CN216135157U - Tobacco paper packaging material improved by far infrared radiation and far infrared radiation processing equipment - Google Patents

Abstract

The utility model relates to a tobacco paper packaging material improved by far infrared radiation and a far infrared radiation processing device, which utilize the far infrared energy to irradiate and act on the tobacco paper packaging material, utilize the far infrared radiation source to radiate the material to improve the far infrared emissivity and wavelength of the material, and consist of a closed bin, an electric heating device, a thermal cycle device, a material frame and a radiation source frame, wherein the electric heating device, the thermal cycle device, the material frame and the radiation source frame are arranged in the closed bin, the radiation source frame is used for placing the radiation source, the electric heating device generates heat to heat air and provides the radiation source with heat energy to generate far infrared radiation, the thermal cycle device drives the air to form cycle convection in the closed bin, so that the far infrared radiation generated by the radiation source continuously and uniformly acts on the material arranged on the material frame, the material generates resonance effect to accelerate molecular movement and gradually generate physical and chemical changes.

Description

Tobacco paper packaging material improved by far infrared radiation and far infrared radiation processing equipment

Technical Field

The utility model relates to a tobacco paper packaging material improved by far infrared radiation and far infrared radiation processing equipment, relates to a tobacco paper packaging material irradiated by far infrared energy, belongs to the technical field of production of far infrared materials, and particularly relates to a tobacco paper packaging material improved by far infrared radiation and far infrared radiation processing equipment for improving the far infrared emissivity and wavelength of the material by radiating the material by a far infrared radiation source.

Technical Field

The far infrared material can be widely applied to the aspects of medical health, air treatment, antibiosis and bacteriostasis, food processing, material performance improvement and the like, and is widely applied at home and abroad at present; such as rehabilitation medical equipment, textiles, water purification, etc., to irradiate the material, thereby changing and improving the far infrared emissivity and wavelength of the material.

The utility model relates to a technology which utilizes far infrared ray energy irradiation to act on a tobacco paper wrapper, the wrapper becomes a stronger far infrared radioactive source by improving the far infrared normal total emissivity of the wrapper, the molecular motion is accelerated by generating a resonance effect by the fact that the wavelength of the far infrared radiation of the wrapper is close to the electromagnetic absorption wavelength of a cigarette product, and the radiated cigarette product gradually generates physical and chemical changes under the condition of lasting time of the resonance effect. Thereby achieving the purpose of improving and stabilizing the quality of the cigarette products.

The technical support of the utility model is the utility model patent applied by the inventor: a far infrared radiation source and a method for improving far infrared emissivity and wavelength of a material are disclosed in the application number: 2021104558695.

at present, the cigarette industry in China is implementing the development strategy of 'harm reduction, tar reduction, aroma enhancement and moisture preservation' to further improve and improve the quality of cigarettes. In recent years, China has made certain progress in the research of tobacco flavor and fragrance technology, and flavor and fragrance preparation technology, flavor and fragrance analysis and evaluation technology, flavor and fragrance moisturizing control technology and the like are improved.

At present, a plurality of cigarette flavoring modes are formed, but the essence and the spice have larger loss in the processing and storage processes of the cigarette; therefore, the technology of the utility model provides a brand-new packaging material formed by applying the far infrared radiation technology to the cigarette packaging material (double copper paper, white cardboard, parchment paper and tinfoil paper), thereby improving and stabilizing the cigarette quality.

The utility model relates to a solution for cigarette paper materials, which comprises the following steps: the far infrared technology treatment and quality improvement technology of the cigarette paper packaging material treats the influence on the improvement and stability of the cigarette quality through the far infrared technology, and utilizes the far infrared technology to treat the influence on the improvement and stability of the cigarette quality, the influence on the smoking taste and the influence on the stability of the cigarette aroma acted on the packaging material.

The far infrared can improve the porosity of the cut tobacco and loosen the structure of the cut tobacco, so that the humectant is more tightly combined with the moisture in the cut tobacco, and the moisturizing effect is further improved.

The protein content in the cut tobacco after the far infrared technology is added is generally lower than that after normal drying, so that the far infrared technology has a certain nitrogen reduction effect.

Far infrared radiation has certain influence on the total amino acid amount change of tobacco shreds. Part of amino acid absorbs far infrared radiation energy to decompose, so that the content of the amino acid is reduced.

