Metallic flexible glove for hoisting processes

Abstract

The utility model discloses a metal flexible glove for hoisting process, including glove body, metal finger cover, first connecting ring, second connecting ring, thread groove and threaded head. The second connecting ring is circular ring structure, and the inner ring is fixedly connected with the finger separation end of glove body, and the outer ring is provided with annular threaded head. The first connecting ring is flat bottom U type groove structure, and the groove bottom is provided with through -hole, and the hole wall of through -hole is fixedly connected with the open end of metal finger cover, and the groove is assembled with thread groove, and the threaded head is embedded in the thread groove, and is connected with thread groove screw thread. The utility model discloses metal finger cover can carry out the protection to the fingertip part, prevent heavy object from falling under abnormal condition and lead to finger being bruised, improve the security degree, and utilize first connecting ring, second connecting ring, thread groove and threaded head to fix metal finger cover on glove body, and people can replace in time when glove body or metal finger cover is damaged.

Description

Technical Field

[0001] This utility model relates to the field of glove technology, specifically a flexible metal glove used in hoisting processes. Background Technology

[0002] In modern industrial production, the hoisting and handling of large workpieces is a crucial part of machinery manufacturing, construction, warehousing and logistics. With the development of industrial scale, the frequency of such operations is constantly increasing, but the safety risks faced by employees during operation are also becoming more prominent. Especially when hoisting large workpieces, the workpieces are heavy and the handling process is complex. Once a heavy object accidentally falls or crushes, the operator's fingers are very likely to be seriously injured. At best, it will lead to finger fractures and soft tissue contusions, and at worst, it may cause finger disability, which will have an irreversible impact on the employee's physical health and career development. Utility Model Content

[0003] The purpose of this utility model is to provide a flexible metal glove for hoisting processes, including a glove body, metal finger sleeves, and a first connecting ring, a second connecting ring, a threaded groove, and a threaded head connecting the glove body and the metal finger sleeves.

[0004] The glove body includes a palm portion covering the palm area and a finger portion extending from the palm to the middle of the fingers.

[0005] The glove body has a multi-layer structure, which includes, from the outside to the inside, a wear-resistant layer, a reinforcing layer, a warm layer, a cushioning layer, and a moisture-absorbing layer.

[0006] The second connecting ring is a circular ring structure, with the inner ring fixedly connected to the fingertips of the glove body and the outer ring fitted with a ring-shaped threaded head.

[0007] The metal finger sleeve has a cylindrical cover structure, with one end closed and the other end open.

[0008] The metal finger sleeve has a multi-layer structure, which includes a wear-resistant and impact-resistant layer, a buffer and energy-absorbing layer and a support layer from the outside to the inside.

[0009] The first connecting ring has a flat-bottomed U-shaped groove structure with a through hole at the bottom of the groove. The wall of the through hole is fixedly connected to the open end of the metal finger sleeve. A threaded groove is fitted inside the flat-bottomed U-shaped groove.

[0010] The threaded head is embedded in the threaded groove and is threadedly connected to the threaded groove.

[0011] Furthermore, the finger portion of the glove body extends to the first or second phalanx.

[0012] Furthermore, the structural layers of the glove body are bonded together with hot melt adhesive.

[0013] Furthermore, the structural layers of the metal finger sleeve are connected by welding.

[0014] Furthermore, the wear-resistant layer is a polyethylene fiber layer.

[0015] Furthermore, the reinforcing layer is a polyester fiber layer.

[0016] Furthermore, the insulating layer is a cashmere fiber layer.

[0017] Furthermore, the buffer layer is a memory foam layer.

[0018] Furthermore, the moisture-absorbing layer is a bamboo charcoal fiber layer.

[0019] Furthermore, the wear-resistant and impact-resistant layer is an alloy steel layer, the buffer energy-absorbing layer is a honeycomb aluminum-magnesium alloy layer, and the support layer is a titanium alloy layer.

[0020] The technical effects of this utility model are undeniable, and its beneficial effects are as follows:

[0021] 1. This utility model can form a complete glove by combining the glove body and the metal finger sleeve. The metal finger sleeve can protect the fingertips and prevent them from being injured by falling heavy objects in abnormal situations, thus improving safety. The first connecting ring, the second connecting ring, the threaded groove and the threaded head can form a connecting structure to fix the metal finger sleeve to the glove body, making it convenient for people to replace the glove body or the metal finger sleeve in time when they are damaged.

