CN106144400B - One kind securely transmits band - Google Patents
One kind securely transmits band Download PDFInfo
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- CN106144400B CN106144400B CN201610719808.4A CN201610719808A CN106144400B CN 106144400 B CN106144400 B CN 106144400B CN 201610719808 A CN201610719808 A CN 201610719808A CN 106144400 B CN106144400 B CN 106144400B
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- carbon nanotube
- composite fibre
- wrapping layer
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G15/00—Conveyors having endless load-conveying surfaces, i.e. belts and like continuous members, to which tractive effort is transmitted by means other than endless driving elements of similar configuration
- B65G15/30—Belts or like endless load-carriers
-
- D—TEXTILES; PAPER
- D01—NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
- D01F—CHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
- D01F1/00—General methods for the manufacture of artificial filaments or the like
- D01F1/02—Addition of substances to the spinning solution or to the melt
- D01F1/09—Addition of substances to the spinning solution or to the melt for making electroconductive or anti-static filaments
-
- D—TEXTILES; PAPER
- D01—NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
- D01F—CHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
- D01F6/00—Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof
- D01F6/44—Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from mixtures of polymers obtained by reactions only involving carbon-to-carbon unsaturated bonds as major constituent with other polymers or low-molecular-weight compounds
- D01F6/46—Monocomponent artificial filaments or the like of synthetic polymers; Manufacture thereof from mixtures of polymers obtained by reactions only involving carbon-to-carbon unsaturated bonds as major constituent with other polymers or low-molecular-weight compounds of polyolefins
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- Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Chemical Kinetics & Catalysis (AREA)
- General Chemical & Material Sciences (AREA)
- Textile Engineering (AREA)
- Mechanical Engineering (AREA)
- Manufacturing & Machinery (AREA)
- Artificial Filaments (AREA)
- Compositions Of Macromolecular Compounds (AREA)
Abstract
This application involves one kind to securely transmit band, and including upper wrapping layer, lower wrapping layer and casing play, the casing play is set between the upper wrapping layer and lower wrapping layer, and the upper wrapping layer is equipped with block.
Description
Technical field
This application involves conveyer belt fields more particularly to one kind to securely transmit band.
Background technology
Electrostatic is since friction generates, and with the development of electronics industry, the harm that electrostatic is brought to the mankind is increasing, than
Such as, electrostatic can influence safety with the normal operation of wireless device on countermeasure aircraft;Electrostatic easily adsorbs dust, causes pharmacy
The environment cleanliness such as factory require high place pollution;For human body, electrostatic may influence various diseases, etc. in human body accumulation.
Antistatic coating is coated in product surface, electrostatic is eliminated so that the more stable longer life expectancy of its performance by improving surface conductivity
It is very important.
Conveyer belt is used for transporting the work-saving device of article, and since article contacts with conveyer belt, rubs, surface can generate greatly
Accumulation of static electricity is measured, security risk is caused to operator.
Invention content
The present invention is intended to provide one kind securely transmits band, it is set forth above to solve the problems, such as.
One kind is provided in the embodiment of the present invention and securely transmits band, including upper wrapping layer, lower wrapping layer and casing play, institute
It states casing play to be set between the upper wrapping layer and lower wrapping layer, the upper wrapping layer is equipped with block, and the upper wrapping layer is under
It wraps up layer surface and is equipped with anti-electrostatic polymer composite fibre, the anti-electrostatic polymer composite fibre is contacted with antistatic chain, institute
The antistatic chain other end is stated to contact with the earth.
The technical solution that the embodiment of the present invention provides can include the following benefits:
The upper wrapping layer of conveyer belt of the present invention and lower package layer surface are made equipped with anti-electrostatic polymer composite fibre, this is multiple
Condensating fiber is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler so that it is antistatic with good electric conductivity
Property is stronger, set forth above so as to solve the problems, such as.
The additional aspect of the application and advantage will be set forth in part in the description, and will partly become from the following description
It obtains significantly or is recognized by the practice of the application.It should be understood that above general description and following detailed description are only
It is exemplary and explanatory, the application can not be limited.
