JP2006059793A - Labor-saving energy-saving controller reducing power consumption of mercury lamp by combining screw type tool and auxiliary reactor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power controller prolonging life of a mercury lamp and a ballast, and reducing power consumption without damaging lamp characteristics, and taking man-hour saving at mounting into consideration. <P>SOLUTION: A plug-in connector type lead-out wire is provided for simply connecting a power controller between a lamp and a socket, and power is appropriately reduced according to a capacity of each mercury lamp equipment without damaging its characteristic function, and a power saving is attained by using a simple device-mounting method. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention relates to a power controller that reduces the power consumption of a mercury lamp, a screw-type instrument that eliminates the need for installation work, and a pinch fixture.

It was only a standard ballast and lamp combination.

Conventionally, mercury lamps have been widely used for the purpose of obtaining high illuminance. However, much power is consumed. By adding the device of the present invention, power consumption is reduced without impairing lamp characteristics. In addition, in order to save the work of installing this device, it is possible to save labor by using both a screw-type device and a pinch device.

In the electric circuit configuration of the mercury lamp, a lamp is connected to a ballast and the lamp is turned on by supplying a voltage to the ballast. Connect power controller A between the ballast and the lamp. At this time, it is possible to easily connect using the screw-type instrument B. The pinch attachment device C is a device for attaching a power controller, and saves labor.

By adding the device of the present invention to the existing equipment, the power consumption was greatly reduced and the work was simplified, leading to energy and labor savings.

The power controller A serves as an auxiliary reactor for the ballast. Depending on the mercury lamp (220W / 300W / 400W / 700W / 1000W), the number of coil turns, thickness, and core gap values are selected. As a result, the current flowing through the lamp is limited, leading to a reduction in power. Further, at the time of starting, the lamp tube is in an arc discharge state, and since the resistance value is negative, the starting current is large. This current is also limited to increase the life of the lamp and ballast. The electrical specifications are as follows.
Auxiliary reactor power-saving controller that can replace fluorescent mercury lamps with high-efficiency mercury lamps without replacing ballasts.
Description of symbols that enable replacement of a fluorescent mercury lamp HF300 with a high efficiency mercury lamp MF200 D. The auxiliary reactor of Table 1 (a).
Description of symbols that enable replacement of a fluorescent mercury lamp HF400 with a high-efficiency mercury lamp MF250 The auxiliary reactor of Table 1 (b).
Description of symbols that enable replacement of a fluorescent mercury lamp HF700 with a high-efficiency mercury lamp MF400 The auxiliary reactor of Table 1 (c).
Description of symbols that enable replacement of a fluorescent mercury lamp HF1000 with a high-efficiency mercury lamp MF700 The auxiliary reactor of Table 1 (d).
In order to selectively use the frequency bands 50 Hz and 60 Hz, the lead wire (4) is 4 lead wires (including 1 common wire and 1 lead wire). In order to protect the auxiliary reactor (1), it is filled with a polyurethane resin (2) that is waterproof, heat-resistant and electrically insulating, and is stored in the case (3). In consideration of heat deformation, polypropylene is used as the material. In order to block the radiant heat from the lamp, the heat-resistant braided tube (5) was used as the outer cover. Originally, in order to electrically connect the power controller A between the ballast and the lamp, the existing wiring must be disconnected and interrupted, but the use of the screw-in tool B enables labor saving. The lead wire (9) is taken out from between the base E39 (6) and the socket fitting (8) in the socket exterior (7), and connected to the power controller A with the connector (11). Similarly, in order to save labor, the electric power controller A is mounted on the sandwiching fixture C and is mounted by a simple method by simply sandwiching it in the existing conduit.

As a result of replacing the fluorescent mercury lamp HF400 with the high-efficiency mercury lamp MF250 without replacing the ballast, the fluorescent mercury lamp HF400 has a power of 408 [W] and an illuminance of 690 [lx]. In the case of a high-efficiency mercury lamp, the power was 260 [W] and the illuminance was 700 [lx].

The range of use of mercury lamps covers a wide range of factories, commercial facilities, etc., and this device contributes to the improvement of the global environment.

It is the actual drawing of this invention, and sectional drawing.

Explanation of symbols

Claims (3)

A screw-in device with a plug-in type lead wire for easy connection of the power controller between the lamp and socket. A pinch attachment that secures the power controller for the purpose of labor saving. Auxiliary reactor power-saving controller that can replace fluorescent mercury lamps with high-efficiency mercury lamps without replacing ballasts.
Description of symbols that enable replacement of a fluorescent mercury lamp HF300 with a high efficiency mercury lamp MF200 D. The auxiliary reactor of Table 1 (a).
Description of symbols that enable replacement of a fluorescent mercury lamp HF400 with a high-efficiency mercury lamp MF250 The auxiliary reactor of Table 1 (b).
Description of symbols that enable replacement of a fluorescent mercury lamp HF700 with a high-efficiency mercury lamp MF400 The auxiliary reactor of Table 1 (c).
Description of symbols that enable replacement of a fluorescent mercury lamp HF1000 with a high-efficiency mercury lamp MF700 The auxiliary reactor of Table 1 (d).

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