[0022] 2. This utility model utilizes a wear-resistant layer to resist frictional wear during workpiece handling; a reinforcing layer to further improve wear resistance; a heat-insulating layer to keep hands warm in cold working environments, preventing stiffness and ensuring flexible joint movement; a cushioning layer to buffer external impacts while conforming closely to the hand's curves for enhanced comfort; a moisture-wicking layer with excellent breathability to quickly absorb sweat and keep hands dry; a wear-resistant and impact-resistant layer to withstand impacts from heavy objects, protecting fingers; a cushioning and energy-absorbing layer to absorb energy through deformation, reducing impact on fingers; and a support layer to provide a basic support structure for the metal finger sleeve. Attached Figure Description

[0023] Figure 1 This is a schematic diagram of the flexible metal glove of this utility model;

[0024] Figure 2 This is a schematic diagram of the flexible metal glove of this utility model;

[0025] Figure 3 This is a schematic diagram of the glove's body structure layers;

[0026] Figure 4 This is a schematic diagram of the finger sleeve structure layers;

[0027] Figure 5 This is a schematic diagram showing the connection between the first connecting ring and the second connecting ring.

[0028] In the diagram: 1-Glove body; 101-Abrasion-resistant layer; 102-Reinforcing layer; 103-Warm-insulating layer; 104-Cushioning layer; 105-Moisture-absorbing layer; 2-First connecting ring; 3-Metal finger cot; 301-Abrasion-resistant and impact-resistant layer; 302-Cushioning and energy-absorbing layer; 303-Supporting layer; 4-Second connecting ring; 5-Threaded groove; 6-Threaded head. Detailed Implementation

[0029] The present invention will be further described below with reference to embodiments, but it should not be construed as the scope of the present invention being limited to the following embodiments. Various substitutions and modifications made based on ordinary technical knowledge and conventional methods in the art without departing from the above-described technical concept of the present invention should be included within the protection scope of the present invention.

[0030] Example 1:

[0031] See Figure 1 , Figure 2 A flexible metal glove for hoisting processes includes a glove body 1, a metal finger sleeve 3, and a first connecting ring 2, a second connecting ring 4, a threaded groove 5, and a threaded head 6 connecting the glove body 1 and the metal finger sleeve 3.

[0032] The glove body 1 includes a palm portion covering the palm area and a finger portion extending from the palm portion to the middle of the fingers.

[0033] See Figure 3 The glove body 1 has a multi-layer structure, which includes, from the outside to the inside, a wear-resistant layer 101, a reinforcing layer 102, a warm layer 103, a cushioning layer 104, and a moisture-absorbing layer 105.

[0034] The second connecting ring 4 is a circular ring structure. The inner ring is fixedly connected to the fingertips of the glove body 1, and the outer ring is fitted with an annular threaded head 6.

[0035] The metal finger sleeve 3 has a cylindrical cover structure, with one end closed and the other end open.

[0036] See Figure 4 The metal finger sleeve 3 has a multi-layer structure, which includes a wear-resistant and impact-resistant layer 301, a buffer and energy-absorbing layer 302 and a support layer 303 from the outside to the inside.

[0037] The first connecting ring 2 has a flat-bottomed U-shaped groove structure with a through hole at the bottom of the groove. The wall of the through hole is fixedly connected to the open end of the metal finger sleeve 3. A threaded groove 5 is fitted inside the flat-bottomed U-shaped groove.

[0038] See Figure 5 The threaded head 6 is embedded in the threaded groove 5 and is threadedly connected to the threaded groove 5.

[0039] Example 2:

[0040] The main structure of this embodiment is the same as that of Embodiment 1. Furthermore, the finger portion of the glove body 1 extends to the first or second finger joint.

[0041] Example 3:

[0042] The main structure of this embodiment is the same as any one of embodiments 1 to 2. Furthermore, the structural layers of the glove body 1 are bonded together by hot melt adhesive.

[0043] Example 4:

[0044] The main structure of this embodiment is the same as any one of embodiments 1 to 3. Furthermore, the structural layers of the metal finger sleeve 3 are connected by welding.

