-layer composite design. The inner layer contains a perforated ventilation membrane, ensuring collar crispness while increasing circumferential heat dissipation around the neck. The micro-perforated ventilation band inside the placket (8) is secured with a press-stitch, offering excellent concealment and functionality, guiding heat dissipation from the chest area. Breathable vents (11) on both sides of the hem allow for movement during walking or exercise, enhancing air exchange and providing some adjustment. In summary, this highly breathable polo shirt, while maintaining its overall shape, comprehensively improves the wearer's sweat-wicking and heat-dissipating efficiency and comfort in high-temperature environments through the innovative combination of three-dimensional air-guiding structures, demonstrating significant practicality and promotional value.

[0023] Furthermore, in this example, such as Figure 3 and Figure 4As shown, the main fabric front piece 1 and the high-breathable mesh front piece 2 are joined by a curved stitching. A gradient breathable area is provided between the main fabric back piece 3 and the high-breathable mesh back piece 4, with the breathability density gradually increasing from top to bottom along the longitudinal direction. This is to work in conjunction with the central back ventilation band 10 to enhance heat dissipation efficiency. The double-layered sleeve piece 5 has a ventilation gap 6 near the armpit. The ventilation gap 6 is a structure with multiple back-sloping seams arranged to guide air into the armpit area when the wearer's arms move. The armpit ventilation structure 9 is a V-shaped stitching structure. The inner flexible mesh fabric and the underarm ventilation structure 9 are sewn on three sides to the junction of the front, back and sleeve pieces under the armpits to form a three-dimensional ventilation armpit area with automatic opening and closing function. The collar 7 is a double-layer structure with a perforated ventilation membrane sandwiched in the inner layer. The perforated ventilation membrane has multiple micro ventilation holes distributed around its periphery to enhance the heat dissipation performance of the area around the neck. The placket 8 is a reinforced structure with a micro-perforated ventilation strip sewn inside to guide the heat in front of the chest out through the opening and closing area of ​​the placket 8. The ventilation strip is fixed to the center of the placket 8 by a press-stitch process.

[0024] During daily activities or exercise, the body accumulates heat unevenly in different areas. To address this, the front structure of this polo shirt features a curved seam where the main fabric front piece 1 and a highly breathable mesh front piece 2 are joined vertically, conforming to the curves of the chest and abdomen. This curved seam also creates a natural downward airflow path along the fabric, allowing body heat to dissipate quickly through the mesh area, preventing stuffiness in the abdominal area. The back piece consists of the main fabric back piece 3 and a highly breathable mesh back piece 4, joined below the waist. The highly breathable mesh back piece 4 features a longitudinally gradient ventilation structure with increasing pore density from top to bottom, working in conjunction with the central back ventilation band 10 running from top to bottom to form a longitudinal ventilation channel from the shoulders to the waist. When the wearer is walking or active, the local air pressure difference created on the back causes hot air to escape through the air ducts and gradient structure, achieving a "chimney effect" of heat convection and effectively improving ventilation and perspiration efficiency in the back. In the sleeve area structure, the inner side of the double-layered sleeve piece 5 is made of breathable material, while the outer layer is made of ordinary main fabric to maintain overall aesthetics. Multiple backward-sloping air-guiding seams 6, located near the armpit, are arranged at an angle. Combined with the wearer's arm movements, they continuously guide surrounding air to the armpit area, forming an active air intake path from the cuff to the armpit, improving the ventilation efficiency in the armpit. The armpit air-guiding structure 9 is a three-dimensional V-shaped structure with embedded flexible mesh fabric, which is sewn to the intersection of the front main fabric piece 1, the back main fabric piece 3, and the double-layered sleeve piece 5. When the arm is raised or swung, the three-sided seam structure naturally expands outward due to tension, forming an opening. The underarm ventilation structure 9 then opens, creating an effective air intake and exhaust window. When the arm returns to its natural hanging position or remains stationary, the structure automatically retracts under the pull of the flexible fabric, closing to form a close-fitting appearance. This expandable and closure characteristic of the structure enables dynamic ventilation in the underarm area, automatically opening and closing with changes in movement, effectively alleviating the stuffiness and discomfort caused by localized sweating. In the collar structure, the lapel 7 is a double-layer structure. The inner layer contains a perforated ventilation membrane with multiple micropores, arranged in a ring around the neck. During wear, this promotes the formation of multiple micro-airflow release points around the wearer's neck. Especially in high-temperature conditions, the heat generated by the head and neck can diffuse outward through the micro-perforated channels of the collar, thereby achieving temperature regulation and heat dissipation assistance in the collar area. The front placket 8 is a reinforced structure with a hidden micro-perforated ventilation strip inside. This ventilation strip is fixed to the center of the placket 8 by a press-stitch process, ensuring it does not affect normal opening and closing function. When worn, heat accumulates along the central axis of the placket 8. The ventilation band provides an auxiliary heat release path from the inside out, alleviating heat buildup in the placket 8 area and improving overall perspiration balance. The hem features breathable vents 11 on both sides, whose opening angle can be adjusted as needed.During walking or vigorous activity, the swaying of the hem creates intermittent air intake windows, thereby enhancing air circulation at the hem of the garment. This allows for a more thorough exchange between the cool air entering from the bottom of the garment and the heat from the body surface, further improving the overall ventilation and perspiration function of the clothing.

