TH114546A - Explosive-proof materials and methods of making them - Google Patents

Abstract

DC60 (04/08/15) This invention provides explosive proof materials, including thin (11) thin sheets with high gaps with one (12) side of the material at the center. A thin sheet material (11) with a high gap is wound into several layers of the material housing (1) in the direction perpendicular to the side (12). The main axis (13) is inserted between the material. Several layers of thin sheets (11) with high gaps of the material body (1) to tighten the frame body (1) and support the material frame (1) to fabricate it. A method for making an explosion proof material, which includes First, by cutting Raw material with a wide open, wavy pattern. This results in a semi-finished sieve shape material, and then slowly extending both sides of the semi-finished sieve shape material to a square shape. A multi-layered honeycomb And thus resulting in a thin sheet material (11) with a high gap later, with one side (12) of this high gaps (11) at the center. The material is then wrapped in a direction perpendicular to this side. Lastly, in the winding process, the core (13) is inserted between the thin sheet material (11) with a high gap. Then the material was cut into thin sheets (11) with a high gap. And the material looks like a thin sheet The main shaft (13) that is inserted is coiled into several layers of explosion-proof material. The invention uses a core to support the high-gap thin-sheet material frame and therefore effectively protect the frame from collapse and deformation. Special features achieved by a simple structure and easy to follow procedures. This invention It can prevent early explosion accidents with open flames, static electricity, electric welding, gun fires, collisions and misoperation. Therefore, it makes the safety, environment-friendly and durable performance of the storage-transport container as effective. The invention provides explosion-proof materials, including highly voided thin (11) sheets with one side (12) of the material at the center. A thin sheet material (11) with a high gap is wound into several layers of the material housing (1) in the direction perpendicular to the side (12). The main axis (13) is inserted between the material. Multi-stage slats (11) with high gaps of the material frame (1) to secure the frame body (1) and the supporting unit to the material frame (1) the fabrication provides a method. Follow procedures for making explosion proof materials, including First, by cutting Raw material with a wide open, wavy design. This results in a semi-finished sieve shape material, and then gradually making both sides of this semi-finished sieve shape material expand to a square shape. A multi-layered honeycomb And thus resulting in a thin sheet material (11) with a high gap later, with one side (12) of this high gaps (11) at the center. The material is then wrapped in a direction perpendicular to this side. Lastly, in the winding process, the core (13) is inserted between the thin sheet material (11) with a high gap. Then the material was cut into thin sheets (11) with a high gap. And the material looks like a thin sheet The main shaft (13) that is inserted is coiled into several layers of explosion-proof material. The invention uses a core to support the high-gap thin-sheet material frame and therefore effectively protect the frame from collapse and deformation. Special features achieved by a simple structure and easy to follow procedures. This invention It can prevent early explosion accidents with open flames, static electricity, electric welding, gun firing, collision and chopper operations. Therefore, it makes the safety, environment-friendly and durable performance of the storage-transport container as effective.

Claims (9)

Disclaimers (all) that will not appear on the advertisement page: 1. Explosion proof material consists of The perforated mesh panels (11) by the perforated mesh panels (11) are coiled up into a multi-layer housing (1) with one edge (12). Of the material is centered and along the perpendicular to this side edge (12), which is characterized by that the main axis (13) is inserted into the space between the two layers of the resulting lattice. Multiple holes are drilled (11) to secure and support the material body (1). 2. Explosion-proof material of claim 1, which characterizes that the aforementioned core (13) is made by bonding between the pull plate (131) and the tightening ring (132) the pull ring provides A sticky tightness (132) that is positioned in the center of the pull plate (131) and fixed on the pull plate, the shape of the main shaft (13) corresponds to the shape of the material frame (1). 3. Explosion-proof material of claim 2, which characterizes that the core (13) is made up of a flexible material. 4. Explosion-proof material of claim 2, which specifies that the said core (13) is a continuous one. 5. Explosive-proof material of claim 2, which characterizes that the said core (13) is a discrete core. 6. Explosion proof material of claim 2, which characterizes that the core (13) is inserted in more than one position. 7. Explosion-proof material of claim 2 or 3 or 4 or 5 or 6, which indicates that the aforementioned pull plate (131) is a wavy formation. 8. Explosion proof material of claim 2 or 3 or 4 or 5 or 6, which indicates that the aforementioned pull plate (131) is a rectangular frame. 