KR20010051400A - Frost Detection Goggle and Manufacturing Method therefor - Google Patents

Abstract

PURPOSE: An eye protective spectacles for preventing frost is provided, which prevents forming frost from user's steam of breath or moisture on spectacles of helmet, snow mobile, or goggle for ski or skate. CONSTITUTION: A process for the preparation of an eye protective spectacles for preventing frost comprises the steps of: treating thermoplastic resin film with heat-contraction at fixed time and temperature(S10); TO(tin-oxide)-treating and sputtering a heating part(S11); forming electrode part by masking-printing to negative(S12); corrosive-treating the separated electrode part with corrosive solution(S13); tearing off thinly the masking-printed electrode part(S14); printing the power-supplying line to negative(S15); plating power-supplying line into a fixed thickness(S16); tearing off thinly the plated power-supplying line(S17); spray-coating with transparent paint(S18); coking the power-supplying terminal(S19); PTC-treating to protect the heating part(S20); and cutting into a fixed form and examining resistance-value(S21).

Description

Protective goggles to prevent frost and its manufacturing method {Frost Detection Goggle and Manufacturing Method therefor}

The present invention relates to an anti-frost protection goggles and a method of manufacturing the same, and more particularly, when the ambient temperature is low while wearing a goggles or snowmobile goggles or ski or skate goggles attached to the face protection helmet. The present invention relates to a method for manufacturing a protective goggles for preventing frost from forming due to wear or moisture of a wearer.

Conventionally, there are many kinds of protective glasses worn to protect a part of the body, face or eyes, in particular, the protective glasses used according to the use is different. Generally, safety glasses have protective glasses (e.g. snowmobiles, motorcycles, etc.) to prevent wind or foreign substances from entering the body, or protective glasses attached to the front of the helmet to protect the head. Among the parts, there are safety glasses to protect the eyes.

When wearing such protective glasses, there may be a case of steaming or frost on the front or the back of the protective glasses due to the temperature difference around them. In other words, the protective goggles are steamed in the place where the protection glasses are relatively hot and humid compared to the ambient temperature, and the frost is caught in the cold and humid place. For example, in the case of a goggle for skiing or skating, when the wearer's breathing is in a protective goggle and the surrounding temperature is relatively cold, frost is formed and the front cannot be seen.

In order to prevent this, the conventional protective glasses, as shown in Figure 1, the electrode portion (3, 4) for generating resistance heat inside the protective glasses 1 is configured up and down, between the electrode portions (3, 4) The heating unit 2 is configured, and the power supply unit 9 is connected to the electrode units 3 and 4 through the power supply lines 5 and 6. Power supply lines (5, 6) is connected to the wire (7) to the outside, the wire (7) is configured with a terminal (8) for the connection of power. In addition, the power supply means 9 is connected in series with a power switch 10 for applying or disconnecting power.

The heating part 2 inserted into the protective glasses 1 is treated with ITO (Indium, Tin, Oxygen; indium-tin oxide), and the electrode parts 3 and 4 are silver printed. The total resistance of the heating section 2 is 9 to 9.5 Ω, and the residual resistance is about 3 Ω due to silk printing. The power supply means 9 uses DC 12-13.6V.

This protective goggle 1 is made according to the purpose when the wearer wears the frost on the protective goggle (1) to turn on the power switch 10, the power supply from the power supply means (9) terminal ( 8) and the power supply lines 5 and 6 are applied to the electrode parts 3 and 4, and the power applied to the electrode parts 3 and 4 is heated through the heating part 2, thereby protecting the protective glasses 1. Will remove the frost trapped in). In other words, the heating unit 2 has a predetermined resistance and converts electrical energy into thermal energy to dissolve frost contained in the protective glasses 2.

As described above, since the electrode part inserted into the protective goggles is silver-printed in two lines on the upper and lower ends of the protective goggles, there is a problem that heat generated from the heating part is not evenly formed on the front of the protective goggles. In particular, the castles formed on the left and right sides of the protective glasses were not easily removed. In addition, since the electrode part appeared to have a thickness through the front of the protective glasses, it was in a state of obscuring the wearer's field of view or aesthetically unfavorable.

