阅读说明：本技术 一种用于气割作业的防火毯 (Fireproof blanket for gas cutting operation ) 是由 陈志鹏 王振国 杜耀东 陈岑凯 沈哲 夏恩亮 王京升 张松 于 2021-08-17 设计创作，主要内容包括：本发明涉及安全防护用品技术领域,具体涉及一种用于气割作业的防火毯,包括沿着防火毯的厚度方向上依次设置的上表隔热层、金属导热层和下表隔热层；所述金属导热层为铜或铝的编织物构成或主要由铜或铝的编织物构成。本发明在两个隔热层之间设置了一个金属导热层,采用铜或铝丝编织而成。由于铜和铝具有很高的导热系数,该导热层能够将局部热量迅速扩散开来。因此,本发明提供的防火毯在厚度方向上具有良好的隔热能力的同时,在长度和宽度方向上具有良好的的热扩散能力,可以将在气割火焰施加在局部区域上的热量,沿面扩散开来,提高了防止局部烫伤的能力。(The invention relates to the technical field of safety protection articles, in particular to a fireproof blanket for gas cutting operation, which comprises an upper surface heat-insulating layer, a metal heat-conducting layer and a lower surface heat-insulating layer, wherein the upper surface heat-insulating layer, the metal heat-conducting layer and the lower surface heat-insulating layer are sequentially arranged along the thickness direction of the fireproof blanket; the metal heat conduction layer is formed by copper or aluminum braided fabric or mainly formed by copper or aluminum braided fabric. The invention arranges a metal heat conduction layer between two heat insulation layers, which is woven by copper or aluminum wires. Since copper and aluminum have high thermal conductivity, the heat conducting layer can rapidly spread local heat. Therefore, the fireproof blanket provided by the invention has good heat insulation capability in the thickness direction and good heat diffusion capability in the length and width directions, can diffuse heat applied to a local area by gas cutting flame along the surface, and improves the capability of preventing local scald.)

1. The fireproof blanket for gas cutting operation is characterized by comprising an upper surface heat-insulating layer, a metal heat-conducting layer and a lower surface heat-insulating layer which are sequentially arranged along the thickness direction of the fireproof blanket, wherein the upper surface heat-insulating layer and the lower surface heat-insulating layer are both made of inorganic fireproof fiber materials or materials taking inorganic fireproof fibers as main bodies; the metal heat conduction layer is formed by copper or aluminum braided fabric or mainly formed by copper or aluminum braided fabric.

2. A fire blanket for gas cutting operations as recited in claim 1, wherein said metal heat conductive layer has a thickness of 1.5mm to 3 mm.

3. The fire blanket for gas cutting operations of claim 1, wherein the metal heat conducting layer is woven from metal heat conducting wires by warp and weft weaving, and the metal heat conducting wires are copper wires or aluminum wires.

4. A fire blanket for gas cutting operations as recited in claim 3, wherein said metallic heat conductive wire is formed from a mixture of a plurality of strands of copper wire or a plurality of strands of aluminum wire.

5. A fire blanket for gas cutting operations as recited in claim 4 wherein said metal heat conductive layer is woven in a plain weave construction.

6. The fire blanket for gas cutting work according to claim 3, wherein the upper surface insulation layer and the lower surface insulation layer are formed by weaving insulation wires formed of inorganic fireproof fibers in warp and weft, and the outer diameter of the insulation wires is larger than that of the metal heat conduction wires.

7. A fire blanket for gas cutting operations according to claim 6, wherein the heat insulating wire has an outer diameter of 3mm to 6mm and the metal heat conducting wire has an outer diameter of 1mm to 2 mm.

8. The fire blanket for gas cutting operations of claim 1, wherein the upper and lower surface insulation layers have a thickness of 2mm to 10 mm.

9. The fire blanket for gas cutting operation as claimed in claim 1, wherein the inorganic fire-proof fiber is one or more of ceramic fiber, glass fiber, fire-retardant carbon fiber and asbestos fiber.

10. A fire blanket for gas cutting operations as recited in claim 1, wherein a layer of fire retardant paint is applied over said upper surface insulation layer.

Technical Field

The invention relates to the technical field of safety protection articles, in particular to a fireproof blanket for gas cutting operation, which is mainly used for protecting adjacent equipment during gas cutting operation.