9. Explosion proof material of claim 1, which specifies that the pillar (13) consists of columns (133) and beams (134) such columns (133) are inserted between the material. It is a thin, multi-layered sheet with a high gap (11) of the material body and extending over the end surface. The top and bottom of the frame (1) and the beam (134) are connected to the elongated portion of the column (133) on the upper and lower end surfaces of the frame body (1) 1. 0. Explosion-proof material of claim 1, which characterizes that the aforementioned core (13) consists of more than one frame (135). These frame frames (135) are produced during the characteristic material as The gaps (11) of the high-gaps (11) and the multilayer frames (135) are connected at the top and bottom of the frame 1. 1. Explosion proof material of claim 1, which characterizes that the aforementioned core (13) consists of two parts: the upper core and the lower core (136), the upper core and the lower core. (136) each core, including the end frames (1361) and the inserted frames (1362), each such end frame (1361) placed on the surface. The top and bottom ends of the material body (1) and the insertion frame (1362) are inserted into the gaps between the thin, multi-layered material with a high gap (11) of the body. Frame material (1) For the purpose of fixing the frame firmly and supporting frame material 1. 2. Explosion proof material of claim 1 or 2, which specifies that the material body (1) may be in the shape of a pole, a dice or a dice, or with many sides. 3. Explosion proof material of claim 1, which characterizes the characteristic that the material It is a high gap thin sheet (11) made up of a type of metal material, alloy material and Materials achieved through coating technology Metal / non-metal Or a combination of Those technologies 1 4. Explosion-proof material of claim 1, which characterizes that the said core (13) is made up of a type of metallic, non-metallic material, alloy material and material achieved by Through the coating technology Metal / non-metal Or is it a combination of those technologies 1 5. Explosion proof material This unique characteristic is that explosion-proof materials include the core body (300) and the metal grille (200) that coils the core body. The axial body made of a material A foam that can expand 1 6. Explosion proof material This specifies that the explosion-proof material includes the core body (300) and the expandable foam-covered material that is wrapped on the core.This core frame (300) is made from a metal mesh. 7. Explosion-proof material of claim 15, which characterizes the metal mesh This provides a coating layer (100), which is made up of expandable foam material 1. 8. Explosion-proof material of claim 15 or 16 or 17, which identifies specific characteristics that That the material to make such an expandable foam is polyether, poly-acid ester or polyurethane 1 9. Explosion-proof material of claim 15, which characterizes that such metal grating (200) is completely or partially wound on the outside of the axle housing 2. 0. How to follow the process of making explosion proof material. Which indicates a unique feature that the method Done include the following steps: Step 1: Through the cut Semi-finished sieve shape materials can also be made from sheet materials. Thin metal, open, wavy, original. Step 2: By gradually expanding and stretching on both sides of the contour material. Semi-finished sieve This results in a thin sheet material (11) with a high gap. Step 3: with one side (12) of this thin sheet material (11) with a central high gap that rolls the material over. Follow the direction perpendicular to this side. Step 4: During the process of inserting the main coil (13) into the gap Between any two layers of thin sheet material (11) with a high gap Winding material Continue until the material is made into a round cylinder of the required diameter, and then cut the thin sheet material (11) with a high gap. And thus resulting in 2 explosion proof material 1. Method of explosion proofing method of claim 20, which characterizes that the process was performed for integrating the core (13) in step 4, including step 4.1: conducting open treatment. Advance to the main axis (13) achieved by weaving Coordinate between the wavy pull-up plate (131) and the sticky pull-ring (132) or the square pull-ring (131) and the tighter pull ring (132). Into a thin sheet material (11) with a high gap. This core (13) can be inserted in one or more positions in Method of doing continuous or spiral or intermittent 2 2. Explosive-proof material method of claim 21, which specifies that the process is performed for inserting the core in multiple positions in step 4.2, including the core (13). It is made possible by the interlocking weave between the wavy pull plate (131) and the tighter pull ring (132), which is inserted in various positions. The tacky rectangle (131) and the sticky pull ring (132), which is inserted in multiple positions or two of the main axis (13), are inserted in multiple positions in a combination pattern 2. 