Description of the drawings
Using attached drawing, the invention will be further described, but the embodiment in attached drawing does not form any limit to the present invention
System, for those of ordinary skill in the art, without creative efforts, can also obtain according to the following drawings
Other attached drawings.
Fig. 1 is the structure diagram of conveyer belt of the present invention.
Fig. 2 is the production process figure of composite fibre of the present invention.
Specific embodiment
Here exemplary embodiment will be illustrated in detail, example is illustrated in the accompanying drawings.Following description is related to
During attached drawing, unless otherwise indicated, the same numbers in different attached drawings represent the same or similar element.Following exemplary embodiment
Described in embodiment do not represent and the consistent all embodiments of the present invention.On the contrary, they be only with it is such as appended
The example of the consistent device and method of some aspects being described in detail in claims, of the invention.
Electrostatic is since friction generates, and with the development of electronics industry, the harm that electrostatic is brought to the mankind is increasing, than
Such as, electrostatic can influence safety with the normal operation of wireless device on countermeasure aircraft;Electrostatic easily adsorbs dust, causes pharmacy
The environment cleanliness such as factory require high place pollution;For human body, electrostatic may influence various diseases, etc. in human body accumulation.
Antistatic coating is coated in product surface, electrostatic is eliminated so that the more stable longer life expectancy of its performance by improving surface conductivity
It is very important.
Conducting polymer composite material be using polymer material be substrate addition with high conduction performance it is organic and inorganic,
The conductive fillers such as metal make it disperse in the base so as to form conductive composite material by various means.At present
The selection of conductive filler, the formation of conductive network etc. are concentrated mainly on to the research of conducing composite material;Polymer fiber
Has the advantages that cheap, quality is light, specific strength is big, thermal conductivity factor is small, chemical property is stablized, so as to be widely used in giving birth to
Various fields of recent life is produced, still, most polymers are good electrical insulators, and appearance is easy to produce static electricity, limits its application.
At present, encountering problems mainly for polymer conductive fibre has:Fiber drawing process causes conductive filler spacing to increase
Greatly, conductive network destroys, and conductivity threshold is caused to increase, fibrous mechanical property is poor;Single conductive filler is due to nano-particle
Reunite, cause conductive nano filler conductive network less efficient, conductivity threshold is high.
Application scenarios one:
Embodiments herein is related to one kind and securely transmits band, by Fig. 1, including upper wrapping layer 1, lower wrapping layer 2 and skeleton
Layer 3, the casing play 3 be set between the upper wrapping layer 1 and lower wrapping layer 2, the upper wrapping layer 1 be equipped with block, it is described on
Wrapping layer 1 and lower 2 surface of wrapping layer are equipped with anti-electrostatic polymer composite fibre, the anti-electrostatic polymer composite fibre with prevent it is quiet
Current source contacts, and the antistatic chain other end is contacted with the earth.
The upper wrapping layer of conveyer belt of the present invention and lower package layer surface are made equipped with anti-electrostatic polymer composite fibre, this is multiple
Condensating fiber is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler so that it is antistatic with good electric conductivity
Property is stronger.
Preferably, the composite fibre is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler, antistatic property
It is relatively strong.
In the composite fibre of the embodiment of the present invention, using carbon nanotube, low-melting-point metal, the carbon nanotube is for filler
Multi-walled carbon nanotube, has good electric conductivity, excellent in mechanical performance, and in annealing process, carbon nanotube can be returned to
Curling or winding state, carbon nanotube mutually has a common boundary to form the first heavy conductive network, and the mechanical property that carbon nanotube is excellent
After can ensureing that precursor is stretched, conductive network is not destroyed in composite fibre.
Preferably, in the composite fibre, content of carbon nanotubes is 0.1~5vol%, and carbon nanotube is hanged by platinum grain
Supernatant liquid processing;The low-melting-point metal is sn-bi alloy, terne metal, and sn-bi alloy content is 0.1~1.5%, terne metal
Content is 0.1%, and the sn-bi alloy, terne metal grain size are 20~30 μm.
