CN205517292U - Press down bacterial type graphite alkene filtration membrane and filter equipment - Google Patents

Abstract

The utility model discloses a press down bacterial type graphite alkene filtration membrane and filter equipment can be effectively antibacterial in order to provide one kind, among filtered air harmful substance and designing. The utility model discloses press down bacterial type graphite alkene filtration membrane, including the antibacterial structure and the filtration of range upon range of setting, wherein, antibacterial structure include antibacterial substrate layer and local or whole nanometer silver particle coating that set up are gone up to antibacterial substrate layer one side at least, the filtration including filter the substrate layer and filter the substrate layer and at least simultaneously go up local or whole graphite alkene particle coating that set up, antibacterial substrate layer, filter the substrate layer and be the ventilated membrane.

Description

Antibacterial type Graphene filter membrane and defecator

Technical field

This utility model relates to a kind of antibacterial type Graphene filter membrane and defecator.

Background technology

Owing to air pollution has been a problem the most serious, along with increasing of haze weather, if not taking any safeguard procedures, it will suck multiple pollutant, harm people's is healthy.Therefore, indoor air filter becomes many people and should be the essential product of air pollution.

The core of decision indoor air filter effect is air filtration part, existing air filter typically only has the sand and dust in air and filters energy, there is no bactericidal action, it is therefore necessary to design a kind of rational in infrastructure, low cost and filtration, the air filter of good antimicrobial effect.

Utility model content

For the problems referred to above, this utility model provides a kind of rational in infrastructure, antibacterial, antibacterial type Graphene filter membrane that adsorption filtration is effective.

For reaching above-mentioned purpose, this utility model antibacterial type Graphene filter membrane, the bacteriostatic structure arranged including stacking and filtration, wherein,

Described bacteriostatic structure includes antibacterial substrate layer and the nano-Ag particles coating partially or fully arranged in described antibacterial substrate layer at least one side；

Described filtration includes filtering substrate layer and the Graphene grain coating partially or fully arranged in described filtering substrate layer at least one side；

Described antibacterial substrate layer, filtering substrate layer are ventilated membrane.

Further, the heating arrangement of the Graphene grain coating of heating and filtering structure is also included.

Specifically, described heating arrangement includes the non-conductive socket for switching on power, it is provided with conductive structure in described non-conductive socket, described bacteriostatic structure, filtration part are arranged in described non-conductive socket, described Graphene grain coating contacts conduction with described conductive structure, and described nanometer silver coating is arranged with described conductive structure spacing, insulation.

Specifically, described heating arrangement is the heating layer of cloth arranged with described filtration stacking, described heating includes some the Graphene heater wires that spacing is arranged, some strip electrode lines of spacing setting and many radial insulation lines, broadwise covered wire, with described Graphene heater wire as radial line, described electrode wires is parallel, described Graphene heater wire is crisscross arranged with described electrode wires, and the Graphene heater wire that each electrode wires is with more than two contacts conduction, by radial insulation line, broadwise covered wire, Graphene heater wire, electrode wires is woven together forming heating layer of cloth by textile technology.

Especially, the Graphene grain coating on described filtering substrate layer is continuous structure, or is interrupted structure, wherein,

Described Graphene grain coating is that continuous structure is: on described filtering substrate layer, whole Graphene granules are interconnected to form continuous structure；

Described Graphene grain coating is that interrupted structure is: be provided with some groups of Graphene grain coatings on described filtering substrate layer, whole Graphene granules in each group Graphene grain coating are interconnected to form continuous structure, and one group of Graphene grain coating arranges the interrupted structure of formation with other Graphene grain coating spacing organized.

Especially, the nano-Ag particles coating on described antibacterial substrate layer is continuous structure, or is interrupted structure, wherein,

Described nano-Ag particles coating is that continuous structure is: on described antibacterial substrate layer, whole nano-Ag particles are interconnected to form continuous structure；

Described nano-Ag particles coating is that interrupted structure is: be provided with some groups of nano-Ag particles coatings on described antibacterial substrate layer, whole nano-Ag particles in each group nano-Ag particles coating are interconnected to form continuous structure, and one group of nano-Ag particles coating is coated with interlamellar spacing with other nano-Ag particles organized and arranges the interrupted structure of formation.