3. Explosive-proof material method of claim 20, which specifies that the process is performed for integrating the core (13) in step 4, including step 4.1 \ ': in the process of Such thin sheet material (11) with high gaps stretching columns (133) over multiple positions between the thin sheet material (11) of the material frame. So that the mast extends over the upper and lower end surfaces of the frame (1), step 4.2 \ ': connect the parts of the mast stretching over the upper end surfaces and The bottom of the material frame (1) with a beam to only get the main shaft (13) inserted into Correct only 2 4. The Explosive-Proof Process Method of Clause 20, which specifies that the process is made for integrating the core (13) in Step 4, including Step 4.1 \ ': In the process of The winding of such thin sheet material (11) with a high gap which provides a frame structure (135) in between the thin sheet material (11) with a high gap of the material frame. With these frames that have been separated from each other that The inner span of certain angles Step 4.2 \ ': Connect multiple truss sections (135) to each other. At the top and bottom of those frames To just get the core (13) inserted correctly. 5. The explosion proof method method of claim 24, which specifies that the exact angle in the aforementioned 4.1 \ '\' step is from 45 ํ -90 ํ 2. 6. The Explosive-Proof Process Method of claim 20, which specifies that the process is performed for integrating the core (13) in Step 4, including Step 4.1 \ ': In the process of Winding of such thin sheet material with high gaps (11) by inserting the upper and lower spindles (136) consisting of the interconnected end frames (1316) and the inserted frames ( 1362), the end frame (1361), which is placed on the upper and lower end surfaces of the body (1) respectively, and the insertion frame (1362) that are inserted into the space between the Material is a thin, multi-layered sheet with high gaps (11) of the frame body (1) for the purpose of tightening the frame and helping Support for the material frame 2 7. How to follow the process of making explosion proof material. Which indicates a unique feature that the method Done include the following steps: Step 1: Through the cut Which resulted in a semi-finished sieve shape material made from Wavy original thin sheet metal material Step 2: By gradually expanding and extending outward on both sides of the material. Semi-finished sieve shape To merely obtain a thin sheet material (11) with a high gap. Step 3: with one side (12) of this thin sheet material (11) with a central high gap that is wound. Roll the material in a direction perpendicular to this side. Step 4: After winding a specific limit, roll the material into a direction perpendicular to this side. The material (11) was then cut into sections, and the core (13) was inserted into the space between the round cylinder material, only to produce several layers of explosion-proof material. 8. How to follow the process of making explosion proof material. Which indicates a unique feature that the method Doing steps include the following steps 100: Through the meshing process. Materials that make it expandable. Step 200: Wrap the metal mesh roll (200) over the outer surface of the pattern core. Combs to make an explosion proof material 2. 9. How to follow the process of making explosion proof material. Which indicates a unique feature that the method Doing steps include the following steps 100: Through the meshing process. Materials that make it expandable. Step 200: Wrap a metal mesh roll (200) over the outer surface of the frame. 300 step honeycomb core: place the material following the process in 200 steps in the template. The outer surface of the template was wrapped with expanded foam material so that only the roll wrap layer (100) was obtained. Which became Explosion proof material 3 0. How to follow the process of making explosion proof material. Which indicates a unique feature that the method This includes the following steps: Steps 100: Passed Winding and Overlaying. Which made a metal grid for As the core body (300), the 200 steps: Wrap the outer surface of the core body with foam material. Expandable characteristics After making it into shape This became an explosion proof material. 3. 1. How to follow the explosion proof material method of claim No. 28 or 29 or 30, which characterizes that the method of making metal grating (200) is As follows: through the cut The semi-finished sieve shape material can also be made from thin, open, wavy sheet metal material, which is then gradually expanded and stretched on both sides of the material. This semi-finished sieve shape forms a triangular honeycomb. Thus resulting in a metal grid Characteristics of a thin sheet with high gaps. 3. 2. Method of explosion-proof material processing of Clause 28 or 29 or 30, which specifies the characteristic that the method of making such metal grating. This is done by making the top and bottom surfaces of the adjacent original thin metal sheet material (600) bonded to each other into multiple layers. With the connecting point that has been arranged, resulting in a range within which The same distance in the transverse and longitudinal directions. Then cut some sheet metal material. It is several layers of original metal that are properly joined together to form strips (602) in the same direction. Then, several layers of material are gradually made to expand in the direction perpendicular to the cutting direction. Later, the internal position between the bonding points expands to make a gap. In order to get Metal grating, characterized by a thin sheet with a high gap (604).