Process of manufacturing heat resistant and low carbon plate for circuit breaker

Abstract

A process of manufacturing a heat resistant and low carbon plate for a circuit breaker includes preparing a heat resistant and low carbon plate for a circuit breaker; coating the heat resistant and low carbon plate with organic material; coating the organic material with inorganic material; and heating and drying the heat resistant and low carbon plate. The process continuously grips each of heat resistant and low carbon plates conveyed on a conveyor with a coat application device being used for the coating steps. A circuit breaker having the heat resistant and low carbon plate is also provided.

Claims

1. A process of manufacturing a heat resistant and low carbon plate for a circuit breaker, comprising: (1) preparing a heat resistant and low carbon plate for a circuit breaker; (2) coating the heat resistant and low carbon plate with organic material; (3) coating the coated organic material with inorganic material; and (4) heating and drying the double coated heat resistant and low carbon plate; wherein the organic material includes polyamide and polyester (PE), and wherein 25-75 ml of modified polysiloxane is added to the inorganic material.

2. The process of claim 1, wherein step (4) is a two-stage heating and drying.

3. The process of claim 1, wherein step (4) is a two-stage heating and drying, and wherein in a first stage heating temperature is 100-120° C. and lasts for 30 minutes and in a second stage heating temperature is 180-200° C. and lasts for 30 minutes.

4. The process of claim 1, wherein both the organic material and the inorganic material are coated by means of spray coating or manual coating.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is an exploded perspective view showing a process of manufacturing a heat resistant and low carbon plate for a circuit breaker according to the invention;

(2) FIG. 2 is a top view of the circuit breaker incorporating the heat resistant and low carbon plate; and

(3) FIG. 3 is a perspective view of the circuit breaker incorporating the heat resistant and low carbon plate.

DETAILED DESCRIPTION OF THE INVENTION

(4) Referring to FIG. 1, a conveyor 10 of the invention includes a positioning member 11 and a base 12. A robotic arm (not shown) is used to grip a heat resistant and low carbon plate 5 and position same on the positioning member 11. The conveyor 10 moves forward. A coat application device 13 includes a main body 131 and a cushion layer 132 formed on the main body 131. The coat application device 13 is used to coat a layer of organic material 14 of the heat resistant and low carbon plate 5 with inorganic material 15. The inorganic material 15 is heated in two stages prior to sending the heat resistant and low carbon plate 5 to an oven (not shown) for drying by heating.

(5) A process of manufacturing the heat resistant and low carbon plate 5 for a circuit breaker in accordance with the invention comprises the steps of preparing a heat resistant and low carbon plate 5; coating the heat resistant and low carbon plate 5 with organic material 14; coating the organic material 14 with inorganic material 15; and heating and drying the heat resistant and low carbon plate 5 to secure the inorganic material 15 onto the organic material 14.

(6) The organic material 14 includes polyamide and polyester (PE). 25-75 ml of modified polysiloxane is added to the inorganic material 15. After coating the organic material 14 with the inorganic material 15 by means of the coat application device 13, the heat resistant and low carbon plate 5 is sent to an oven for drying by heating. The heating is a two-stage one. For example, the heat resistant and low carbon plates 5 are gripped by the robotic arm sequentially with coating and heating being performed thereafter on the conveyor 10.

(7) On the heat resistant and low carbon plate 5, the inorganic material 15 is secured onto the organic material 14 by heating in which a chemical reaction occurs between the inorganic material 15 and the organic material 14. Heating temperatures are different. For example, in a first stage heating temperate is 100-120° C. and heating lasts for 30 minutes and in a second stage heating temperature is 180-200° C. ad heating lasts for 30 minutes.

(8) Both the organic material 14 and the inorganic material 15 are coated by means of spray coating or manual coating.

(9) A circuit breaker has the heat resistant and low carbon plate 5 coated with an organic material 14 which is in turn coated with an inorganic material 15. The heat resistant and low carbon plate 5 includes two parallel side walls 51 and a base member 52 interconnecting the side walls 51.

(10) Referring to FIGS. 2 and 3, the circuit breaker includes a lever 1, a link 2, a moveable member 3, a guard 4, a heat resistant and low carbon plate 5, a plurality of grids 6, two side members 7, a base board 8, and a plurality of contacts 9. An arc extinguishing chamber consists of the grids 6 and the side members 7. All of the lever 1, the link 2, the moveable member 3, the guard 4, the heat resistant and low carbon plate 5, the grids 6, the side members 7, the base board 8, and the contacts 9 are well known devices and thus a detailed description thereof is omitted herein for the sake of brevity.

(11) The invention has the following characteristics and advantages:

(12) The plate is heat resistant and has low carbon residue after being subject to high heat. Thus, the heat resistant and low carbon plates can prevent the circuit breaker from being broken.

(13) The heat resistant and low carbon plate does not change appearance of the circuit breaker. The organic material coated with the inorganic material provides a double layer protection to the circuit breaker so that the circuit breaker is heat resistant and have low carbon residue being generated after being subject to high heat.

(14) The circuit breaker can withstand high heat. Otherwise, it may be broken. Low carbon residue is generated due to the novel manufacturing process.

(15) It has double layer protection and can continuously generate air current to extinguish arc.

(16) Arc is substantially extinguished. Also, minimum carbon residue is generated on the contacts of the circuit breaker. Otherwise, short circuit may occur.

(17) No appearance change. Transparent coating. Decreased number of the manufacturing steps. Primer is not required. All coating steps are done in one process. The inorganic material and the organic material are secured together.

(18) The manufacturing process is continuous with maximum yield.

(19) While the invention has been described in terms of preferred embodiments, those skilled in the art will recognize that the invention can be practiced with modifications within the spirit and scope of the appended claims.