[0025] Those skilled in the art should understand that the discussion of any of the above embodiments is merely exemplary and is not intended to imply that the scope of the present invention (including the claims) is limited to these examples; within the framework of the present invention, the technical features of the above embodiments or different embodiments can also be combined, the steps can be implemented in any order, and there are many other variations of the different aspects of the present invention as described above, which are not provided in the details for the sake of brevity.

[0026] This utility model is intended to cover all such substitutions, modifications, and variations that fall within the broad scope of the appended claims. Therefore, any omissions, modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. A highly breathable polo shirt, characterized in that, The polo shirt includes a main fabric front piece (1), a high-breathability mesh front piece (2), a main fabric back piece (3), a high-breathability mesh back piece (4), double-layer sleeves (5), a collar (7), a placket (8), an underarm ventilation structure (9), a central back ventilation strip (10), and a breathable vent (11). The main fabric front piece (1) and the high-breathability mesh front piece (2) are spliced ​​together on the front of the polo shirt, the main fabric back piece (3) and the high-breathability mesh back piece (4) are spliced ​​together on the back of the polo shirt, and the high-breathability mesh front piece (2) and the high-breathability mesh back piece (4) are spliced ​​together on the back of the polo shirt. The eye back panel (4) is located in the lower part of the POLO shirt to form a ventilation structure. The double-layer sleeve panel (5) adopts a double-layer structure, with the inner layer being a highly breathable layer and the outer layer being the main fabric. It also forms an underarm ventilation structure (9) at the underarm. The underarm ventilation structure (9) automatically forms an opening for ventilation when the underarm moves. The POLO shirt has a back center ventilation band (10) that runs through the shoulder to the hem to form a longitudinal ventilation channel on the back. The hem has a breathable slit (11) to enhance the air convection performance of the hem.

2. The highly breathable polo shirt according to claim 1, characterized in that, The main fabric front piece (1) and the high-breathability mesh front piece (2) are joined and sewn together by a curved stitch.

3. A highly breathable polo shirt according to claim 2, characterized in that, A gradient breathable area is provided between the main fabric back piece (3) and the high breathable mesh back piece (4), with the breathable density gradually increasing from top to bottom in the longitudinal direction, in order to cooperate with the back center air guide belt (10) to enhance heat dissipation efficiency.

4. A highly breathable polo shirt according to claim 3, characterized in that, The double-layered sleeve (5) has a guide slit (6) near the armpit. The guide slit is a structure of multiple slits arranged at a backward angle, which is used to guide air into the armpit area when the wearer swings his arm.

5. A highly breathable polo shirt according to claim 4, characterized in that, The underarm air-guiding structure (9) is a V-shaped splicing structure with embedded flexible mesh fabric. The three sides of the underarm air-guiding structure (9) are respectively sewn to the underarm junction of the front piece, the back piece and the sleeve piece to form a three-dimensional ventilation underarm area with automatic opening and closing function.

6. A highly breathable polo shirt according to claim 5, characterized in that, The lapel (7) has a double-layer structure, with a perforated ventilation membrane sandwiched in the inner layer. The perforated ventilation membrane has multiple micro ventilation holes distributed around its circumference to enhance the heat dissipation performance of the area around the neck.

7. A highly breathable polo shirt according to claim 6, characterized in that, The placket (8) is a reinforced structure with a micro-perforated ventilation strip inside, which guides the heat in front of the chest out through the opening and closing area of ​​the placket. The ventilation strip is fixed to the center of the placket by a pressing process.