KR100342681B1 - Heater for large sideview mirror - Google Patents

Abstract

A substrate 1 made of an insulating and flame retardant resin, a front positive electrode 21 formed at an edge of the upper part of the substrate 1, and a front negative electrode formed at the center of the upper part of the substrate 1 (22), the front auxiliary positive electrode (23) and the front auxiliary negative electrode (24), which are alternately arranged in parallel between the front positive electrode (21) and the front negative electrode (22), and the front surface described above. The front PTC resistive layer 3 covering the negative electrode 21, the front negative electrode 22, the front auxiliary positive electrode 23, and the front auxiliary negative electrode 24, and the center of the lower portion of the substrate 1 described above. An electrical connection between the rear positive electrode 41 formed on the rear electrode, the rear negative electrode 42 formed on the lower edge of the substrate 1, and the front positive electrode 21 and the rear positive electrode 41; A second electrode electrically connecting the through electrode 61 to the front negative electrode 22 and the rear negative electrode 42. It consists of a through electrode 62, and the electrode is installed on both sides of the front and back, and connected in parallel to reduce the resistance value by 1/2 to increase the amount of current flow to increase the total current flow, and at the same time, By providing a larger size of the front electrode than the size of the rear electrode provides a heating device for a large side-view mirror that can efficiently use the heat generated by generating more heat than the heat generated on the back.

Description

Heating device for large side view mirror {HEATER FOR LARGE SIDEVIEW MIRROR}

The present invention relates to a heating device of a large side view mirror, and more specifically, to install the electrodes on both sides of the front and rear, and then connected in parallel to reduce the resistance value to 1/2 to increase the overall flow of current The present invention relates to a heating apparatus for a large side view mirror, which increases the amount of heat generated and at the same time increases the size of the front electrode to be larger than the size of the electrode on the back so that the amount of heat generated on the front side is greater than the amount of heat generated on the back side.

In general, a vehicle is provided with a side view mirror (M) on the outer left and right sides of the driver's seat as shown in FIG. 1 so as to be able to see the rear of the driving lane or the side lane. Since the side view mirror (M) provides the driver with important information about the vehicle running in the left and right rear of the vehicle while the vehicle is running, it is very important to keep it clean at all times.

Conventionally, when rain or snow falls on the vehicle while driving, the rain or snow gets on the side-view mirror M, and the rear view is difficult to see. It is dangerous to clean the side view mirror (M) by using the moment stopped due to the stop signal of a traffic light, or stop the driving for a while and put the vehicle safely to the right side of the road before cleaning the side view mirror (M). There was a very troublesome point. In addition, even if the side view mirror (M) has been wiped clean like this, it is inconvenient to continue the cumbersome operation as described above because the rainy view or snow gets in the back again after a short time after restarting the operation. There is a ham.

In order to alleviate this inconvenience and inconvenience, if the rain or snow on the side view mirror gets dirty due to rain or snow during the vehicle operation, the rear view through the side view mirror does not stop. In addition, a technique for a device for safe vehicle operation by researching to easily remove raindrops or snow on both mirrors of side view mirrors has been studied.

Such a device is roughly classified into a method of wiping off water using a mechanical mechanism, a method of drying water using hot air, and a method of drying water using heat generated from a heating element. Among the above methods, a technique for drying water using heat generated from a heater has been in the spotlight. As an example of such a technique, Korean Utility Model Application Publication No. 90-7627 (Notice date: AD 1990 8) 'Heater Miller' on 23 March) and 'Heater Miller' on 90-8118 (published September 3, 1990 AD). However, the above-described techniques have a disadvantage in that a heater cannot be designed to be distributed throughout the side-view mirror because the heater needs to form a distance between the heater and the heater because it serves as an electrode and a resistor. There is a problem that the power consumption is wasted by not being controlled.

In order to improve this disadvantage, by separating the electrode and the resistive layer to distribute the resistive layer, which is a heating layer throughout the side-view mirror, and the above-mentioned resistive layer having a PTC characteristic technology that can control the temperature constant Korean Patent Application Publication No. 89-17999 (published date: December 18, 1989 AD), 'Electric device made of conductive polymer', and Patent Application Publication No. 94-10814 (published date: AD 1994) November 16, 1, 'thin film heating element'.