The far infrared irradiation energy is absorbed and resonated by the moisture in the tobacco shreds to generate pores with larger diameters, so that the surface wrinkles of the tobacco shreds are more prominent; by utilizing the resonance absorption principle of far infrared energy, the original properties of the material are not changed, the far infrared absorption light on the cigarette packaging material (double copper paper, white cardboard, parchment paper and tinfoil paper) is 2-12 mu m far infrared which is 4-1000 mu m electromagnetic wave, the far infrared absorption light acts on the material, the material has radiation, permeability, resonance and absorption, and the vibration number of the far infrared is in the same range with the vibration number of the common material.

Therefore, when far infrared rays touch substances, resonance and resonance phenomena can be caused in molecules forming the substances, the effect of utilizing radioactive objects is achieved, the far infrared wavelength of cigarette packaging materials (double copper paper, white cardboard, sulfuric acid paper and tin foil paper) is improved to 8-14 mu m, the packaging materials become a strong far infrared radioactive source, the wavelength of far infrared radiation of the packaging materials is close to the electromagnetic absorption wavelength of cigarette products, resonance effect is generated, molecular motion is accelerated, and the radiated cigarette products gradually generate physical and chemical changes under the condition of lasting time. Thereby achieving the purpose of improving and stabilizing the quality of the cigarettes.

Disclosure of Invention

The utility model discloses a heat radiation cabinet, in particular to heat radiation equipment for improving far infrared emissivity and wavelength of a material.

To achieve the above object, the present invention has the following technical scheme

The utility model provides a far infrared radiation processing equipment, by closed storehouse, electric heater unit, thermal cycle device, material frame, radiation source frame constitution, electric heater unit, thermal cycle device, material frame, radiation source frame erect and arrange in closed storehouse in, the radiation source frame is used for placing the radiation source, electric heater unit produces heat heating air, provides heat energy for the radiation source and produces far infrared radiation, thermal cycle device drives the air and forms the circulation convection in closed storehouse, makes the far infrared radiation that the radiation source produced act on in succession evenly on the material that the material frame was placed, thereby make the material produce resonance effect acceleration molecular motion, produce physics and chemical change gradually.

The inner wall of the closed bin is provided with a heat insulation layer.

The electric heating device adopts an electric heating pipe and is arranged below the thermal irradiation cabinet.

The heat circulating device adopts a plurality of fans which are arranged along the air circulation channel to drive air to circularly flow.

The material rack is provided with one or more layers for placing the irradiated materials.

The material rack is of a porous structure and is used for air circulation.

The radiation source frame is of a porous structure and is used for placing a radiation source.

A paper packing material for tobacco is a paper material with improved far infrared emissivity and wavelength after long-time irradiation by far infrared radiation source.

The paper material is double copper paper/white cardboard/parchment paper/tinfoil paper.

Drawings

The utility model is further illustrated by the following figures and examples,

FIG. 1 is a front view of a far infrared radiation processing apparatus,

FIG. 2 is a perspective view of one of far infrared radiation processing apparatuses,

FIG. 3 is a second perspective view of the far infrared radiation processing apparatus,

FIG. 4 is a schematic view of hot air convection in a far infrared radiation processing apparatus.

The numbers in the figures are respectively: 1: an air flow channel; 2: a material rack; 3: a heat insulation protection plate; 4: an equipment enclosure door; 5: a radiation source holder; 6: a heat insulation layer; 7: a fan; 8: an electric heating device; 9: air convection direction.

Detailed Description

Exemplary embodiments of the present invention will be described in detail below with reference to the accompanying drawings. These exemplary embodiments are provided so that those skilled in the art can clearly understand the present invention and can implement the present invention according to the description herein. The drawings and detailed description are not intended to limit the utility model, which is defined by the appended claims.

As shown in fig. 2, a far infrared radiation processing apparatus is composed of a closed bin, an electric heating device, a thermal circulation device, a material frame, and a radiation source frame, wherein the electric heating device, the thermal circulation device, the material frame, and the radiation source frame are arranged in the closed bin, the radiation source frame is used for placing a radiation source, the electric heating device generates heat to heat air and provides heat energy for the radiation source to generate far infrared radiation, the thermal circulation device drives the air to form circulation convection in the closed bin, so that the far infrared radiation generated by the radiation source continuously and uniformly acts on the material placed on the material frame, and the material generates a resonance effect to accelerate molecular motion and gradually generate physical and chemical changes;

the tobacco packaging material (such as double copper paper, white cardboard, parchment paper, tinfoil paper and the like) is placed on the material frame in a layered or multi-layered mode, the radiation source is granular and is uniformly distributed on the radiation source frame, the electric heating device provides heat, the radiation source emits a large amount of far infrared rays, and the tobacco packaging material is irradiated for a long time, so that the material generates a resonance effect, molecular motion is accelerated, and physical and chemical changes are gradually generated.