In the composite fibre of the embodiment of the present invention, carbon nanotube is handled by platinum grain suspension, and surface is embedded with platinum
Grain in annealing process, is blended, and then received with carbon in the low-melting-point metal of molten state and the platinum grain of carbon nano tube surface
Mitron is inlayed together, and after drawing process, molten state low-melting-point metal is stretched, and is formed the second heavy conductive network, is further increased
The conductivity of composite fibre is added;Also, after making annealing treatment, metallic particles mutually merges in composite fibre, and contact point is reduced, connect
Resistance of getting an electric shock reduces.
Preferably, calcium carbonate is also contained in the composite fibre, the calcium carbonate content is 0.6w%.
In the composite fibre of the application, inorganic particle calcium carbonate is further increased, since the volume of calcium carbonate discharges effect
Should, the excess effusion value of composite fibre can be effectively reduced, while contribute to the dispersion of carbon nanotube, improve the networking effect of conductive network
Rate.
Still more preferably, such as Fig. 2, the making step of the composite fibre is as follows:
Step 1, carbon nanotube processing:
First, compound concentration 10- 4M chloroplatinic acids and a concentration of 10- 5The reaction solution of M polyvinylpyrrolidones, to reaction
High-purity argon gas bubbling 30min is passed through in solution, the oxygen in liquid is removed, is then equally passed through hydrogen 10min and is restored, with
Reaction solution sealing is protected from light afterwards and stands 12h, in the reaction system, the platinum grain growth of 5nm or so obtains platinum grain suspension
Liquid;
The multi-walled carbon nanotube of purchase is taken, length is 50~500 μm, is dipped into more than 1h in above-mentioned suspension, by
It is 5nm or so in platinum grain, grain size is smaller, and platinum grain can be embedded in surface or the fault location of multi-walled carbon nanotube;
Step 2 prepares mixture:
By sn-bi alloy, terne metal, carbon nanotube, antioxidant 1010, antioxidant 168, zinc stearate, calcium carbonate
It is uniformly mixed in homogenizer by proportioning with polypropylene granules, then with extruder extruding pelletization, obtains compound particles;
(wherein, sn-bi alloy, terne metal grain size are 20~30 μm, and sn-bi alloy content is 0.1~1.5%, and slicker solder closes
Gold content be 0.1~2%, content of carbon nanotubes be 0.1~5vol%, antioxidant 1010 content be 0.1w%, antioxidant
168 contents are 0.1w%, and zinc stearate content is 0.25w%, calcium carbonate content 0.6w%);
Step 3 prepares precursor:
Said mixture particle at 80 DEG C is dried into 4h, is then precursor by its spinning using capillary rheometer;
Step 4 prepares anti-electrostatic polymer composite material:
Upper step is obtained into precursor and makes annealing treatment 5h at 180 DEG C, then Uniform Tension, extends 5 with 10mm/min speed tensiles
~20 times, obtain anti-electrostatic polymer composite fibre.
Application scenarios two:
Embodiments herein is related to one kind and securely transmits band, by Fig. 1, including upper wrapping layer 1, lower wrapping layer 2 and skeleton
Layer 3, the casing play 3 be set between the upper wrapping layer 1 and lower wrapping layer 2, the upper wrapping layer 1 be equipped with block, it is described on
Wrapping layer 1 and lower 2 surface of wrapping layer are equipped with anti-electrostatic polymer composite fibre, the anti-electrostatic polymer composite fibre with prevent it is quiet
Current source contacts, and the antistatic chain other end is contacted with the earth.
The upper wrapping layer of conveyer belt of the present invention and lower package layer surface are made equipped with anti-electrostatic polymer composite fibre, this is multiple
Condensating fiber is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler so that it is antistatic with good electric conductivity
Property is stronger.
Preferably, the composite fibre is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler, antistatic property
It is relatively strong.
