JP2001265138A - Heat-insulating material for electrophotographic apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat-insulating material for electrphotographic apparatus that can be installed inside the electrophotographic apparatus. SOLUTION: The heat insulating material for the electrophotographic apparatus is constituted so that a laminated material, consisting of a flame retardant and heat resistant fiber sheet and a sheet having an aluminum layer is packed into a bag consisting of the sheet having the aluminum layer and is sealed in a vacuum state.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a heat insulating material for an electrophotographic apparatus. For example, it relates to a heat insulating material that can be used around a heat-generating component inside a copying machine.

[0002]

2. Description of the Related Art Inside an electrophotographic apparatus, there is a heat-generating component such as a fixing roll for fixing carbon particles to a copy sheet such as paper. This fixing roll is used not only during copying but also during standby for not copying. Sometimes it is kept at a high temperature above a certain temperature. Generally, electronic components that are liable to malfunction at high temperatures are incorporated around the heat-generating components, and thus, conventionally, heat was exhausted while securing a space. In recent years, there has been a trend to downsize electrophotographic apparatuses. However, when electrophotographic apparatuses are downsized, it is difficult to secure a space for exhausting heat, and thus there has been a problem that electronic components are likely to malfunction.

[0003]

SUMMARY OF THE INVENTION The present inventor has found that electronic components are liable to malfunction due to the influence of heat of the heat-generating components, so that the heat of the heat-generating components does not affect the electronic components. Thus, it was thought that a heat insulating material should be provided between the heat-generating component and the electronic component. However, the conventional heat insulating material is not intended for a component having a higher temperature than a heat-generating component in the electrophotographic apparatus, and therefore, it is difficult to install the heat insulating material in the electrophotographic apparatus. The present invention has been made to solve such a problem, and an object of the present invention is to provide a heat insulating material for an electrophotographic apparatus that can be installed in the electrophotographic apparatus.

[0004]

The heat insulating material for an electrophotographic apparatus of the present invention (hereinafter sometimes simply referred to as "heat insulating material") is:
A laminate of a flame-retardant and heat-resistant fiber sheet and a sheet having an aluminum layer is filled in a bag made of a sheet having an aluminum layer and sealed in a vacuum.
The heat insulating material of the present invention can reflect the radiant heat from the heat-generating component by including the sheet having the aluminum layer, and further, because the laminate is sealed in a vacuum state, the gas in the bag can be reflected. Since heat conduction by convection can be made as small as possible, it is excellent in heat insulation. In addition, since the heat insulating material of the present invention uses a flame retardant and heat resistant fiber sheet,
It can also be used under high temperature conditions of about 200 ° C. as in an electrophotographic apparatus. As described above, the sheet having the aluminum layer reflects radiant heat from the heat-generating component, and the heat-insulating material can maintain the temperature of the heat-generating component, thereby contributing to energy saving of the electrophotographic apparatus. It also has an effect.

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A fiber sheet which can be used in the present invention has heat resistance and flame retardancy. Therefore, it should be installed on a sheet having a high-temperature exothermic component such as an electrophotographic apparatus. Became possible. The term "flame retardant" in the present invention means that the material satisfies UL (Underwriters Laboratories) standard V-1 or V-0. The term “heat resistance” means that no endothermic peak due to melting occurs even when measured from a room temperature to a temperature 20 ° C. higher than the temperature of the exothermic component at a heating rate of 10 ° C./min using a differential calorimeter. Say. As the flame-retardant and heat-resistant fiber sheet, for example, use is made of a nonwoven fabric, a woven fabric, a knitted fabric or a composite thereof made of inorganic fibers such as glass and alumina, and organic fibers such as acrylic oxide, polyester and aromatic polyester. be able to. A fiber sheet made of such fibers has a low solid thermal conductivity and is excellent in heat insulation. The fiber constituting the fiber sheet does not need to be one kind, but may be composed of two or more kinds of fibers such as a mixture of inorganic fibers and organic fibers. Among these, a nonwoven fabric made of glass fiber can be suitably used because of its excellent compression resistance. In addition, it is preferable to add a flame-retardant binder to the fiber sheet so that the fiber sheet has flame retardancy and heat resistance, and the thickness of the fiber sheet is not easily reduced during vacuum compression. Examples of such a flame retardant binder include a binder obtained by adding a flame retardant to a thermosetting resin and a binder obtained by introducing a flame retardant functional group into a thermosetting resin. As a flame retardant, phosphorus-containing polyols, tetrabromobisphenol, halogen-containing polyphosphate, antimony trioxide, phosphorus-based such as aluminum hydroxide, halogen-based, epoxy resins and phenolic resins to which inorganic ones are added, and the like, Examples of the latter include an epoxy resin and a phenol resin into which a halogen-containing functional group or a phosphorus-containing functional group is introduced. The thickness of the flame-retardant and heat-resistant fiber sheet in a vacuum state is not particularly limited, but is preferably about 0.2 to 1 mm.