[0045] Example 5:

[0046] The main structure of this embodiment is the same as any one of embodiments 1 to 4. Furthermore, this technical solution can form a complete glove by using the glove body 1 and the metal finger sleeve 3. The metal finger sleeve 3 is used to protect the fingertips to prevent heavy objects from falling and injuring the fingers under abnormal circumstances, thereby improving safety.

[0047] The first connecting ring 2, the second connecting ring 4, the threaded groove 5 and the threaded head 6 form a connecting structure to fix the metal finger sleeve 3 to the glove body 1, so that people can replace it in time when the glove body 1 or the metal finger sleeve 3 is damaged.

[0048] Example 6:

[0049] The main structure of this embodiment is the same as any one of embodiments 1 to 5. Furthermore, the wear-resistant layer 101 is made of polyethylene fiber and is used to resist frictional wear during workpiece handling.

[0050] Example 7:

[0051] The main structure of this embodiment is the same as any one of embodiments 1 to 6. Furthermore, the reinforcing layer 102 is made of polyester fiber to further improve the wear resistance.

[0052] Example 8:

[0053] The main structure of this embodiment is the same as any one of embodiments 1 to 7. Furthermore, the insulating layer 103 is made of cashmere fiber, which enables the flexible metal glove to play a warming role in cold working environments, ensures flexible joint movement, and prevents the hands from becoming stiff due to cold.

[0054] Example 9:

[0055] The main structure of this embodiment is the same as any one of embodiments 1 to 8. Furthermore, the buffer layer 104 is made of memory foam to buffer external impact forces and closely fit the curve of the hand to improve wearing comfort.

[0056] Example 10:

[0057] The main structure of this embodiment is the same as any one of embodiments 1 to 9. Furthermore, the moisture-absorbing layer 105 is made of bamboo charcoal fiber, which is used to quickly absorb hand sweat and keep the hands dry.

[0058] Example 11:

[0059] The main structure of this embodiment is the same as any one of embodiments 1 to 10. Furthermore, the wear-resistant and impact-resistant layer 301 is made of alloy steel, the buffer energy-absorbing layer 302 is made of honeycomb aluminum-magnesium alloy, and the support layer 303 is made of titanium alloy.

[0060] The wear-resistant and impact-resistant layer 301 has wear-resistant and impact-resistant properties, and can directly withstand the impact of heavy objects to protect the fingers.

[0061] The buffer energy-absorbing layer 302 is used to absorb energy through its own deformation when subjected to external impact, thereby reducing the impact on the fingers.

[0062] The support layer 303 is used to provide a basic support structure for the metal finger sleeve 3.

[0063] Example 12:

[0064] The main structure of this embodiment is the same as any one of embodiments 1 to 11. Further, a flexible metal glove for hoisting includes a glove body 1 and a metal finger sleeve 3. A second connecting ring 4 is fixedly connected to the right side of the glove body 1, and a threaded head 6 is fixedly connected to the right side of the second connecting ring 4. A first connecting ring 2 is fixedly connected to the left side of the metal finger sleeve 3. A threaded groove 5 is provided on the left side of the first connecting ring 2. The threaded head 6 is threadedly connected to the inner cavity of the threaded groove 5. The glove body 1 includes a wear-resistant layer 101, a reinforcing layer 102, a warm layer 103, a cushioning layer 104, and a moisture-absorbing layer 105. The metal finger sleeve 3 includes a wear-resistant and impact-resistant layer 301, a cushioning and energy-absorbing layer 302, and a support layer 303.

[0065] Furthermore, the wear-resistant layer 101 is made of ultra-high molecular weight polyethylene fiber, the reinforcing layer 102 is made of high-strength polyester fiber, the warming layer 103 is made of cashmere fiber, the cushioning layer 104 is made of memory foam, and the moisture-absorbing layer 105 is made of bamboo charcoal fiber.

[0066] Hot melt adhesive is provided between the wear-resistant layer 101, the reinforcing layer 102, the heat-insulating layer 103, the buffer layer 104 and the moisture-absorbing layer 105.

[0067] Furthermore, the wear-resistant layer 101 is located outside the reinforcing layer 102, the reinforcing layer 102 is located outside the heat-insulating layer 103, the heat-insulating layer 103 is located outside the buffer layer 104, and the buffer layer 104 is located outside the moisture-absorbing layer 105.