In the composite fibre of the embodiment of the present invention, using carbon nanotube, low-melting-point metal, the carbon nanotube is for filler
Multi-walled carbon nanotube, has good electric conductivity, excellent in mechanical performance, and in annealing process, carbon nanotube can be returned to
Curling or winding state, carbon nanotube mutually has a common boundary to form the first heavy conductive network, and the mechanical property that carbon nanotube is excellent
After can ensureing that precursor is stretched, conductive network is not destroyed in composite fibre.
Preferably, in the composite fibre, content of carbon nanotubes is 0.1~5vol%, and carbon nanotube is hanged by platinum grain
Supernatant liquid processing;The low-melting-point metal is sn-bi alloy, terne metal, and sn-bi alloy content is 0.1~1.5%, terne metal
Content is 0.5%, and the sn-bi alloy, terne metal grain size are 20~30 μm.
In the composite fibre of the embodiment of the present invention, carbon nanotube is handled by platinum grain suspension, and surface is embedded with platinum
Grain in annealing process, is blended, and then received with carbon in the low-melting-point metal of molten state and the platinum grain of carbon nano tube surface
Mitron is inlayed together, and after drawing process, molten state low-melting-point metal is stretched, and is formed the second heavy conductive network, is further increased
The conductivity of composite fibre is added;Also, after making annealing treatment, metallic particles mutually merges in composite fibre, and contact point is reduced, connect
Resistance of getting an electric shock reduces.
Preferably, calcium carbonate is also contained in the composite fibre, the calcium carbonate content is 0.6w%.
In the composite fibre of the application, inorganic particle calcium carbonate is further increased, since the volume of calcium carbonate discharges effect
Should, the excess effusion value of composite fibre can be effectively reduced, while contribute to the dispersion of carbon nanotube, improve the networking effect of conductive network
Rate.
Still more preferably, such as Fig. 2, the making step of the composite fibre is as follows:
Step 1, carbon nanotube processing:
First, compound concentration 10- 4M chloroplatinic acids and a concentration of 10- 5The reaction solution of M polyvinylpyrrolidones, to reaction
High-purity argon gas bubbling 30min is passed through in solution, the oxygen in liquid is removed, is then equally passed through hydrogen 10min and is restored, with
Reaction solution sealing is protected from light afterwards and stands 12h, in the reaction system, the platinum grain growth of 5nm or so obtains platinum grain suspension
Liquid;
The multi-walled carbon nanotube of purchase is taken, length is 50~500 μm, is dipped into more than 1h in above-mentioned suspension, by
It is 5nm or so in platinum grain, grain size is smaller, and platinum grain can be embedded in surface or the fault location of multi-walled carbon nanotube;
Step 2 prepares mixture:
By sn-bi alloy, terne metal, carbon nanotube, antioxidant 1010, antioxidant 168, zinc stearate, calcium carbonate
It is uniformly mixed in homogenizer by proportioning with polypropylene granules, then with extruder extruding pelletization, obtains compound particles;
Step 3 prepares precursor:
Said mixture particle at 80 DEG C is dried into 4h, is then precursor by its spinning using capillary rheometer;
Step 4 prepares anti-electrostatic polymer composite fibre:
Upper step is obtained into precursor and makes annealing treatment 5h at 180 DEG C, then Uniform Tension, extends 5 with 10mm/min speed tensiles
~20 times, obtain anti-electrostatic polymer composite fibre.
Application scenarios three:
Embodiments herein is related to one kind and securely transmits band, by Fig. 1, including upper wrapping layer 1, lower wrapping layer 2 and skeleton
Layer 3, the casing play 3 be set between the upper wrapping layer 1 and lower wrapping layer 2, the upper wrapping layer 1 be equipped with block, it is described on
Wrapping layer 1 and lower 2 surface of wrapping layer are equipped with anti-electrostatic polymer composite fibre, the anti-electrostatic polymer composite fibre with prevent it is quiet
Current source contacts, and the antistatic chain other end is contacted with the earth.