In addition, since the electrode part is formed at the top or the bottom, or the left or right side, the arrangement of the electrodes is not only simple, but also when the wearer does not turn off the power switch even after all the frost is removed while the wearer is turned on. Since the additionally formed film portion may collapse the protective glasses due to the strong heat that is sustained, there is a problem of lowering the effectiveness and reliability of the protective glasses.

In addition, in the conventional protective glasses, the heating parts are spaced apart from each other by the synthetic resistance, and the film does not undergo an aging treatment, causing thermal deformation of the film. An expensive indium by ITO treatment is used and a separate coating after the ITO treatment. Durability is weak because it does not, and the problem such as deformation of the protective glasses occurs when the heating temperature is more than 50 ℃.

In order to solve the above problems, the heating part is processed in parallel with a predetermined area with tin-oxide, the electrode part is formed by masking printing, and the film is heat-shrinked at a predetermined temperature and time so that the temperature is higher than the predetermined temperature. Prevents heat deformation, prevents excessive heat generation by PTC treatment, ensures even heat generation across the entire surface of the protective glasses, reduces the thickness of the electrode and prevents the electrode from being seen from the protective glasses, and directly solders the terminal parts. An object of the present invention is to provide a method for producing a protective goggle for preventing frost, which has been treated beautifully in appearance.

In addition, another object of the present invention is to provide a protective goggles manufactured by the manufacturing method.

1 is a schematic configuration diagram of a conventional anti-aging protective goggles,

2 is a schematic configuration diagram of a protective goggle for frosting according to the present invention,

Figure 3 is a flow chart showing the manufacturing process of the anti-aging safety glasses of the present invention.

♣ Explanation of symbols for main part of drawing ♣

1, 100: protective glasses 2, 102: heating unit

3, 4, 103, 104: electrode 5, 6, 105, 115: power supply line

7, 106: wire 8, 107: terminal

9, 108: power supply means 10, 109: power switch

110: PTC (Thermistor)

The present invention for the purpose of the above, the step of heat-treating the thermoplastic resin film for a predetermined temperature and time, the electrode treatment and sputtering the heating portion with TO (tin-oxide), and negatively masked printing electrode Forming a portion, corroding an electrode portion divided into predetermined equal parts with a corrosion solution, peeling a masked printed electrode portion, printing a power supply line negatively, and supplying a power supply line with a predetermined thickness Plating the steel sheet, peeling the plated power supply line, spray coating the transparent paint, cogging the power terminal, and performing PTC (thermistor) treatment to protect the heating portion; It can be achieved by providing a method of manufacturing a protective goggles for frost protection, including the step of cutting and resistance value in a predetermined shape.

In addition, the present invention is connected to a power supply means for supplying a voltage of a predetermined size, a power switch for switching the power of the power supply means, one end of the power supply means and one end of the power switch is a predetermined length A frost protection goggle made of an electric wire for supplying power, comprising: a plurality of electrode portions formed in pairs at predetermined intervals at both ends of the goggles, and heating processed in parallel in an area of predetermined intervals in the paired electrode portions; And a power supply line for connecting the electrode unit in parallel, a PTC (thermistor) for turning on or off the power applied from the power supply line according to the temperature of the heating unit, and the wire and the power supply line It is characterized by providing a frost protection goggles made by including a terminal connected to the soldering on one side.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a schematic configuration diagram of a protective goggle for frost according to the present invention.

As the material of the protective glasses 100 of the present invention, a thermoplastic resin film was used, and as the thermoplastic resin film, a PET (Polyethylene Terephthalate Resin) film, a PC (Poly Carbonate Resin; polycarbonate resin) film, Tricarbonate Resin (TC) film, Cellulose Propionate Resin (CP) film, Cellulose Acetate Resin (Cellulose Acetate Resin) film, etc. are applied.