Background

When gas cutting operation is carried out, the tail part of the flame can possibly blow the adjacent equipment, so that the equipment is damaged, and safety accidents are caused when the equipment is serious. A straightforward solution to this problem is to use fire blankets for protection.

The danger analysis and research work of the fire operation of a nuclear power plant shows that the most common high-temperature vulnerable equipment is cables and electrical elements, because the upper limit temperature of the chemical stability of organic materials does not exceed 120 ℃ generally; the objects to be protected are therefore primarily cables and their sleeves, housings for electrical equipment, cable trays. Relevant statistics show that the longest working time of a single oxyacetylene cutting operation is about 15min, the average time is 9min, and the time for the flame to stably face a certain direction is about 2.5 min. The length of the oxyacetylene flame is about 15cm, the diameter of the widest part is 2cm, and the shortest distance between the oxyacetylene flame and the adjacent equipment is 5 cm-10 cm through experimental measurement; the flame core temperature is about 2200 ℃, the flame jet entrains the mixed ambient air, the downstream temperature drops rapidly with increasing distance, but the temperature can still be as high as 600 ℃ to 1100 ℃ over a distance of 5cm to 10 cm.

Chinese patent publication No. CN210652116U discloses a welded fire blanket, which is provided with an aramid fiber flame retardant fabric, a glass fiber layer and an acrylic cotton flame retardant fabric to improve the flame retardant property of the fire blanket. The fire blanket has the problems that the material composition of the fire blanket comprises more organic matters, the fire blanket can be ablated by gas cutting flame in a short time, and toxic gas is released.

Chinese patent publication No. CN210472847U discloses a fire blanket for construction, which is mainly formed by weaving glass fiber yarns and carbon fiber yarns; the fireproof blanket is woven by selecting the alkali-resistant glass fiber yarns and the carbon fiber glass yarns, so that the fireproof blanket has high temperature resistance, high alkali corrosion resistance, high impact resistance and high tensile strength, is non-combustible, and can play good fireproof and heat insulation effects. The fireproof blanket is used for building protection, is made of fireproof inorganic fibers and can be used for blocking gas cutting flame; however, the material has high heat insulation capability and low thermal diffusivity, and can form high local high temperature on a heating point with stable flame, so that the material is likely to penetrate through a fireproof blanket to scald equipment below.

It can be seen that a disadvantage of the existing fire blankets is the insufficient resistance to local heating by the gas cutting flame.

Disclosure of Invention

The present invention is directed to overcoming the deficiencies of the prior art and providing a fire blanket for gas cutting operations that has the ability to block gas cutting flames and prevent localized overheating.

In order to solve the technical problems, the scheme is realized by the following technical scheme:

a fire blanket for gas cutting operation comprises an upper surface heat insulation layer, a metal heat conduction layer and a lower surface heat insulation layer which are sequentially arranged along the thickness direction of the fire blanket, wherein the upper surface heat insulation layer and the lower surface heat insulation layer are both made of inorganic fireproof fiber materials or materials taking inorganic fireproof fibers as main bodies; the metal heat conduction layer is formed by copper or aluminum braided fabric or mainly formed by copper or aluminum braided fabric.

Preferably, the thickness of the metal heat conduction layer is 1.5mm to 3 mm.

Preferably, the metal heat conduction layer is formed by weaving metal heat conduction wires in a warp-weft mode, and the metal heat conduction wires are copper wires or aluminum wires.

Preferably, the metal heat conducting wire is formed by mixing a plurality of strands of copper wires or a plurality of strands of aluminum wires.

Preferably, the metal heat conduction layer is woven in a plain weave structure.

Preferably, the upper surface heat insulating layer and the lower surface heat insulating layer are formed by weaving heat insulating threads made of inorganic fireproof fibers, and the outer diameter of the heat insulating threads is larger than the outer diameter of the metal heat conducting threads.

Preferably, the heat insulating wire has an outer diameter of 3mm to 6mm, and the metal heat conductive wire has an outer diameter of 1mm to 2 mm.

Preferably, the upper surface heat insulation layer and the lower surface heat insulation layer have a thickness of 2mm to 10 mm.