The upper wrapping layer of conveyer belt of the present invention and lower package layer surface are made equipped with anti-electrostatic polymer composite fibre, this is multiple
Condensating fiber is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler so that it is antistatic with good electric conductivity
Property is stronger.
Preferably, the composite fibre is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler, antistatic property
It is relatively strong.
In the composite fibre of the embodiment of the present invention, using carbon nanotube, low-melting-point metal, the carbon nanotube is for filler
Multi-walled carbon nanotube, has good electric conductivity, excellent in mechanical performance, and in annealing process, carbon nanotube can be returned to
Curling or winding state, carbon nanotube mutually has a common boundary to form the first heavy conductive network, and the mechanical property that carbon nanotube is excellent
After can ensureing that precursor is stretched, conductive network is not destroyed in composite fibre.
Preferably, in the composite fibre, content of carbon nanotubes is 0.1~5vol%, and carbon nanotube is hanged by platinum grain
Supernatant liquid processing;The low-melting-point metal is sn-bi alloy, terne metal, and sn-bi alloy content is 0.1~1.5%, terne metal
Content is 1%, and the sn-bi alloy, terne metal grain size are 20~30 μm.
In the composite fibre of the embodiment of the present invention, carbon nanotube is handled by platinum grain suspension, and surface is embedded with platinum
Grain in annealing process, is blended, and then received with carbon in the low-melting-point metal of molten state and the platinum grain of carbon nano tube surface
Mitron is inlayed together, and after drawing process, molten state low-melting-point metal is stretched, and is formed the second heavy conductive network, is further increased
The conductivity of composite fibre is added;Also, after making annealing treatment, metallic particles mutually merges in composite fibre, and contact point is reduced, connect
Resistance of getting an electric shock reduces.
Preferably, calcium carbonate is also contained in the composite fibre, the calcium carbonate content is 0.6w%.
In the composite fibre of the application, inorganic particle calcium carbonate is further increased, since the volume of calcium carbonate discharges effect
Should, the excess effusion value of composite fibre can be effectively reduced, while contribute to the dispersion of carbon nanotube, improve the networking effect of conductive network
Rate.
Still more preferably, such as Fig. 2, the making step of the composite fibre is as follows:
Step 1, carbon nanotube processing:
First, compound concentration 10- 4M chloroplatinic acids and a concentration of 10- 5The reaction solution of M polyvinylpyrrolidones, to reaction
High-purity argon gas bubbling 30min is passed through in solution, the oxygen in liquid is removed, is then equally passed through hydrogen 10min and is restored, with
Reaction solution sealing is protected from light afterwards and stands 12h, in the reaction system, the platinum grain growth of 5nm or so obtains platinum grain suspension
Liquid;
The multi-walled carbon nanotube of purchase is taken, length is 50~500 μm, is dipped into more than 1h in above-mentioned suspension, by
It is 5nm or so in platinum grain, grain size is smaller, and platinum grain can be embedded in surface or the fault location of multi-walled carbon nanotube;
Step 2 prepares mixture:
By sn-bi alloy, terne metal, carbon nanotube, antioxidant 1010, antioxidant 168, zinc stearate, calcium carbonate
It is uniformly mixed in homogenizer by proportioning with polypropylene granules, then with extruder extruding pelletization, obtains compound particles;
Step 3 prepares precursor:
Said mixture particle at 80 DEG C is dried into 4h, is then precursor by its spinning using capillary rheometer;
Step 4 prepares anti-electrostatic polymer composite fibre:
Upper step is obtained into precursor and makes annealing treatment 5h at 180 DEG C, then Uniform Tension, extends 5 with 10mm/min speed tensiles
~20 times, obtain anti-electrostatic polymer composite fibre.