On the surface of the thermoplastic resin film used as the material of the protective glasses 100, the heating part 102 sputtered with TO (Tin-Oxygen; tin-oxide) has a predetermined area (the minimum amount of heat generated evenly). Area). In addition, the heating units 102 are formed with the electrode units 103 and 104, respectively, so that the applied power is supplied to the heating unit 102. The power supply lines 105 and 115 are connected to the electrode portions 103 and 104, respectively, and the power supply lines 105 and 115 are treated by masking printing and peeled off. The electrode portions 103 and 104 are formed in pairs at both ends of the protective glasses 100 in a predetermined direction, preferably in a vertical direction, and the pair of electrode portions 103 and 104 are formed in plural at predetermined intervals. The electrode portions 103 and 104 are arranged differently at upper and lower ends according to the shape of the protective glasses 100. In addition, the electrode portions 103 and 104 may be configured in pairs at both ends of the protective glasses 100 in the horizontal direction.

In addition, the heating unit 102 is formed in parallel in the region of a predetermined interval on the pair of electrode portions 103 and 104, the PTC (thermistor) 110 so that the heating unit 102 does not generate heat above a set temperature, respectively. ) And soldered directly to the terminal 107 without connecting a separate wire. The terminal 107 is connected to a power supply means 108 for supplying a voltage of a predetermined magnitude, and a power switch 109 for switching the supply of power to an on or off state. The PTC 110 turns on or off the power applied from the power supply line 115 according to the temperature of the heating unit 102. That is, the PTC 110 cuts off the power applied to the power supply line 109 when the temperature of the heating unit 102 rises above the set temperature, and applies the cut off power when the temperature of the heating unit 102 falls below the set temperature.

One end of the power supply means 108 and one end of the power switch 109 is connected to a wire 106 for supplying power to a predetermined length, the wire 106 is a power supply line of the protective glasses 100 ( 105 and 115 are connected to the terminal 107, and the terminal 107 is connected to one side of the protective glasses 100 by soldering. The power supply lines 105 and 115 connect the electrode portions 103 and 104 in parallel, respectively, and are connected to the + pole or the-pole.

Referring to the flow chart of FIG. 3 for the manufacturing method of the anti-frost protection goggles 100, first, the main material of the protective goggles 100 in step S10 was used PET film, PET film is a predetermined temperature and time Heat shrinkage (aging) is carried out (for example, 4 hours at 100 ° C). The heat shrink treatment of the PET film is performed to prevent heat deformation of the film.

In step S11, tin-oxide (Tin-Oxygen) is sputtered on a surface of the heat-shrinked protective glasses 100 in a predetermined area unit. At this time, the area unit to be sputtered is set to a range in which the heat generation is even. It is desirable to set an appropriate area based on the experiment. In addition, it is preferable to process the sputtered area in plural in parallel so that the resistance of the corresponding section is constant.

The electrode portions 103 and 104 are formed by masking printing at one end of the sputtered unit area in step S12, and the masking printing is processed negatively.

In step S13, the electrode parts 103 and 104 divided into predetermined equal parts are corroded with a corrosion solution, and in step S14, the masked and printed electrode parts 103 and 104 are peeled off, and in step S15, the negative part is removed. To print the power supply lines 105 and 115.

In step S16, the power supply line 105 is plated to a predetermined thickness, and the material to be plated is made of copper and nickel to a predetermined thickness (preferably 0.2 mu). In addition, in step S17, the plated power supply line is peeled off, and in step S18, a transparent paint is applied to spray coating. The paint uses PET or acrylic.

In step S19, a cogging operation for connecting the terminal 107 to which power is connected through the wire 106 is performed, and in step S20, the protective glasses 100 are predetermined by the heating of the heating unit 102. The protection glasses 100 are prevented from rising to a temperature (for example, 80 ° C.) and subjected to a PTC (thermistor) 110 for protection. The PTC (thermistor) 110 has its zero load resistance value increasing with increasing temperature, and its current-voltage characteristic is determined by the voltage and temperature applied between the terminals of the thermistor at the specified temperature in the stopped air. It is the relationship with the current (DC or AC 40/60 Hz) measured after equilibrium, and the maximum voltage is the direct current voltage that can be applied to the thermistor continuously after switching to the standard ambient temperature in stationary air.

When the protective goggle 100 is manufactured as described above, in step S21, the manufacturing process is performed by cutting into a predetermined shape and shape corresponding to the protective goggle 100 and inspecting the resistance value (about 9 Ω). Is done.

The characteristics of the anti-aging protective goggles of the present invention is a DC power supply of 12 to 13.6V, the means for supplying power 108 uses a battery (battery or rechargeable battery), the total resistance of the protective goggles 100 is 9 It is -9.5 (ohm), and residual resistance is 0 (ohm) by plating process.