Specifically, nano-Ag particles coating nano-Ag particles coating on described antibacterial substrate layer is interrupted structure, and the Graphene grain coating on described filtering substrate layer is continuous structure；Or,

Nano-Ag particles coating nano-Ag particles coating nano-Ag particles coating on described antibacterial substrate layer is interrupted structure, Graphene grain coating on described filtering substrate layer is interrupted structure, described nano-Ag particles coating is arranged between each interrupted Graphene grain coating, and described nano-Ag particles coating and described Graphene grain coating spacing spacing on plane bearing of trend is arranged.

Further, described heating layer of cloth is provided with the electric leading-out end being connected in described electrode wires, described electricity leading-out end includes the first buckle structure and the second buckle structure, some claws that wherein said first buckle structure includes electrical contacts, is arranged on electrical contacts, described second buckle structure is provided with through hole, the claw that described first card is buckled is penetrated to opposite side by the side of electrode wires, described claw is placed in described through hole, and described first buckle structure and described second buckle structure are fixed together with coordinating of through hole by claw.

Preferably, on described heating layer of cloth, the spacing of adjacent two Graphene heater wires is 5mm to 25mm, and the spacing of adjacent two electrode wires is 1mm to 6mm, a diameter of 1mm to 3mm of described Graphene heater wire.

For reaching above-mentioned purpose, this utility model antibacterial type Graphene defecator, including above-mentioned antibacterial type Graphene filter membrane.

This utility model antibacterial type Graphene filter membrane, described ventilated membrane basal layer at least one side is partially or fully provided with at least one of which Graphene grain coating, forms filter course, the Graphene grain coating good filtration effect to air, and low cost.

Accompanying drawing explanation

Fig. 1 is the structural representation of this utility model antibacterial type Graphene filter membrane embodiment 2；

Fig. 2 is the structural representation of this utility model antibacterial type Graphene filter membrane embodiment 2；

Fig. 3 is the structural representation of this utility model antibacterial type Graphene filter membrane embodiment 2；

Fig. 4 is the structural representation of this utility model antibacterial type Graphene filter membrane embodiment 3；

Fig. 5 is the structural representation of this utility model antibacterial type Graphene filter membrane embodiment 3；

Fig. 6 is the structural representation of this utility model antibacterial type Graphene filter membrane embodiment 3；

Fig. 7 is the structural representation of this utility model antibacterial type Graphene filter membrane embodiment 4；

Fig. 8 is the structural representation of this utility model antibacterial type Graphene filter membrane embodiment 4；

Fig. 9 is the structural representation of this utility model antibacterial type Graphene filter membrane heating layer of cloth.

Detailed description of the invention

Below in conjunction with Figure of description, this utility model is further described.

Embodiment 1

The present embodiment antibacterial type Graphene filter membrane, antibacterial type Graphene filter membrane, the bacteriostatic structure arranged including stacking and filtration, wherein,

Described bacteriostatic structure includes antibacterial substrate layer and the nano-Ag particles coating that local is arranged on described antibacterial substrate is laminated；

Described filtration includes filtering substrate layer and the Graphene grain coating that local is arranged in described filtering substrate layer at least one side；

Described antibacterial substrate layer, filtering substrate layer are ventilated membrane.

The present embodiment, nano-Ag particles coating can carry out antibacterial, carry out air filtration by Graphene grain coating.

Embodiment 2

As shown in Figures 1 to 3, the present embodiment antibacterial type Graphene filter membrane, antibacterial type Graphene filter membrane, the bacteriostatic structure arranged including stacking and filtration, wherein,

Described bacteriostatic structure includes antibacterial substrate layer 21 and the nano-Ag particles coating 22 that local is arranged on described antibacterial substrate is laminated；

Described filtration includes filtering substrate layer 11 and the Graphene grain coating 12 all arranged in described filtering substrate layer at least one side；

Described antibacterial substrate layer, filtering substrate layer are ventilated membrane.

In the present embodiment, the Graphene grain coating on described filtering substrate layer is continuous structure, and described Graphene grain coating is that continuous structure is: on described filtering substrate layer, whole Graphene granules are interconnected to form continuous structure.