The far infrared radiation processing equipment can be a far infrared electromagnetic radiation box/cabinet which is arranged in a cabinet shape.

The inner wall of the closed bin is provided with a heat insulation layer, so that heat loss and outward diffusion are prevented.

The electric heating device adopts an electric heating pipe and is arranged below the thermal irradiation cabinet.

The heat circulating device adopts a plurality of fans which are arranged along the air circulation channel to drive air to circularly flow.

The material rack is provided with one or more layers for placing the irradiated materials.

The material frame is of a porous structure, and air circulation is facilitated.

The radiation source frame is of a porous structure and is used for placing the radiation source, so that air circulation is facilitated, and the radiation source is heated more quickly.

A paper packing material for tobacco is a paper material with improved far infrared emissivity and wavelength after long-time irradiation by far infrared radiation source.

The paper material is double copper paper/white cardboard/parchment paper/tinfoil paper.

After the material is radiated and processed by the far infrared electromagnetic radiation box, the far infrared normal total emissivity of the material can be improved to be more than 0.8.

The utility model patent of the applicant's application relates to a far infrared radiation source and a method for improving the far infrared emissivity and wavelength of a material', which comprises the following specific manufacturing method and application:

the far infrared energy source is made up of iron meteorite powder (5-7%), praseodymium-neodymium oxide (8-12%) and oxygen

3-7% of zirconium oxide, 3-7% of lanthanum oxide, 20-30% of nano ceramic powder and 45-55% of ceramic powder, and the materials are fully mixed, formed by casting and pressing by a ceramic dry casting method and sintered at the temperature of 800-1300 ℃ to prepare the far infrared radiation source.

According to the preferred scheme of the utility model, the far infrared radiation source is prepared by fully mixing 5% of iron meteorite powder, 10% of praseodymium neodymium oxide, 5% of zirconium oxide, 5% of lanthanum oxide, 25% of nano ceramic powder and 50% of ceramic powder, performing cast molding by using a ceramic dry casting method and sintering at the temperature of 800-1300 ℃.

The method for improving the far infrared normal total emissivity of the material by utilizing the thermal effect adopts a far infrared radiation source, places the material around the far infrared radiation source, and continuously keeps a certain temperature in a certain time, so that the far infrared radiation source and the material generate a resonance effect when the wavelength of the far infrared radiation source is close to the absorption wavelength of the material, thereby accelerating molecular motion, changing and improving the far infrared normal total emissivity wavelength of the material, and improving the far infrared emissivity of the material.

The material is prepared by fully mixing 5-7% of iron meteorite powder, 8-12% of praseodymium neodymium oxide, 3-7% of zirconium oxide, 3-7% of lanthanum oxide, 20-30% of nano ceramic powder and 45-55% of ceramic powder, casting and pressing the materials into spheres, cubes, cylinders and any other forms by using a ceramic dry casting method, wherein the size of a single far infrared radiation source specification is not less than 0.5 x 1 (cm) at the minimum and not more than 30 x 30 (cm) at the maximum, and the far infrared radiation source with the far infrared normal total emissivity of more than 0.82 and the wavelength of more than 8-14 mu m is prepared by sintering at the temperature of 800-1300 ℃.

The method for improving the far infrared normal total emissivity of the material by utilizing the thermal effect adopts a far infrared radiation source, places the material around the far infrared radiation source, and continuously keeps a certain temperature in a certain time, so that the far infrared radiation source and the material generate a resonance effect when the wavelength of the far infrared radiation source is close to the absorption wavelength of the material, thereby accelerating molecular motion, changing and improving the far infrared normal total emissivity wavelength of the material, and improving the far infrared emissivity of the material.

The method comprises the steps of adopting a far infrared electromagnetic irradiation box to perform irradiation processing on a material, utilizing a thermal effect to improve the far infrared normal total emissivity of the material, adopting a far infrared energy radiation source, arranging the far infrared energy radiation sources around the material according to a matrix, enabling the material frame to be used as a radiation source frame, placing a layer of radiation source on the material frame at intervals, activating energy radiation of an independent far infrared radiation source through the temperature of more than 20 ℃, enabling the energy to act on the material for a certain time (about 30 minutes to 10 hours), and generating a resonance effect when the radiated wavelength is close to the absorption wavelength of the material, so that the molecular motion is accelerated, and the far infrared emissivity of the material is improved under the continuous action of the temperature for a long time.

