KR102152176B1 - multi-electric heater arrayed multi- pennel of electric conduction - Google Patents

Abstract

The present invention relates to a multiple electric heater for a three-phase power with multiple adjacent conductive panels to quickly heat water to a high temperature by applying different powers alternately to the multiple heating induction conductive panels. The multiple electric heater for the three-phase power includes: a first heating induction conductive panel applied with a first power source and arranged to heat water using the first power; a second heating induction conductive panel applied with a second power to directly heat the water in the first heating space; a third heating induction conductive panel applied with a third power to directly heat the water in the second heating space and a third heating space; a pair of gap-maintaining insulators coupled to gap maintaining holes of the first to third heating induction conductive panels, maintaining a plurality of first to third heating spaces, and individually maintaining each of the applied powers; first to third power transmission units for transmitting the first to third power to the first to third heating induction conductive panels respectively; and a conduction-avoidance groove.

Description

Multi-electric heater arrayed multi-pennel of electric conduction with multiple adjacent conductive panels

The present invention relates to a multi-electric heater for a three-phase power supply having a plurality of adjacent conductive panels, and more particularly, to a plurality of heating induction conductive panels alternately applying different power to the adjacent one so that water can be quickly heated to high temperature It relates to a multi-electric heater for a three-phase power supply having a plurality of conductive panels.

In general, electric heaters that heat water are used in electric boilers, so that water in contact with a heater rod heated to a high temperature by receiving power is gradually heated to maintain a high temperature state.

However, since the heater rod of such an electric heater must be heated to a high temperature of 350°C or higher to heat the contacted water, the heat loss is high, so it takes considerable time to heat the water, and the electricity consumption is large due to the high electric loss. Since it is indirectly heated by the original body, there is a problem in that the efficiency is low and the operation and management costs are high.

In addition, while heating water, foreign matters are gradually attached to the heater rod, so that the heat transfer rate is lowered, so that the efficiency is lowered, or there is a problem in that it needs to be replaced, and the management cost according to the replacement is high.

The present invention was invented to solve the above problems, by arranging a plurality of heating induction conductive panels at regular intervals, and by alternately applying different power to them to heat water, and the panel shape is simple and convenient. To provide a multi-electric heater for a three-phase power supply having a plurality of adjacent conductive panels, which not only allows assembly but also requires less installation and maintenance costs, and has an object thereof.

In addition, in the present invention, a plurality of heating induction conductive panels are arranged at regular intervals, so that the heating space increases exponentially so that a large amount of water can be heated more quickly and quickly, as well as controlling the number of heating induction conductive panels. It is an object of the present invention to provide a multi-electric heater for a three-phase power supply having a plurality of adjacent conductive panels so as to quickly heat a desired and appropriate amount of water.

According to the present invention, according to the above object, the first power is applied among the three-phase commercial power, and the first heating induction has a predetermined heating zone for heating water with the first power, and a plurality of them are arranged at intervals. A conductive panel; A plurality of first heating induction conductive panels are alternately positioned in succession to form a plurality of first heating spaces, and a second power of the three-phase commercial power is applied to the same as the first power of the first heating induction conductive panel. A second heating induction conductive panel for directly heating water in the first heating space; The plurality of second heating induction conductive panels are alternately positioned in succession to form a plurality of second heating spaces, the first heating induction conductive panel and a plurality of third heating spaces are formed consecutively at the rear end, and the three-phase A third power source among commercial power sources is applied to directly heat the water in the second heating space and the third heating space like the second power source of the second heating induction conductive panel and the first power source of the first heating induction conductive panel. 3 heating induction conductive panel; The first heating induction conductive panel, the second heating induction conductive panel, and the third heating induction conductive panel are coupled to the spacing hole of the third heating induction conductive panel, and are located between them to provide a plurality of first to third heating spaces according to a predetermined distance. A pair of gap-maintaining insulators for maintaining and individually maintaining each applied power source; A first power transmission unit which is connected through the plurality of first heating induction conductive panels through power supply holes in succession and simultaneously to transmit the first power to the first heating induction conductive panel; A second power transmission unit which is connected through the power supply holes of the plurality of second heating induction conductive panels at the same time in succession to transmit the second power to the second heating induction conductive panel; A third power transmission unit for transmitting the third power to the third heating induction conductive panel by being simultaneously connected through the power supply holes of the plurality of third heating induction conductive panels; The first heating induction conductive panel, the second heating induction conductive panel, and the third heating induction conductive panel are located respectively, and a first power transmission part of the first heating induction conductive panel conducts the second and third heating induction. Do not contact the panel, prevent the second power transmission part of the second heating induction conductive panel from electrically contacting the first and third heating induction conductive panels, and transfer the third power to the third heating induction conductive panel The addition is achieved by an electric heater for a three-phase power source having a plurality of adjacent conductive panels including conduction avoidance grooves to prevent electrical contact with the first and second heating induction conductive panels.