Preferably, the inorganic fireproof fiber is one or a composite of several of ceramic fiber, glass fiber, flame-retardant carbon fiber and asbestos fiber.

Preferably, a fireproof paint layer is coated on the upper surface heat insulation layer.

Compared with the prior art, the invention has the beneficial effects that:

the invention arranges a metal heat conduction layer between two heat insulation layers, which is woven by copper or aluminum wires. Since copper and aluminum have high thermal conductivity, the heat conducting layer can rapidly spread local heat. Therefore, the fireproof blanket provided by the invention has good heat insulation capability in the thickness direction and good heat diffusion capability in the length and width directions, can diffuse heat applied to a local area by gas cutting flame along the surface, and improves the capability of preventing local scald.

In addition, the fireproof blanket has good water absorption capacity, before and during use, each layer of structure is in an infiltration state by water spraying, and the protection capacity for electrical equipment is improved by utilizing the characteristics that water is heated and evaporated to carry away a large amount of vaporization heat and control the temperature to be less than or equal to 100 ℃.

Drawings

FIG. 1 is a schematic structural view of examples 1 and 2;

FIG. 2 is a schematic structural view of embodiment 3;

fig. 3 is a schematic structural view of embodiment 4.

In the above drawings:

1 is an upper surface heat insulation layer, 2 is a metal heat conduction layer, 3 is a lower surface heat insulation layer, 11 is a heat insulation line, and 12 is a metal heat conduction line.

Detailed Description

The following detailed description of embodiments of the present product is made with reference to the accompanying drawings:

the present application provides various forms of fire blankets, all following a basic principle, as shown in fig. 1: spatially, the device mainly comprises three layers of structures: an upper surface heat insulation layer 1, a lower surface heat insulation layer 3 and a metal heat conduction layer 2 sandwiched in the middle.

The upper surface heat insulation layer 1 and the lower surface heat insulation layer 3 are made of inorganic fireproof fibers or materials taking the inorganic fireproof fibers as main bodies; inorganic fire-resistant fibers include ceramic fibers, glass fibers, flame-retardant carbon fibers, asbestos fibers, and composites thereof.

The metal heat conducting layer 2 is a braided fabric of copper or aluminum, or is mainly composed of a braided fabric of copper or aluminum.

The area of the fire blanket is selected from 0.25 square meter to 1.0 square meter. Can be used singly or by overlapping a plurality of blocks. When the fireproof blanket is used, water can be uniformly sprayed on the surface of the fireproof blanket to soak each layer of structure.

Example 1

A fire blanket for gas cutting operations, as shown in fig. 1: the heat-insulating layer mainly comprises a three-layer structure, and comprises an upper heat-insulating layer 1, a lower heat-insulating layer 3 and a metal heat-conducting layer 2 sandwiched in the middle. The upper surface heat insulation layer 1 and the lower surface heat insulation layer 3 are made of inorganic fireproof fiber cloth; the metal heat conduction layer 2 is an aluminum wire braided layer; stainless steel wire stitching or stainless steel staples (like carton staples) are used.

The upper surface heat insulation layer 1 and the lower surface heat insulation layer 3 can be selected from an aluminum silicate fiber felt, a flame-retardant carbon fiber composite fabric or non-woven fabric and a glass fiber felt; the thickness is chosen between 2mm and 10mm, preferably 6mm in this embodiment. The thickness of the metal heat conducting layer 2 is selected from 1.5mm to 3mm, and the thickness of the metal heat conducting layer is preferably 3mm in the embodiment. The material of the stainless steel wire or nail is austenitic stainless steel (with good gas cutting resistance).

Example 2

A fire blanket for gas cutting operations, as shown in fig. 1: the three-layer composite fabric is similar to a three-layer composite fabric and mainly comprises three layers of tissues, namely a warp direction and a weft direction are respectively interwoven by adopting three threads of different systems, and three single-layer braided fabrics are connected together to form a whole. The upper surface warp, the upper surface weft, the lower surface warp and the lower surface weft all adopt heat insulation wires to form an upper surface heat insulation layer 1 and a lower surface heat insulation layer 3, and the middle warp and the middle weft adopt metal heat conduction wires to form a metal heat conduction layer 2.