After the material is radiated and processed by a far infrared electromagnetic radiation box, the far infrared normal total emissivity of the material can be improved to

Above 0.8.

As shown in fig. 2, the far infrared radiation processing equipment, the electric heating device adopts an insulated heating wire or an electric heating tube, the irradiation source frame adopts 316 stainless steel, the die is punched and formed, the specification of the irradiation source frame (the aperture of which is determined by the shape and specification of an independent irradiation source) in the equipment is 610 x 80mm, the irradiation source frame is used for embedding a far infrared radiation source, the radiation source laminate is arranged in a multilayer arrangement, the material to be processed is in a plate shape, the material is placed on the irradiation source frame and is heated for a certain time (about 10 hours), so that the radiation source carries out far infrared energy radiation on the material to generate a resonance effect, the molecular motion is accelerated, and the far infrared emissivity of the material is improved under the continuous action of keeping the temperature for a long time.

On the basis of the equipment manufacturing and process, the temperature control and the processing time control are changed, so that the packaging materials (double copper paper, white cardboard, parchment paper, tin foil paper and the like) of the tobacco products are improved to be far infrared radioactive sources with the wavelength of 8-14 mu m and the normal total emissivity of more than 0.8.

The specific implementation method comprises the following steps:

according to different characteristics of temperature resistance and ageing resistance of paper packaging materials (such as copper double paper, white cardboard, parchment paper, tin foil paper and the like) of the processed cigarette products, the temperature of the inner cavity of the far infrared energy source equipment is controlled to be maintained between 20 and 80 ℃, and the temperature is maintained for 30 minutes to 5 hours.

The wavelength of the paper packaging material (double copper paper, white cardboard, parchment paper, tin foil paper and the like) of the cigarette product processed by the technology reaches 8-14 mu m, and the normal total emissivity is more than 0.86.

After the tobacco products are packaged by the packaging material with the normal total emissivity reaching above 0.8, the released far infrared radiation wavelength and the absorption wavelength of the cigarette products generate resonance effect, and the radiated cigarette products gradually generate physical and chemical changes under the condition that the resonance effect lasts for a long time, so that the aim of improving and stabilizing the cigarette quality is fulfilled.

The cigarette product produced by the utility model technology of utilizing the far infrared energy source to act on the tobacco paper packaging material to improve and stabilize the cigarette quality has fragrant, mellow and soft taste and obviously reduces the pungent and pungent smoke.

After long-term smoking evaluation by tobacco evaluation experts and public smokers, the taste is optimized and the sensitivity is 100%.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the present invention, and it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the utility model.

And (4) attaching a detection report:

Claims (9)

1. the utility model provides a far infrared radiation processing equipment, its characterized in that, a far infrared radiation processing equipment comprises closed bin, electric heater unit, thermal cycle device, material frame, radiation source frame are erect and are arranged in closed bin, the radiation source frame is used for placing the radiation source, electric heater unit produces heat heated air, provides heat energy for the radiation source and produces far infrared radiation, thermal cycle device drives the air and forms the circulation convection in closed bin, makes the far infrared radiation that the radiation source produced continuously evenly act on the material that the material frame was placed makes the material produce resonance effect and accelerates the molecular motion, produces physics and chemical change gradually.

2. The far infrared radiation processing apparatus as set forth in claim 1, wherein said closed chamber is provided with a heat insulating layer on an inner wall thereof.

3. The far infrared radiation processing apparatus as set forth in claim 1, wherein said electric heating means, which employs an electric heating tube, is disposed below the heat irradiation cabinet.

4. The far infrared radiation processing apparatus as set forth in claim 1, wherein said heat circulating means is provided by a plurality of fans arranged along the air circulation passage.

5. The far infrared radiation processing apparatus as set forth in claim 1, wherein said material frame is provided with one or more layers.

6. The far infrared radiation processing apparatus as set forth in claim 1, wherein said material frame is provided in a porous structure.

7. The far infrared radiation processing apparatus as set forth in claim 1, wherein said radiation source frame is provided in a porous structure.

8. A paper packing material for tobacco is improved by far infrared radiation, and features that after it is radiated by far infrared radiation source for a long time, the far infrared emissivity and wavelength of said paper material are increased.

9. The paper packaging material for tobacco improved by far infrared radiation as claimed in claim 8, wherein said paper material is selected from the group consisting of copper paper, white cardboard, sulfuric acid paper, and tin foil.

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