Here, the first power transmission unit, the second power transmission unit, and the third power transmission unit are disposed between the first heating induction conductive panel, the second heating induction conductive panel, and the third heating induction conductive panel, respectively. An interval maintaining power transmission ring for transmitting power while maintaining a space between them, and a plurality of power transmission rings between each of the first heating induction conductive panel, the second heating induction conductive panel, and the third heating induction conductive panel. It is preferable to include a power transmission shaft assembly that is sequentially arranged and coupled through and integrated.

In the present invention, a plurality of heating induction conductive panels are arranged at regular intervals, and water is heated by alternately applying different power to them, and the panel shape is simple and convenient to assemble, and installation and maintenance costs are reduced. Since it requires less, it is possible to maximize productivity and installation rate, and there is an effect of setting an optimal heating state.

In addition, in the present invention, a plurality of heating induction conductive panels are arranged at regular intervals, so that the heating space increases exponentially so that a large amount of water can be heated faster and faster, and the number of heating induction conductive panels is controlled. It has the effect of maximizing user satisfaction by quickly heating an appropriate amount of water desired by the user and enabling installation to suit the user's taste.

1 is a perspective view showing a multi-electric heater for a three-phase power supply having a plurality of adjacent conductive panels according to the present invention,
2 is an exploded perspective view showing a multi-electric heater for a three-phase power supply having a plurality of adjacent conductive panels according to the present invention,
3 is a cross-sectional view showing a multiple electric heater for a three-phase power source having a plurality of adjacent conductive panels according to the present invention.

Hereinafter, a multi-electric heater for a three-phase power supply having a plurality of adjacent conductive panels according to the present invention will be described in detail with reference to the accompanying drawings.

In this multi-electric heater for three-phase power supply having a plurality of adjacent conductive panels, the three-phase commercial power is applied individually to each other, and the number of heating induction conductive panels can be controlled by the operator or user, and water is quickly supplied with the desired amount of heat. Hot water can be produced by direct heating.

As shown in FIG. 1, the multi-electric heater for a three-phase power supply having a plurality of conductive panels as described above includes a first heating induction conductive panel 1, a second heating induction conductive panel 3, and a third heating induction conductive panel. (4), spacing maintenance insulating part (5), first power transmission part (7), second power transmission part (9), third power transmission part (10), conduction avoidance groove (11), gap maintenance power transmission It consists of a ring 13 and a power transmission shaft assembly 15.

In particular, the first heating induction conductive panel (1), the second heating induction conductive panel (3), and the third heating induction conductive panel (4) are arranged at predetermined intervals, and they are repeatedly successively Are arranged in.

The first heating induction conductive panel 1 is applied with a first power among three-phase commercial power, and has a predetermined heating area for heating water with the first power, and a plurality of them are arranged at intervals. A first heating space is formed between the second heating induction conductive panel 3 arranged to be spaced apart from the heating region.

The second heating induction conductive panel 3 is alternately positioned in succession to each of the plurality of first heating induction conductive panels 1 to form a plurality of first heating spaces, and a second power of the three-phase commercial power is applied. As a result, water in the first heating space is directly heated like the first power source of the first heating induction conductive panel 1. A second heating space is formed between the third heating induction conductive panel 4 located on the other side of the second heating induction conductive panel 3.

The third heating induction conductive panel 4 is alternately positioned in succession to each of the plurality of second heating induction conductive panels 3 to form a plurality of second heating spaces, and the first heating induction located in succession at the repeated rear end A conductive panel 1 and a plurality of third heating spaces are formed, and a third power of the three-phase commercial power is applied to the second power supply and the first heating induction conductive panel of the second heating induction conductive panel 3 ( Like the first power source in 1), the water in the second heating space and the third heating space is directly heated.