[0006] In addition to such a flame-retardant and heat-resistant fiber sheet, a sheet having an aluminum layer is laminated,
Excellent heat insulation because it can reflect radiant heat from heat-generating components. As a sheet having this aluminum layer,
For example, a sheet obtained by subjecting one or both surfaces of a plastic film such as polyester to aluminum vapor deposition, an aluminum foil, or a sheet obtained by bonding and combining an aluminum foil and a plastic film can be used. Note that the sheet having an aluminum layer is preferably stacked such that the glossy surface (for example, a vapor deposition surface) of aluminum is on the heat-generating component side so that radiant heat can be reflected. Further, the lamination of the flame-retardant and heat-resistant fiber sheet and the sheet having the aluminum layer may be in any number of layers, and can be appropriately set according to the temperature of the heat-generating component. When two or more flame-retardant and heat-resistant fiber sheets and / or sheets having an aluminum layer are laminated, these sheets are alternately arranged so that heat conduction of the sheet having an aluminum layer can be suppressed. Lamination is preferred. Further, as described later, since a laminate of these sheets is sealed in a bag made of a sheet having an aluminum layer, the heat conduction of the sheet having an aluminum layer constituting the bag can be suppressed. Preferably, both surfaces of the sheet laminate are comprised of a flame retardant and heat resistant fiber sheet.

[0007] The laminate of these sheets is sealed in a vacuum state in a bag made of a sheet having an aluminum layer,
Since heat conduction due to convection of gas in the bag can be minimized, the heat insulating material of the present invention is excellent in heat insulating properties. As the sheet having an aluminum layer constituting this bag, for example, a sheet obtained by subjecting one or both sides of a plastic film such as polyester to aluminum vapor deposition processing or a sheet obtained by bonding and bonding an aluminum foil and a plastic film can be used. In addition, when forming a bag from a sheet having an aluminum layer, the inside of the sheet having an aluminum layer (for example, the non-deposited surface of the film, the non-adhesive surface of the aluminum foil) is formed on the inside of the sheet having the aluminum layer in order to enhance the thermal adhesion between the sheets. Alternatively, a low-melting polymer such as a copolyester, polypropylene, or polyethylene may be laminated or coated as long as heat resistance is not impaired. The sheet having the aluminum layer constituting the bag may be the same as or different from the sheet having the aluminum layer constituting the laminate described above. Further, the sheet having an aluminum layer constituting the bag is more excellent in heat insulation when the bag is formed such that the glossy surface (for example, the vapor deposition surface) of aluminum is on the heat-generating component side. The above-described laminate is sealed in a bag made of a sheet having an aluminum layer in a vacuum state. In the present invention, the “vacuum state” means that the pressure in the bag is 13.3 Pa (Pascal) or less. That means. In addition, from the point of heat insulation, 6.7 Pa
It is preferred that: The heat insulating material of the present invention has a thickness of 1 to 5
Even if the thickness is mm, it has a sufficient heat insulating property, and can contribute to downsizing of the electrophotographic apparatus.

[0008] The heat insulating material of the present invention can be manufactured, for example, as follows. First, a flame-retardant and heat-resistant fiber sheet as described above, a sheet having an aluminum layer forming a laminate, and a sheet having an aluminum layer forming a bag are prepared. Next, a flame-retardant and heat-resistant fiber sheet and a sheet having an aluminum layer constituting a laminate are laminated. When two or more flame-retardant and heat-resistant fiber sheets and / or sheets having an aluminum layer are laminated, it is preferable to alternately laminate these sheets. In addition, it is preferable to laminate these sheets so that both surfaces of the laminate are flame-retardant and heat-resistant fiber sheets. On the other hand, after a sheet having an aluminum layer constituting the bag is overlaid so that the glossy surface (for example, vapor deposition surface) of aluminum is on the outside, the three sides are sealed by heating, high frequency or ultrasonic sealing to form the bag. I do. Next, the laminate is inserted into the bag, degassed in the chamber until the pressure becomes 13.3 Pa (Pascal) or less, and the remaining side is similarly sealed to obtain the heat insulating material of the present invention. be able to.