Nano-Ag particles coating on described antibacterial substrate layer is continuous structure, and described nano-Ag particles coating is that continuous structure is: on described antibacterial substrate layer, whole nano-Ag particles are interconnected to form continuous structure.

The present embodiment, on the basis of embodiment 1, also includes the heating arrangement of the Graphene grain coating of heating and filtering structure.Described heating arrangement includes the non-conductive socket 31 for switching on power, it is provided with conductive structure in described non-conductive socket, described bacteriostatic structure, filtration part are arranged in described non-conductive socket, described Graphene grain coating contacts conduction with described conductive structure, and described nanometer silver coating is arranged with described conductive structure spacing, insulation.

In the present embodiment, nano-Ag particles coating has bacteria resistance function, described Graphene grain coating can carry out filtration, purification to air, after Graphene grain coating absorbs harmful substance, heated by heating arrangement, Graphene grain coating temperature is raised, and so so that harmful substance emersion Graphene grain coating, such Graphene grain coating can be recycled.

Embodiment 3

As shown in Figs. 4-6, the present embodiment antibacterial type Graphene filter membrane, antibacterial type Graphene filter membrane, the bacteriostatic structure arranged including stacking and filtration, wherein,

Described bacteriostatic structure includes antibacterial substrate layer 21 and the nano-Ag particles coating 22 that local is arranged on described antibacterial substrate layer two sides；

Described filtration includes filtering substrate layer 11 and the Graphene grain coating 12 all arranged on described filtering substrate layer at least two sides；

Described antibacterial substrate layer, filtering substrate layer are ventilated membrane.

In the present embodiment, the Graphene grain coating on described filtering substrate layer is continuous structure, and described Graphene grain coating is that continuous structure is: on described filtering substrate layer, whole Graphene granules are interconnected to form continuous structure.

Nano-Ag particles coating on described antibacterial substrate layer is interrupted structure, described nano-Ag particles coating is that interrupted structure is: be provided with some groups of nano-Ag particles coatings on described antibacterial substrate layer, whole nano-Ag particles in each group nano-Ag particles coating are interconnected to form continuous structure, and one group of nano-Ag particles coating is coated with interlamellar spacing with other nano-Ag particles organized and arranges the interrupted structure of formation.

Similarly to Example 2, in the present embodiment, also include the heating arrangement of the Graphene grain coating of heating and filtering structure.Described heating arrangement includes the non-conductive socket 31 for switching on power, it is provided with conductive structure in described non-conductive socket, described bacteriostatic structure, filtration part are arranged in described non-conductive socket, described Graphene grain coating contacts conduction with described conductive structure, and described nanometer silver coating is arranged with described conductive structure spacing, insulation.

In the present embodiment, nano-Ag particles coating has bacteria resistance function, described Graphene grain coating can carry out filtration, purification to air, after Graphene grain coating absorbs harmful substance, heated by heating arrangement, Graphene grain coating temperature is raised, and so so that harmful substance emersion Graphene grain coating, such Graphene grain coating can be recycled.

In the present embodiment, nano-Ag particles coating is interrupted structure, is the circulation that continuous print structure is relatively beneficial to air compared to nanometer silver coating in above-described embodiment, facilitates air to contact with the Graphene grain coating on filtering substrate layer.

Embodiment 4

If Fig. 7 is to shown in 8, the present embodiment antibacterial type Graphene filter membrane, antibacterial type Graphene filter membrane, the bacteriostatic structure arranged including stacking, filtration heating arrangement, wherein,

Described bacteriostatic structure includes antibacterial substrate layer 21 and the nano-Ag particles coating 22 that local is arranged on described antibacterial substrate is laminated；

Described filtration includes filtering substrate layer 11 and the Graphene grain coating 12 that local is arranged on described filtering substrate is laminated；

Described antibacterial substrate layer, filtering substrate layer are ventilated membrane.

In the present embodiment, Graphene grain coating on described filtering substrate layer is interrupted structure, described Graphene grain coating is that interrupted structure is: be provided with some groups of Graphene grain coatings on described filtering substrate layer, whole Graphene granules in each group Graphene grain coating are interconnected to form continuous structure, and one group of Graphene grain coating arranges the interrupted structure of formation with other Graphene grain coating spacing organized.