Application scenarios four:
Embodiments herein is related to one kind and securely transmits band, by Fig. 1, including upper wrapping layer 1, lower wrapping layer 2 and skeleton
Layer 3, the casing play 3 be set between the upper wrapping layer 1 and lower wrapping layer 2, the upper wrapping layer 1 be equipped with block, it is described on
Wrapping layer 1 and lower 2 surface of wrapping layer are equipped with anti-electrostatic polymer composite fibre, the anti-electrostatic polymer composite fibre with prevent it is quiet
Current source contacts, and the antistatic chain other end is contacted with the earth.
The upper wrapping layer of conveyer belt of the present invention and lower package layer surface are made equipped with anti-electrostatic polymer composite fibre, this is multiple
Condensating fiber is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler so that it is antistatic with good electric conductivity
Property is stronger.
Preferably, the composite fibre is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler, antistatic property
It is relatively strong.
In the composite fibre of the embodiment of the present invention, using carbon nanotube, low-melting-point metal, the carbon nanotube is for filler
Multi-walled carbon nanotube, has good electric conductivity, excellent in mechanical performance, and in annealing process, carbon nanotube can be returned to
Curling or winding state, carbon nanotube mutually has a common boundary to form the first heavy conductive network, and the mechanical property that carbon nanotube is excellent
After can ensureing that precursor is stretched, conductive network is not destroyed in composite fibre.
Preferably, in the composite fibre, content of carbon nanotubes is 0.1~5vol%, and carbon nanotube is hanged by platinum grain
Supernatant liquid processing;The low-melting-point metal is sn-bi alloy, terne metal, and sn-bi alloy content is 0.1~1.5%, terne metal
Content is 1.5%, and the sn-bi alloy, terne metal grain size are 20~30 μm.
In the composite fibre of the embodiment of the present invention, carbon nanotube is handled by platinum grain suspension, and surface is embedded with platinum
Grain in annealing process, is blended, and then received with carbon in the low-melting-point metal of molten state and the platinum grain of carbon nano tube surface
Mitron is inlayed together, and after drawing process, molten state low-melting-point metal is stretched, and is formed the second heavy conductive network, is further increased
The conductivity of composite fibre is added;Also, after making annealing treatment, metallic particles mutually merges in composite fibre, and contact point is reduced, connect
Resistance of getting an electric shock reduces.
Preferably, calcium carbonate is also contained in the composite fibre, the calcium carbonate content is 0.6w%.
In the composite fibre of the application, inorganic particle calcium carbonate is further increased, since the volume of calcium carbonate discharges effect
Should, the excess effusion value of composite fibre can be effectively reduced, while contribute to the dispersion of carbon nanotube, improve the networking effect of conductive network
Rate.
Still more preferably, such as Fig. 2, the making step of the composite fibre is as follows:
Step 1, carbon nanotube processing:
First, compound concentration 10- 4M chloroplatinic acids and a concentration of 10- 5The reaction solution of M polyvinylpyrrolidones, to reaction
High-purity argon gas bubbling 30min is passed through in solution, the oxygen in liquid is removed, is then equally passed through hydrogen 10min and is restored, with
Reaction solution sealing is protected from light afterwards and stands 12h, in the reaction system, the platinum grain growth of 5nm or so obtains platinum grain suspension
Liquid;
The multi-walled carbon nanotube of purchase is taken, length is 50~500 μm, is dipped into more than 1h in above-mentioned suspension, by
It is 5nm or so in platinum grain, grain size is smaller, and platinum grain can be embedded in surface or the fault location of multi-walled carbon nanotube;
Step 2 prepares mixture:
By sn-bi alloy, terne metal, carbon nanotube, antioxidant 1010, antioxidant 168, zinc stearate, calcium carbonate
It is uniformly mixed in homogenizer by proportioning with polypropylene granules, then with extruder extruding pelletization, obtains compound particles;
Step 3 prepares precursor:
Said mixture particle at 80 DEG C is dried into 4h, is then precursor by its spinning using capillary rheometer;
Step 4 prepares anti-electrostatic polymer composite fibre:
Upper step is obtained into precursor and makes annealing treatment 5h at 180 DEG C, then Uniform Tension, extends 5 with 10mm/min speed tensiles
~20 times, obtain anti-electrostatic polymer composite fibre.