Typically, the three layers of weave are all plain weave, the insulating thread is twisted by aluminium silicate fibre, and the outline external diameter is 3 mm. The metal heat conducting wires consist of 7 strands of 0.2 square millimeter copper wires.

Example 3

A fire blanket for gas cutting operations, as shown in fig. 2: the warp and weft are in the form of heat insulating lines 11 and metal heat conducting lines 12 which are alternately arranged in a single-layer plain weave structure. Wherein, the heat insulation line 11 is twisted by fireproof fiber, and the metal heat conduction line 12 is of a multi-strand fine copper wire structure. The insulated wires 11 have a larger profile outer diameter than the metal heat-conducting wires 12 (note: in the top view of the upper half of fig. 2, the outer diameter of the insulated wires 11 is the same as the outer diameter of the metal heat-conducting wires 12 for convenience of expressing the fabric structure).

Typically, the insulating threads 11 are twisted from aluminium silicate fibres or asbestos fibres with a profile external diameter of 3mm and the metallic heat-conducting threads 12 are constituted by 7 strands of 0.2 square mm copper wire.

By virtue of the compact weave, the main volume of the insulating yarn 11 occupies both the upper and lower faces of the fire blanket. From the point of view of the weaving structure, this is a single layer structure, but from the point of view of the distribution of the spatial objects, a three-layer structure is formed, the wire bodies of the heat-insulating threads 11 occupying the upper and lower faces of the fire blanket constitute the upper and lower heat-insulating layers 1 and 3, and the metal heat-conducting threads 12 sandwiched therebetween constitute the metal heat-conducting layer 2.

In addition, preferably, the rule of the warp and weft sinking and floating with each other can be adjusted to form a structure similar to a twill weave or a satin weave, and the period of the heat insulating lines 11 and the metal heat conducting lines 12 can also be adjusted.

More preferably, a layer of fire-retardant coating can be coated on the upper surface of the upper heat-insulating layer 1 to fill the gap and prevent the metal heat-conducting wires 12 from being exposed to flame.

Example 4

A fire blanket for gas cutting operations, as shown in fig. 3: the warp and weft are in the form of heat insulation wires 11 and metal heat conduction wires 12 which are alternately arranged in a basic organization structure. The heat insulating wire 11 and the adjacent one of the metal heat conductive wires 12 follow the same sinking and floating rule. Wherein, the heat insulation line 11 is twisted by fireproof fiber, and the metal heat conduction line 12 is a multi-strand thin aluminum wire structure. The insulated wires 11 have a larger profile outer diameter than the metal heat-conducting wires 12 (note: in the top view of the upper half of fig. 3, the outer diameter of the insulated wires 11 is the same as the outer diameter of the metal heat-conducting wires 12 for convenience of expressing the fabric structure).

The outer diameter of the profile of the heat insulating wire 11 may be selected from 4mm to 8mm, and the outer diameter of the profile of the metal heat conductive wire 12 may be selected from 2mm to 3 mm. Typically, the heat insulating thread 11 is twisted from inorganic fire-resistant fibres with an outer diameter of 5mm profile and the metallic heat conducting thread 12 is constituted by 7 strands of 0.5 mm square aluminium wire.

It can be seen that all the metallic heat-conducting wires 12 alone constitute a plain weave structure, being a stable frame, able to carry the heat-insulating wires 11, which impose length redundancies to maintain the slack state without affecting the overall structural stability. By means of the compact weaving and the lengthy application of the insulating threads 11, the main volume of the insulating threads 11 occupies both the upper and lower faces of the fire blanket. From the point of view of the weaving structure, this is a single layer structure, but from the point of view of the distribution of the spatial objects, a three-layer structure is formed, the wire bodies of the heat-insulating threads 11 occupying the upper and lower faces of the fire blanket constitute the upper and lower heat-insulating layers 1 and 3, and the metal heat-conducting threads 12 sandwiched therebetween constitute the metal heat-conducting layer 2.

In addition, the rules of the warp and weft sinking and floating can be adjusted to form a twill weave or satin weave structure, but it is necessary to ensure that the metal heat conduction wires 12 independently form a basic weave structure, especially a plain weave structure.

In addition, since the metal heat-conducting wires 12 themselves constitute a stable structure alone, the heat-insulating wires can be present only in one of the warp direction or the weft direction, which is advantageous in simplifying the weaving process.