Hereinafter, embodiments of the present invention will be described, but the present invention is not limited to the following embodiments.

[0010]

(Example 1) A glass fiber having a fiber diameter of 10 μm was replaced with a brominated epoxy resin (trade name: Epicron 15).
3. Six glass nonwoven fabrics (flame retardancy: UL V-0, melting point: 230 ° C. or more) bonded by a binder made of Dainippon Ink and Chemicals, Inc. were prepared. The areal density of this glass non-woven fabric is 100 g / m ² and is in a vacuum state (2.7 P
The thickness in a) was 0.5 mm. In addition, thickness 1
Five films were prepared by depositing aluminum on one side of a 2 μm polyester film. Next, the glass nonwoven fabric and the aluminum-deposited film are alternately laminated such that the glass nonwoven fabric becomes both surface layers and the vapor-deposited surface of the aluminum-deposited film is on the heat-generating component side, and a laminate (thickness: (Approximately 3 mm). On the other hand, two films in which aluminum was evaporated on one side of a polyester film having a thickness of 50 μm were prepared. Then, this 2
After stacking a plurality of aluminum vapor-deposited films such that the vapor-deposited surface was on the outside, three sides were heat-sealed to form an insertion bag. Next, the laminate is inserted into the insertion bag, deaerated in the chamber until a pressure of 2.7 Pa is reached, and then the remaining side is heat-sealed to produce the heat insulating material of the present invention. did.

(Comparative Example 1) A heat insulating material (normal pressure state) having a thickness of about 3 mm, comprising a laminate and a bag having exactly the same configuration as in Example 1 except that the vacuum state was not applied, was manufactured.

(Comparative Example 2) As a fiber sheet, a needle-punched nonwoven fabric having a basis weight of 1400 g / m ² and a thickness of 14 mm made of oxidized acrylic fiber was prepared. On the other hand, two films in which aluminum was evaporated on one side of a polyester film having a thickness of 50 μm were prepared. Then, the two aluminum vapor-deposited films were laminated on both sides of the fiber sheet with a rubber-based adhesive so that the vapor-deposited surface was on the outside, to produce a heat insulating material (normal pressure state) having a thickness of about 14 mm.

(Evaluation of heat insulating property) A heating element was installed, and Example 1 and Comparative Examples 1 and 2 were placed at a distance of 20 mm from the heating element.
Was placed so that the aluminum vapor-deposited surface was on the side of the heating element, and a temperature sensor was placed 50 mm away from the heating element. A heat-insulating material was provided around the heating element and the temperature sensor to prevent excess heat from escaping. Next, the temperature of the heating element is set to 20.
Set to 0 ° C., the temperature of the heating element and 50 mm from the heating element
When the temperature at the distant place stably reached the steady state, the temperature at a distance of 50 mm from the heating element was measured by a temperature sensor. The results were as shown in Table 1.

[0014]

【table 1】 As is evident from Table 1, the heat insulating material of the present invention has excellent heat insulating properties, and has a high-temperature exothermic component such as an electrophotographic apparatus. It turns out that it can be insulated. Further, it was also found that the thickness can be reduced as compared with the heat insulating material in a normal pressure state, which can contribute to downsizing of the electrophotographic apparatus.

[0015]

The heat insulating material for an electrophotographic apparatus according to the present invention has excellent heat insulating properties, and can be used as a heat insulating material for an electrophotographic apparatus. In addition, since the temperature of the heat-generating component can be maintained by the heat insulating material, the effect of contributing to energy saving of the electrophotographic apparatus can be obtained.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H05K 7/20 H05K 7/20 Y F-term (Reference) 2H033 AA41 AA42 BA37 2H071 BA41 DA12 3H036 AB03 AB18 AB24 AB28 AC03 AE01 4F100 AB10B AG00 AK41 AK53 BA02 DG01 DG11A DG15 EH66 GB90 JJ02 JJ03A JJ07A 5E322 CA05 FA02

Claims (1)

[Claims] An electronic device characterized in that a laminate of a flame-retardant and heat-resistant fiber sheet and a sheet having an aluminum layer is sealed in a vacuum state in a bag made of a sheet having an aluminum layer. Thermal insulation for photographic equipment.