However, the heating apparatus of the related art side view mirror has a relatively small amount of heat generated from the heater, so that it can be applied to a small side view mirror having a small size, but cannot be applied to a large side view mirror having a large size.

An object of the present invention is to solve such a conventional problem, by installing the electrodes on both sides of the front and rear, and connecting them in parallel to reduce the resistance value by 1/2 to increase the total amount of current flow to generate heat At the same time increasing the size of the front electrode larger than the size of the electrode on the back to provide a heating device of a large side view mirror that can use the heat efficiently by making the amount of heat generated on the front side more than the amount of heat generated on the back side.

1 is a view showing a position of a general side view mirror.

Figure 2 is a plan view of the heating device of a large side view mirror according to an embodiment of the present invention.

3 is a cross-sectional structural view of the heating apparatus of the large side view mirror according to the embodiment of the present invention.

Figure 4 is another plan view of the heating apparatus of the large side view mirror according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1 substrate 3 front PTC resistive layer

5: rear PTC resistive layer 21: front positive electrode

22: front negative electrode 23: front auxiliary positive electrode

24: auxiliary negative electrode of the front portion 41: positive electrode of the rear portion

42: rear negative electrode 43: rear auxiliary positive electrode

44: auxiliary anode negative electrode 61: first through electrode

62: second through electrode

Hereinafter, the most preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily implement the present invention.

As shown in Fig. 2 and Fig. 3, the configuration of the heating apparatus of the side view mirror for a large vehicle according to the embodiment of the present invention includes a substrate 1 made of an insulating and flame-retardant resin, and the substrate 1 described above. The front positive electrode 21 is formed at the upper edge of the top, the front negative electrode 22 is formed in the center of the upper portion of the substrate 1, the front positive electrode 21 and the front negative electrode 22 The front auxiliary positive electrode 23 and the front auxiliary negative electrode 24 which are installed in parallel to each other in parallel to each other, the front positive electrode 21 and the front negative electrode 22 and the front auxiliary positive electrode 23 ) And a front PTC resistive layer 3 covering the front side auxiliary negative electrode 24 and a lower portion of the substrate 1 and having a width greater than that of the front positive electrode 21 and the front negative electrode 22. The rear positive electrode 41 is formed narrowly, and is formed at the edge of the lower portion of the substrate 1, and the positive electrode of the front portion is formed. A rear side negative electrode 42 which is formed to be narrower in width than the pole 21 and the front negative electrode 22, and a rear side auxiliary positive electrode which is alternately installed in parallel between the rear positive electrode 41 and the rear negative electrode 42. (43) and the rear subsidiary negative electrode 44, and the rear PTC resistive layer 5 covering the rear positive electrode 41, the rear negative electrode 42, the rear auxiliary positive electrode 43, and the rear auxiliary negative electrode 44; The first through electrode 61 electrically connecting the front positive electrode 21 and the rear positive electrode 41 to each other, and the second connecting electrode electrically connecting the front negative electrode 22 and the rear negative electrode 42 to each other. It comprises a through electrode 62.

By the above configuration, the action of the heating apparatus of the large side view mirror according to the embodiment of the present invention is as follows.

If rain or snow falls while the vehicle is in operation, the driver's side and rear view is obstructed by moisture, moisture, or snow on the side-view mirror. In addition, if the vehicle is parked at night during the winter, the side view mirror is stuck in the morning, which interferes with the driver's rear and rear view. In this case, when the driver turns on the switch (not shown) to remove moisture, water, snow, and frost formed in the side view mirror, the current output from the battery (not shown) is divided into the front part and the rear part. It flows through the following path.