The gap maintaining insulating part 5 is coupled through the gap maintaining hole formed in the first heating induction conductive panel 1, the second heating induction conductive panel 3, and the third heating induction conductive panel 4, and It is located between them and maintains a plurality of first to third heating spaces according to a certain spacing interval uniformly and uniformly, and each applied power is individually maintained. It is composed of a plurality of insulating rings and an insulating shaft assembly so that different power sources are individually maintained, and the first heating induction conductive panel (1) and the second heating induction conductive panel (3) and the third heating induction conduction Maintain an even spacing between each of the panels 4.

Here, the first to third heating spaces are between each of the first heating induction conductive panel 1, the second heating induction conductive panel 3, and the third heating induction conductive panel 4 are repeatedly arranged. The spacing-maintaining insulating part 5 is provided to maintain a state in which water can be directly heated so that the spacing is 7 mm or less.

The first power transmission unit 7 is connected through the power supply holes of the plurality of first heating induction conductive panels 1 in succession and at the same time to transmit the first power to the first heating induction conductive panel 1. . The power supply hole is formed at the same position in the first heating induction conductive panel 1 and is a terminal capable of applying power only to the first heating induction conductive panel 1.

Here, in the second heating induction conductive panel (3) and the third heating induction conductive panel (4), the first power transmission unit along a direction in which the power supply holes of the first heating induction conductive panel (1) are arranged. A conduction avoidance groove 11 is formed so that the first power source of (7) does not contact.

The second power transmission unit 9 is a location that does not overlap with the power supply holes of the plurality of first heating induction conductive panels 1, that is, power provided on the other side of the edge of the plurality of second heating induction conductive panels 3 The second power is transmitted to the second heating induction conductive panel 3 by being simultaneously connected through the application hole. The power supply hole is formed at the same position in the second heating induction conductive panel 3 and is a terminal capable of applying power only to the second heating induction conductive panel 3.

Here, in the first heating induction conductive panel (1) and the third heating induction conductive panel (4), the second power transmission unit along the direction in which the power supply holes of the second heating induction conductive panel (3) are arranged. A conduction avoidance groove 11 is formed so that the second power source of (9) does not contact.

The third power transmission unit 10 is connected through the power supply holes of the plurality of third heating induction conductive panels 4 at the same time, and transmits the third power to the third heating induction conductive panel 4. . The power supply hole is formed at the same position in the arranged third heating induction conductive panel 4 and is a terminal capable of applying power only to the third heating induction conductive panel 4.

Here, in the first heating induction conductive panel (1) and the second heating induction conductive panel (3), the third power transmission unit along the direction in which the power supply holes of the third heating induction conductive panel (4) are arranged. A conduction avoidance groove 11 is formed so that the second power source of 10 does not contact.

That is, the conduction avoidance groove 11 is located in each of the first heating induction conductive panel 1, the second heating induction conductive panel 3, and the third heating induction conductive panel, and the first heating induction conduction Make sure that the first power transmission part 7 of the panel 1 does not come into contact with the second and third heating induction conductive panels 3 and 4, and transfers the second power to the second heating induction conductive panel 3 Make sure that the part 9 does not make electrical contact with the first and third heating induction conductive panels 1 and 4, and the third power transmission part 10 of the third heating induction conductive panel 4 Avoid electrical contact with the first and second heating induction conductive panels (1, 3).

Meanwhile, each of the first power transmission unit 7, the second power transmission unit 9, and the third power transmission unit 10 has the first heating induction conductive panel 1 and the second heating induction conduction. A space-maintaining power transmission ring 13 disposed between the panel 3 and the third heating induction conductive panel 4 to transfer power while maintaining a gap therebetween, and the first heating induction conductive panel 1 And a power transmission shaft assembly (15) in which a plurality of power transmission rings are sequentially arranged in a row between each of the second heating induction conductive panel (3) and the third heating induction conductive panel (4) to penetrate through and integrate them. Configure.

The operation of the multi-electric heater for a three-phase power supply having a plurality of adjacent conductive panels according to the present invention as described above will be described as follows.

First, external power to the power transmission shaft assembly 15 of each of the first power transmission unit 7, the second power transmission unit 9, and the third power transmission unit 10, respectively, a first power supply and a first power supply. The 2nd power and the 3rd power are supplied.

The first power received from the power transmission shaft assembly 15 is simultaneously transmitted to each of the first heating induction conductive panels 1 through a plurality of spaced power transmission rings 13 to maintain a conductive state, and the The second power supply is simultaneously transmitted to each of the second heating induction conductive panels 3 through a plurality of spacing maintaining power transmission rings 13 to maintain a conductive state, and the third power supplying a plurality of spacing maintaining power supply rings Through (13), the third heating induction is simultaneously transmitted to each of the conductive panels 4 to maintain a conductive state.