[0068] Furthermore, the wear-resistant and impact-resistant layer 301 is made of high-hardness alloy steel, the buffer energy-absorbing layer 302 is made of honeycomb aluminum-magnesium alloy, and the support layer 303 is made of lightweight titanium alloy. The wear-resistant and impact-resistant layer 301 is welded to the outside of the buffer energy-absorbing layer 302, and the buffer energy-absorbing layer 302 is welded to the outside of the support layer 303.

[0069] This technical solution utilizes the wear-resistant layer 101 to resist frictional wear during workpiece handling, the reinforcing layer 102 to further improve wear resistance, the insulating layer 103 to provide warmth in cold working environments, preventing hand stiffness due to cold and ensuring joint flexibility, the cushioning layer 104 to buffer external impacts while closely conforming to the hand's curves for enhanced comfort, the moisture-wicking layer 105 to quickly absorb hand sweat and keep hands dry, the wear-resistant and impact-resistant layer 301 to withstand impacts from heavy objects and protect finger safety, the energy-absorbing layer 302 to absorb energy through deformation when subjected to external impacts, reducing the impact on the fingers, and the support layer 303 to provide a basic support structure for the metal finger sleeve 3.

[0070] Example 13:

[0071] The main structure of this embodiment is the same as any one of embodiments 1 to 12. Furthermore, this utility model provides a flexible metal glove for the hoisting process, which has the advantage of high safety and solves the problem that the safety risks faced by employees during operation are becoming increasingly prominent, especially when hoisting large workpieces. The workpieces are heavy and the handling process is complex. Once the heavy object falls or is squeezed, the operator's fingers are very likely to be seriously injured. At best, it will lead to finger fractures and soft tissue contusions, and at worst, it may cause finger disability, which will have an irreversible impact on the employee's physical health and career development.

Claims

1. A flexible metal glove for use in hoisting processes, characterized in that: It includes a glove body (1), a metal finger sleeve (3), and a first connecting ring (2), a second connecting ring (4), a threaded groove (5), and a threaded head (6) connecting the glove body (1) and the metal finger sleeve (3). The glove body (1) includes a palm portion covering the palm area and a finger portion extending from the palm portion to the middle of the fingers; The glove body (1) has a multi-layer structure, which includes, from the outside to the inside, a wear-resistant layer (101), a reinforcing layer (102), a warm layer (103), a cushioning layer (104) and a moisture-absorbing layer (105). The second connecting ring (4) is a circular ring structure. The inner ring is fixedly connected to the finger ends of the glove body (1), and the outer ring is fitted with a ring thread head (6). The metal finger sleeve (3) has a cylindrical cover structure, with one end closed and the other end open; The metal finger sleeve (3) has a multi-layer structure, which includes a wear-resistant and impact-resistant layer (301), a buffer energy-absorbing layer (302) and a support layer (303) from the outside to the inside. The first connecting ring (2) has a flat-bottomed U-shaped groove structure, with a through hole at the bottom of the groove. The hole wall of the through hole is fixedly connected to the open end of the metal finger sleeve (3), and the threaded groove (5) is assembled inside the flat-bottomed U-shaped groove. The threaded head (6) is embedded in the threaded groove (5) and is threadedly connected to the threaded groove (5).

2. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The finger portion of the glove body (1) extends to the first or second phalanx.

3. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The structural layers of the glove body (1) are bonded together by hot melt adhesive.

4. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The structural layers of the metal finger sleeve (3) are connected by welding.

5. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The wear-resistant layer (101) is a polyethylene fiber layer.

6. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The reinforcing layer (102) is a polyester fiber layer.

7. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The insulation layer (103) is a cashmere fiber layer.

8. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The buffer layer (104) is a memory foam layer.

9. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The moisture-absorbing layer (105) is a bamboo charcoal fiber layer.

10. A flexible metal glove for hoisting operations according to claim 1, characterized in that: The wear-resistant and impact-resistant layer (301) is an alloy steel layer, the buffer energy-absorbing layer (302) is a honeycomb aluminum-magnesium alloy layer, and the support layer (303) is a titanium alloy layer.

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