In addition, the connection of power is parallel processing by staggered resistance of the section is constant, there is almost no thermal deformation due to aging by heat shrinkage, sputtering (in O ₂ atmosphere) only tin-oxide without indium The coating process not only makes the manufacturing cost cheap, but also the durability. In addition, overheating of the protective glasses 100 is prevented by the PTC 110 treatment of each part of the corresponding heating unit 102, the appearance is beautiful due to the soldering process of the terminal, and heat generation of the heating unit 102 is prevented. Even heating is achieved over the protective goggles 100. In addition, the rear surface of the protective glasses performs an anti-fog treatment so that the breathing is not frosted.

In addition, the present invention can also be applied to the case of treating the ITO (Indium, Tin, Oxygen; Indium-Tin oxide) in the manufacturing step of the heating unit 2 inserted into the protective goggle 1, which is an expensive protective goggle (1) ) Can be applied when making

The scope of application of the anti-aging safety glasses of the present invention is widely applied in snowmobiles, skis, skates, helmets, automobiles, aircraft, marine, glasses or industrial use.

As described above, the anti-aging protective goggles of the present invention are not limited to the above-described embodiments, and those skilled in the art will be able to easily change or replace them.

As described above, the anti-aging protective glasses of the present invention heat-treat the thermoplastic resin film, and then sputter the heating part with tin-oxide, mask the electrode part, print the power supply line with plating, and simultaneously prevent the heating part from overheating. PTC treatment for the purpose, the production cost is low by using tin-oxide, evenly arranged heating and electrode parts to evenly generate heat throughout the protective goggles to prevent the protective goggles, Plating treatment and soldering of the terminal connection not only do not interfere with the wearer's vision, but also aesthetically beautiful, there is an effect of improving workability and wide application range and performance according to the production of protective glasses.

Claims (7)

Treating the thermoplastic resin film by heat shrink for a predetermined temperature and time; Treating and sputtering the heating portion (tin-oxide), Negatively masking printing to form electrode portions; Corroding the electrode portion divided into predetermined equal parts with a corrosion solution; Peeling the masked printed electrode portion, Negatively printing the power supply line, Plating the power supply line to a predetermined thickness; Peeling the plated power supply line; Spray coating with transparent paint, Cogging a power terminal; Performing a PTC (thermistor) process to protect the heating part, Method of manufacturing a protective goggle for preventing frost, characterized in that it comprises the step of inspecting the cut and the resistance value in a predetermined shape. According to claim 1, wherein the thermoplastic resin film PET (Polyethylene Terephthalate Resin; polyethylene terephthalate resin), PC (Poly Carbonate Resin (polycarbonate resin) film, TC (Tricarbonate Resin (tricarbonate resin) film, CP (Cellulose) Propionate Resin; Cellulose propionate resin) or CA (Cellulose Acetate Resin; Cellulose acetate resin) A method for producing a protective goggle, characterized in that the selective application of any one. The method of claim 1, wherein the thermoplastic resin film is heat shrinked at 100 ° C. for 4 hours. The method of claim 1, wherein the power supply line is an alloy of copper and nickel, and has a thickness of 0.2 µ. The method of claim 1, wherein the spray coating transparent coating is a method for producing a protective goggle, characterized in that any one of PET or acrylic. Power supply means for supplying a voltage of a predetermined magnitude; A power switch for switching the power of the power supply means; In one end of the power supply means and one end of the power switch in the anti-frost protection goggles made of a wire for supplying power, A plurality of electrode portions formed in pairs at both ends of the protective glasses at predetermined intervals, A heating unit processed in parallel in an area of a predetermined interval on the pair of electrode units; A power supply line for connecting the electrode units in parallel; PTC (thermistor) for turning on or off the power applied from the power supply line according to the temperature of the heating unit, Protective wire for anti-frost protection, characterized in that the wire and the power supply line comprises a terminal connected by soldering to one side of the protective glasses. The protective goggle of claim 6, wherein the protective goggles are selectively applied to any one of snowmobiles, skis, skates, helmets, automobiles, aircrafts, ships, glasses, or industrial use.