Nano-Ag particles coating on described antibacterial substrate layer is interrupted structure, described nano-Ag particles coating is that interrupted structure is: be provided with some groups of nano-Ag particles coatings on described antibacterial substrate layer, whole nano-Ag particles in each group nano-Ag particles coating are interconnected to form continuous structure, and one group of nano-Ag particles coating is coated with interlamellar spacing with other nano-Ag particles organized and arranges the interrupted structure of formation.

Nano-Ag particles coating nano-Ag particles coating nano-Ag particles coating on described antibacterial substrate layer is interrupted structure, Graphene grain coating on described filtering substrate layer is interrupted structure, described nano-Ag particles coating is arranged between each interrupted Graphene grain coating, and described nano-Ag particles coating and described Graphene grain coating spacing spacing on plane bearing of trend is arranged.

The present embodiment is compared to the antibacterial type Graphene filter membrane described in embodiment 3, owing to nano-Ag particles coating in the in-plane direction and Graphene grain coating all stagger setting, namely with Graphene grain coating stacking arrange for ventilated membrane, so the Graphene grain coating in the present embodiment more can efficient solution except air.

In the present embodiment, nano-Ag particles coating has bacteria resistance function, described Graphene grain coating can carry out filtration, purification to air, after Graphene grain coating absorbs harmful substance, heated by heating arrangement, Graphene grain coating temperature is raised, and so so that harmful substance emersion Graphene grain coating, such Graphene grain coating can be recycled.

As shown in Figure 9, heating arrangement described in the present embodiment is heating layer of cloth 32, some strip electrode lines 2 that some Graphene 1 heater wires arranged including spacing and spacing are arranged, this heating cloth uses warp, the mode that broadwise line cross interlocks is formed by weaving, with the radially weaving together with radial insulation line of described Graphene heater wire, with the broadwise weaving together with warp-wise covered wire of described electrode wires, thus covered wire and Graphene heater wire, electrode wires has been woven into the structure of a piece of cloth jointly, described Graphene heater wire is arranged with broadwise covered wire square crossing, each electrode wires contacts conduction respectively with all of Graphene heater wire.

In the present embodiment, Graphene heater wire is woven together formed the structure of a piece of cloth, this heating cloth novel structure as braided wire by textile technology with electrode wires, with power supply conducting disconnection, Graphene heater wire is heated by electrode wires.

It addition, when any two Graphene heater wires are not in the case of heating, two Graphene heater wires and contact human skin, gather the voltage between two Graphene heater wires, human heartbeat can be calculated by this voltage.

Described heating layer of cloth is provided with the electric leading-out end being connected in described electrode wires, described electricity leading-out end includes the first buckle structure and the second buckle structure, some claws that wherein said first buckle structure includes electrical contacts, is arranged on electrical contacts, described second buckle structure is provided with through hole, the claw that described first card is buckled is penetrated to opposite side by the side of electrode wires, described claw is placed in described through hole, and described first buckle structure and described second buckle structure are fixed together with coordinating of through hole by claw.On described heating layer of cloth, the spacing of adjacent two Graphene heater wires is 5mm to 25mm, and the spacing of adjacent two electrode wires is 1mm to 6mm, a diameter of 1mm to 3mm of described Graphene heater wire.

Heating arrangement in the various embodiments described above 3 can also replace with the heating arrangement described in embodiment 4.

Embodiment 5

The present embodiment antibacterial type Graphene defecator, including the antibacterial type Graphene filter membrane described in any of the above-described embodiment.

Above; it is only preferred embodiment of the present utility model; but protection domain of the present utility model is not limited thereto; any those familiar with the art is in the technical scope that this utility model discloses; the change that can readily occur in or replacement, all should contain within protection domain of the present utility model.Therefore, protection domain of the present utility model should be as the criterion with the protection domain that claim is defined.

Claims (10)

1. an antibacterial type Graphene filter membrane, it is characterised in that include bacteriostatic structure and filtration that stacking arranges, wherein,

Described bacteriostatic structure includes antibacterial substrate layer and the nano-Ag particles coating partially or fully arranged in described antibacterial substrate layer at least one side；

Described filtration includes filtering substrate layer and the Graphene grain coating partially or fully arranged in described filtering substrate layer at least one side；

Described antibacterial substrate layer, filtering substrate layer are ventilated membrane.