Then, the water contained in the plurality of first heating spaces repeatedly formed between the first heating induction conductive panel 1 and the second heating induction conductive panel 3 is directly in the first heating space with equal intervals. It is heated to induce rapid heating of the whole through circulation and convection processes.

In addition, water accommodated in a plurality of second heating spaces repeatedly formed between the second heating induction conductive panel 3 and the third heating induction conductive panel 4 is directly in the second heating space at equal intervals. It is heated to induce rapid heating of the whole through circulation and convection processes.

In addition, water accommodated in a plurality of third heating spaces repeatedly formed between the third heating induction conductive panel 4 and the first heating induction conductive panel 1 is equally spaced for third heating. It is heated directly in space and induces rapid heating of the whole through circulation and convection processes.

Meanwhile, by adjusting and setting the number of repeated arrangements of the first heating induction conductive panel 1, the second heating induction conductive panel 3, and the third heating induction conductive panel 4, the number of heating spaces is reduced. If adjusted, the heating capacity can be adjusted as much as the operator or user wants, and the heating capacity can be expanded and reduced by expanding and reducing it conveniently and conveniently.

1: first heating induction conductive panel 3: second heating induction conductive panel
4: 3rd heating induction conductive panel 5: Insulation part maintaining spacing
7: first power transmission unit 9: second power transmission unit
10: 3rd power transmission unit 11: evangelism avoidance home
13: spacing maintenance power transmission ring 15: power transmission shaft assembly

Claims (2)

A first heating induction conductive panel in which a first power is applied among the three-phase commercial power, has a predetermined heating area for heating water with the first power, and a plurality of them are arranged at spaced intervals;
A plurality of first heating induction conductive panels are alternately positioned in succession to form a plurality of first heating spaces, and a second power of the three-phase commercial power is applied to the same as the first power of the first heating induction conductive panel. A second heating induction conductive panel for directly heating water in the first heating space;
The plurality of second heating induction conductive panels are alternately positioned in succession to form a plurality of second heating spaces, the first heating induction conductive panel and a plurality of third heating spaces are formed consecutively at the rear end, and the three-phase A third power source among commercial power sources is applied to directly heat the water in the second heating space and the third heating space like the second power source of the second heating induction conductive panel and the first power source of the first heating induction conductive panel. 3 heating induction conductive panel;
The first heating induction conductive panel, the second heating induction conductive panel, and the third heating induction conductive panel are coupled to the spacing hole of the third heating induction conductive panel, and are positioned between them to provide a plurality of first to third heating spaces according to a predetermined distance. A gap-maintaining insulation unit that maintains and individually maintains each applied power source;
A first power transmission unit which is connected through the plurality of first heating induction conductive panels through power supply holes in succession and simultaneously to transmit the first power to the first heating induction conductive panel;
A second power transmission unit for transmitting the second power to the second heating induction conductive panel by being simultaneously connected through the power supply holes of the plurality of second heating induction conductive panels;
A third power transmission unit for transmitting the third power to the third heating induction conductive panel by being simultaneously connected through the power supply holes of the plurality of third heating induction conductive panels;
The first heating-inducing conductive panel, the second heating-inducing conductive panel, and the third heating-inducing conductive panel are located respectively, and a first power transmission part of the first heating-inducing conductive panel is used to conduct the second and third heating induction. Make sure that the panel is not contacted, and the second power transmission part of the second heating-inducing conductive panel is not electrically contacted with the first and third heating-inducing conductive panels, and the third power is transmitted to the third heating-inducing conductive panel. A multi-electric heater for a three-phase power source having a plurality of adjacent conductive panels, characterized in that it comprises a conduction avoidance groove for preventing electrical contact with the additional first and second heating induction conductive panels.
The method of claim 1;
The first power transmission unit, the second power transmission unit, and the third power transmission unit,
A spacing maintenance power transmission ring disposed between each of the first heating induction conductive panel, the second heating induction conductive panel, and the third heating induction conductive panel to transfer power while maintaining a gap therebetween;
A plurality of power transmission rings are sequentially arranged in a row between each of the first heating induction conductive panel, the second heating induction conductive panel and the third heating induction conductive panel to penetrate through and integrate the power transmission shaft assembly. Multi-electric heater for three-phase power having a plurality of adjacent conductive panels, characterized in that.

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