Application scenarios five:
Embodiments herein is related to one kind and securely transmits band, by Fig. 1, including upper wrapping layer 1, lower wrapping layer 2 and skeleton
Layer 3, the casing play 3 be set between the upper wrapping layer 1 and lower wrapping layer 2, the upper wrapping layer 1 be equipped with block, it is described on
Wrapping layer 1 and lower 2 surface of wrapping layer are equipped with anti-electrostatic polymer composite fibre, the anti-electrostatic polymer composite fibre with prevent it is quiet
Current source contacts, and the antistatic chain other end is contacted with the earth.
The upper wrapping layer of conveyer belt of the present invention and lower package layer surface are made equipped with anti-electrostatic polymer composite fibre, this is multiple
Condensating fiber is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler so that it is antistatic with good electric conductivity
Property is stronger.
Preferably, the composite fibre is using polypropylene as matrix, and carbon nanotube and low-melting-point metal are filler, antistatic property
It is relatively strong.
In the composite fibre of the embodiment of the present invention, using carbon nanotube, low-melting-point metal, the carbon nanotube is for filler
Multi-walled carbon nanotube, has good electric conductivity, excellent in mechanical performance, and in annealing process, carbon nanotube can be returned to
Curling or winding state, carbon nanotube mutually has a common boundary to form the first heavy conductive network, and the mechanical property that carbon nanotube is excellent
After can ensureing that precursor is stretched, conductive network is not destroyed in composite fibre.
Preferably, in the composite fibre, content of carbon nanotubes is 0.1~5vol%, and carbon nanotube is hanged by platinum grain
Supernatant liquid processing;The low-melting-point metal is sn-bi alloy, terne metal, and sn-bi alloy content is 0.1~1.5%, terne metal
Content is 2%, and the sn-bi alloy, terne metal grain size are 20~30 μm.
In the composite fibre of the embodiment of the present invention, carbon nanotube is handled by platinum grain suspension, and surface is embedded with platinum
Grain in annealing process, is blended, and then received with carbon in the low-melting-point metal of molten state and the platinum grain of carbon nano tube surface
Mitron is inlayed together, and after drawing process, molten state low-melting-point metal is stretched, and is formed the second heavy conductive network, is further increased
The conductivity of composite fibre is added;Also, after making annealing treatment, metallic particles mutually merges in composite fibre, and contact point is reduced, connect
Resistance of getting an electric shock reduces.
Preferably, calcium carbonate is also contained in the composite fibre, the calcium carbonate content is 0.6w%.
In the composite fibre of the application, inorganic particle calcium carbonate is further increased, since the volume of calcium carbonate discharges effect
Should, the excess effusion value of composite fibre can be effectively reduced, while contribute to the dispersion of carbon nanotube, improve the networking effect of conductive network
Rate.
Still more preferably, such as Fig. 2, the making step of the composite fibre is as follows:
Step 1, carbon nanotube processing:
First, compound concentration 10- 4M chloroplatinic acids and a concentration of 10- 5The reaction solution of M polyvinylpyrrolidones, to reaction
High-purity argon gas bubbling 30min is passed through in solution, the oxygen in liquid is removed, is then equally passed through hydrogen 10min and is restored, with
Reaction solution sealing is protected from light afterwards and stands 12h, in the reaction system, the platinum grain growth of 5nm or so obtains platinum grain suspension
Liquid;
The multi-walled carbon nanotube of purchase is taken, length is 50~500 μm, is dipped into more than 1h in above-mentioned suspension, by
It is 5nm or so in platinum grain, grain size is smaller, and platinum grain can be embedded in surface or the fault location of multi-walled carbon nanotube;
Step 2 prepares mixture:
By sn-bi alloy, terne metal, carbon nanotube, antioxidant 1010, antioxidant 168, zinc stearate, calcium carbonate
It is uniformly mixed in homogenizer by proportioning with polypropylene granules, then with extruder extruding pelletization, obtains compound particles;
Step 3 prepares precursor:
Said mixture particle at 80 DEG C is dried into 4h, is then precursor by its spinning using capillary rheometer;
Step 4 prepares anti-electrostatic polymer composite fibre:
Upper step is obtained into precursor and makes annealing treatment 5h at 180 DEG C, then Uniform Tension, extends 5 with 10mm/min speed tensiles
~20 times, obtain anti-electrostatic polymer composite fibre.