Antibacterial type Graphene filter membrane the most according to claim 1, it is characterised in that also include the heating arrangement of the Graphene grain coating of heating and filtering structure.

Antibacterial type Graphene filter membrane the most according to claim 2, it is characterized in that, described heating arrangement includes the non-conductive socket for switching on power, it is provided with conductive structure in described non-conductive socket, described bacteriostatic structure, filtration part are arranged in described non-conductive socket, described Graphene grain coating contacts conduction with described conductive structure, and described nanometer silver coating is arranged with described conductive structure spacing, insulation.

Antibacterial type Graphene filter membrane the most according to claim 2, it is characterized in that, described heating arrangement is the heating layer of cloth arranged with described filtration stacking, described heating layer of cloth includes some the Graphene heater wires that spacing is arranged, some strip electrode lines of spacing setting and many radial insulation lines, broadwise covered wire, with described Graphene heater wire as radial line, described electrode wires is parallel, described Graphene heater wire is crisscross arranged with described electrode wires, and the Graphene heater wire that each electrode wires is with more than two contacts conduction, by radial insulation line, broadwise covered wire, Graphene heater wire, electrode wires is woven together forming heating layer of cloth by textile technology.

Antibacterial type Graphene filter membrane the most according to claim 1, it is characterised in that the Graphene grain coating on described filtering substrate layer is continuous structure, or be interrupted structure, wherein,

Described Graphene grain coating is that continuous structure is: on described filtering substrate layer, whole Graphene granules are interconnected to form continuous structure；

Described Graphene grain coating is that interrupted structure is: be provided with some groups of Graphene grain coatings on described filtering substrate layer, whole Graphene granules in each group Graphene grain coating are interconnected to form continuous structure, and one group of Graphene grain coating arranges the interrupted structure of formation with other Graphene grain coating spacing organized.

Antibacterial type Graphene filter membrane the most according to claim 1, it is characterised in that the nano-Ag particles coating on described antibacterial substrate layer is continuous structure, or be interrupted structure, wherein,

Described nano-Ag particles coating is that continuous structure is: on described antibacterial substrate layer, whole nano-Ag particles are interconnected to form continuous structure；

Described nano-Ag particles coating is that interrupted structure is: be provided with some groups of nano-Ag particles coatings on described antibacterial substrate layer, whole nano-Ag particles in each group nano-Ag particles coating are interconnected to form continuous structure, and one group of nano-Ag particles coating is coated with interlamellar spacing with other nano-Ag particles organized and arranges the interrupted structure of formation.

Antibacterial type Graphene filter membrane the most according to claim 1, it is characterised in that nano-Ag particles coating nano-Ag particles coating on described antibacterial substrate layer is interrupted structure, and the Graphene grain coating on described filtering substrate layer is continuous structure；Or,

Nano-Ag particles coating nano-Ag particles coating nano-Ag particles coating on described antibacterial substrate layer is interrupted structure, Graphene grain coating on described filtering substrate layer is interrupted structure, described nano-Ag particles coating is arranged between each interrupted Graphene grain coating, and described nano-Ag particles coating and described Graphene grain coating spacing spacing on plane bearing of trend is arranged.

Antibacterial type Graphene filter membrane the most according to claim 4, it is characterized in that, described heating layer of cloth is provided with the electric leading-out end being connected in described electrode wires, described electricity leading-out end includes the first buckle structure and the second buckle structure, wherein said first buckle structure includes electrical contacts, the some claws being arranged on electrical contacts, described second buckle structure is provided with through hole, the claw that described first card is buckled is penetrated to opposite side by the side of electrode wires, described claw is placed in described through hole, described first buckle structure and described second buckle structure are fixed together with coordinating of through hole by claw.

Antibacterial type Graphene filter membrane the most according to claim 4, it is characterized in that: on described heating layer of cloth, the spacing of adjacent two Graphene heater wires is 5mm to 25mm, the spacing of adjacent two electrode wires is 1mm to 6mm, a diameter of 1mm to 3mm of described Graphene heater wire.

10. an antibacterial type Graphene defecator, it is characterised in that include the arbitrary described antibacterial type Graphene filter membrane of claim 1 to 9.