1. Front part: Front positive electrode 21 → Front auxiliary positive electrode 23 → Front PTC resistive layer 3 → Front negative electrode 22

2. Rear part: Rear positive electrode (41) → Rear auxiliary positive electrode (43) → Rear PTC resistive layer (5) → Rear negative electrode (42)

The front PTC resistive layer 3 and the rear PTC resistive layer 5 serve as heat generating layers due to the resistive component. The front positive electrode 21 and the rear positive electrode 41 are formed by the first through electrode 61. Since the front negative electrode 22 and the rear negative electrode 42 are electrically connected to each other by the second through electrode 62, the front PTC resistive layer 3 and the rear PTC resistive layer ( 5) is electrically connected in parallel, the overall synthesis resistance is reduced to less than 1/2, and a large current flows. That is, referring to the basic calorie equation (E = I ² Rt), in which the calorific value is proportional to the resistance value but the current value is proportional to the square, the front PTC resistive layer 3 and the rear PTC resistive layer 5 are connected in parallel to each other. Instead of reducing the resistance to 1/2 or less, the large amount of current can flow to increase the overall calorific value. Therefore, the heat generation becomes large, so that frost and moisture can be removed within a short time due to the increase in heat generation, and thus it is suitable for a large side view mirror as well as a small side view mirror.

In this case, the front positive electrode 21 and the front negative electrode 22 have larger widths of the electrodes than the rear positive electrode 41 and the rear negative electrode 42 to decrease the resistance value, thereby increasing the amount of current to the front and rear parts. The heat flows more on the front side rather than on the same side, so that the calorific value can be used more efficiently.

Since the glass is attached to the front PTC resistive layer 3 by using an adhesive layer, resistance heat generated from the front PTC resistive layer 3 and the rear PTC resistive layer 5 is transferred to the glass, thereby forming on the surface of the glass. Moisture, moisture, snow and frost are removed.

On the other hand, the front PTC resistive layer 3 and the rear PTC resistive layer 5 is made of a carbon carbon paste (carbon paste), the resistance value is rapidly increased when the heating temperature exceeds a certain temperature due to the PTC characteristics, the amount of current Since the heating temperature is kept constant, the overheating is prevented.

The positive electrode and the negative electrode may be changed according to the application direction of the power supply, and as shown in FIG. 4, the pattern shape of the main electrode and the auxiliary electrode may be configured in various shapes.

As described above, in an embodiment of the present invention, the electrodes are installed on both sides of the front and rear surfaces, and then connected in parallel to reduce the resistance value by 1/2, thereby increasing the amount of heat generated by increasing the total amount of current flow. By heating the size of the front electrode to be larger than the size of the electrode on the back side, it is possible to provide a heating device for a large side view mirror having an effect of efficiently utilizing the heat amount by causing the amount of heat generated on the front side to be greater than the amount of heat generated on the back side. Such effects of the present invention may be variously modified and used within the scope of the side view mirror without departing from the technical scope of the present invention.

Claims (3)

(Correction) A substrate 1 made of an insulating and flame retardant resin, a front positive electrode 21 formed at an edge of the upper portion of the substrate 1, and a center formed on the upper portion of the substrate 1 A front side auxiliary positive electrode 23 and a front side auxiliary negative electrode 24 which are alternately disposed in parallel between the front negative electrode 22 and the front positive electrode 21 and the front negative electrode 22; The front PTC resistive layer 3 covering the front positive electrode 21, the front negative electrode 22, the front auxiliary positive electrode 23, and the front auxiliary negative electrode 24, and the substrate 1 The rear positive electrode 41 formed at the center of the lower part, the rear negative electrode 42 formed at the lower edge of the substrate 1, and the front positive electrode 21 and the rear positive electrode 41 are electrically connected to each other. The first through electrode 61 to be connected, and the front negative electrode 22 and the rear negative electrode 42 are electrically connected to each other. A second heating device for large side view mirror, characterized in that comprises a through-hole interconnection (62). (New) The apparatus of claim 1, further comprising a rear auxiliary positive electrode 43 and a rear auxiliary negative electrode 44 which are alternately installed in parallel between the rear positive electrode 41 and the rear negative electrode 42. Heating device for a large side view mirror, characterized in that. (New) The method of claim 2, further comprising a rear PTC resistive layer (5) covering the rear positive electrode (41), the rear negative electrode (42), the rear auxiliary positive electrode (43) and the rear auxiliary negative electrode (44). Heating device for a large side view mirror, characterized in that made.