Those skilled in the art will readily occur to the present invention its after considering specification and putting into practice invention disclosed herein
Its embodiment.This application is intended to cover the present invention any variations, uses, or adaptations, these modifications, purposes or
Person's adaptive change follows the general principle of the present invention and including the undocumented common knowledge in the art of the application
Or conventional techniques.Description and embodiments are considered only as illustratively, and true scope and spirit of the invention are by following
Claim is pointed out.
It should be understood that the invention is not limited in the precision architecture for being described above and being shown in the drawings, and
And various modifications and changes may be made without departing from the scope thereof.The scope of the present invention is only limited by appended claim.
Claims (2)
1. one kind securely transmits band, including upper wrapping layer, lower wrapping layer and casing play, which is characterized in that the casing play is set on
Between the upper wrapping layer and lower wrapping layer, the upper wrapping layer is equipped with block;
The upper wrapping layer and lower package layer surface are equipped with anti-electrostatic polymer composite fibre;
For the composite fibre using polypropylene as matrix, multi-walled carbon nanotube and low-melting-point metal are filler;
In the composite fibre, multi-walled carbon nanotube content is 0.1~5vol%, and multi-walled carbon nanotube passes through platinum grain suspension
Processing;The low-melting-point metal is sn-bi alloy, terne metal, and sn-bi alloy content is 0.1~1.5%, terne metal content
It is 0.1%, the sn-bi alloy, terne metal grain size are 20~30 μm;Also contain calcium carbonate, the carbon in the composite fibre
Sour calcium content is 0.6wt%;
The making step of the composite fibre is as follows:
Step 1, multi-walled carbon nanotube processing:
First, compound concentration 10- 4M chloroplatinic acids and a concentration of 10- 5The reaction solution of M polyvinylpyrrolidones, to reaction solution
In be passed through high-purity argon gas bubbling 30min, remove the oxygen in liquid, be then equally passed through hydrogen 10min and restored, then will
Reaction solution sealing, which is protected from light, stands 12h, and in the reaction system, the platinum grain growth of 5nm or so obtains platinum grain suspension;
The multi-walled carbon nanotube of purchase is taken, length is 50~500 μm, more than 1h in above-mentioned suspension is dipped into, due to platinum
Particle is 5nm or so, and grain size is smaller, and platinum grain can be embedded in surface or the fault location of multi-walled carbon nanotube;
Step 2 prepares mixture:
By sn-bi alloy, terne metal, carbon nanotube, antioxidant 1010, antioxidant 168, zinc stearate, calcium carbonate and gather
Propylene pellet is uniformly mixed by proportioning in homogenizer, then with extruder extruding pelletization, obtains compound particles;
Wherein, antioxidant 1010 content is 0.1wt%, and 168 content of antioxidant is 0.1wt%, and zinc stearate content is
0.25wt%, calcium carbonate content 0.6wt%;
Step 3 prepares precursor:
Said mixture particle at 80 DEG C is dried into 4h, is then precursor by its spinning using capillary rheometer;
Step 4 prepares anti-electrostatic polymer composite material:
Upper step is obtained into precursor and makes annealing treatment 5h at 180 DEG C, then Uniform Tension, extends 5~20 with 10mm/min speed tensiles
Times, obtain the anti-electrostatic polymer composite fibre.
2. according to claim 1 securely transmit band, which is characterized in that the anti-electrostatic polymer composite fibre with it is anti-quiet
Current source contacts, and the antistatic chain other end is contacted with the earth.
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