CS277306B6 - Thermal protection placed in fluorescent lighter - Google Patents

Abstract

Thermal protection for opening the contacts of the electrical circuit of the fluorescent lighting body consists of a fixed strip (1) and a sliding strip (3). On the fixed strip (1) there are a fixed contact (13) and a movable contact (22), a bimetallic actuator (23) with a locking pin (24), a circular hole (14) and a longitudinal guide groove (15) located opposite each other. The sliding strip (3) has a guide pin (35) located in its middle part between the bent side guide walls (36) and a lower hole (34) below it to secure the position of the sliding strip (3). The lower end is bent and forms a controller (33) for closing the contacts (13, 22). The sliding strip (3) is controlled to the closed position mechanically by pressing the button (32) against the pressure of the compression spring (4). When the fluorescent lamp starting circuit is repeatedly switched on, or when the fluorescent lamp igniter is damaged by its contacts being permanently connected due to repeated electric discharges, the bimetallic actuator (23) heats up, it deflects and the locking pin (24) is ejected from the holes (14,34) of the fixed bar (1) and the sliding bar (3). Under the influence of the compression spring (4), the sliding bar (3) is moved to the open position.

Description

The invention relates to a thermal protection located inside or outside a fluorescent lighter, included in a series of starting circuits of a fluorescent luminaire.

In the known electrical circuits of fluorescent lamps, luminaires, a choke, a switching glow plug with its own interference suppression capacitor and a fluorescent tube are usually included. The switching glow plug with the capacitor usually forms one unit, the so-called fluorescent lighter or starter. It is usually housed in an electrically non-conductive housing, from which two conductive pins for bayonet mounting on the fluorescent body protrude. The luminaires may comprise one or more fluorescent tubes, each of which must have its own electrical circuit and a fluorescent igniter of appropriate power, which forms a so-called starting circuit. Fluorescent luminaires are often placed at great heights, mainly due to the uniformity of the lighting. The replacement of defective fluorescent lighters or fluorescent tubes is usually done in bulk until the lighting approaches the lower limit of the standard or even later, in cases where the fluorescent bodies are located in hard-to-reach places and the replacement of fluorescent tubes requires complex auxiliary mechanical equipment. Up to 35% of fluorescent tubes are already taken out of operation. However, defective fluorescent tubes are in continuous operation and draw electricity until they are replaced. Defects are caused either by an imperfect filling of the fluorescent tube, or by exhaustion of its service life, or by baking the contacts of the switching glow plug in the fluorescent lighter. In the event of an imperfect or low gas charge in the fluorescent lighter, it repeatedly switches on and off the starting circuit, so that the fluorescent lamp flashes until the contacts of the switching glow plug are permanently baked. The baking of the contacts is caused by the fact that the contacts at the point of contact are partially melted and joined by the electric discharge, so that they form a permanently closed electrical circuit which is closed via the resistive fibers of the fluorescent tube. Electricity consumption will increase about twofold permanently, but the fluorescent lamp will not light. On a national scale, this represents very high energy losses.

These disadvantages are eliminated by the thermal protection located inside or outside the fluorescent lighter, included in the series of the starting circuit of the fluorescent luminaire, intended to disconnect the power supply according to the invention.

The essence of the invention lies in the fact that the thermal protection is formed by a fixed strip, terminated at the lower end by a fastening conductive pin and at the upper end by a rectangular stop with a guide recess. In the lower part there is an electrically non-conductive carrier of the movable flexible arm of the movable contact and the bimetallic locking pin actuator, a fixed contact and a circular hole, above which a longitudinal guide groove is formed. It is further formed by a sliding bar located along the fixed bar engaging with its tapered end terminated by a button of insulator into the guide recess of the fixed bar and the lower part of which is bent as an actuator of the movable resilient arm of the movable contact. It has a lower hole for the locking pin in the middle part and a guide pin and curved side guide walls above it, while there is a compression spring between the rectangularly bent stop of the fixed rail and the button of the sliding rail.

CS 277306 B6 2

An example of a possible embodiment of thermal protection according to the invention is shown in the accompanying drawings, where Fig. 1 is a circuit diagram of a fluorescent body using the invention for one fluorescent tube, Fig. 2 is a structural diagram of a fluorescent lighter according to the invention; the thermal protection system is in the closed state, Fig. 4 is the thermal protection system in the open state, Fig. 5 is a fixed thermal protection strip, Fig. 6 is a sliding thermal protection strip, Fig. 7 is a detail of an electrically non-conductive carrier on fixed bar, Fig. 8 is a diagram of the location of the thermal protection directly in the housing of the fluorescent lighter, Fig. 9 is a diagram of the location of the thermal protection separately in the housing outside the fluorescent lighter and Fig. 10 is a diagram of the location of the thermal protection separately with the possibility of disconnecting electricity from the network.

The thermal protection according to the invention consists of two rails, one of which is fixed, the other sliding. The fixed strip 1 has a lower part terminated by a fixing conductive pin 11, which at the same time forms an electrical contact.

In the lower third of the fixed strip 1 there is a hole 17 for fixing an electrically non-conductive carrier 2, on which a movable flexible arm 21 of movable contact 22 and a bimetallic actuator 23 are mounted, which consists of a bimetallic strip 231 with a wound heating resistance wire 232 isolated from the bimetallic strip. 231 by a non-conductive sleeve 233. At the free end of the bimetallic strip 231, a locking pin 24 made of insulator is fixed. However, the locking pin 24 may be made of a metallic material for strength reasons, but must be isolated from the bimetallic strip 231 of the bimetallic actuator 23. A circular hole 14 is formed on the fixed rail 1 against the locking pin 24 for inserting the locking pin 24. Above this circular hole 14 a longitudinal guide groove 15 is formed for the guide pin 35 of the sliding rail 3, which limits the movement of this sliding rail 3 only upwards and downwards. The upper end of the fixed rail 1 is bent at a right angle and thus forms a rectangular bent stop 12 for the sliding rail 3, which is inserted with its tapered end 31 into the guide recess 16 of the fixed rail 1. The sliding rail 2 has a lower part deviated from the longitudinal plane and is terminated controller 33 of insulator. It has two holes in the middle. The lower hole 34 serves to insert the locking pin 24 in the closed position, when the lower hole 34 of the sliding bar 3 is in position against the circular hole 14 of the fixed bar 1, the upper hole 38 is between the curved side guide walls 36 and serves to fasten the guide pin 35. The upper part of the sliding bar 3 has a tapered end 31 on which a button 32 made of insulator is pressed. Between this button 32 and the rectangularly bent stop 12 of the fixed rail 1, at the narrowed end 31 of the sliding rail 3, there is a compression spring 4. A movable spring arm 21 is mounted on the electrically non-conductive carrier 2, at the free end of which there is a movable contact 22. the state rests on a fixed contact 13 formed on the fixed rail 1, for example by a press-fit.

From a constructional point of view, however, it is suitable to place the thermal protection according to the invention also outside the fluorescent lighter in a separate non-conductive housing of the same construction with a control button. This system must also be connected in the same electrical branch as the fluorescent lighter, or in the starting circuit according to the diagram in Fig. 9.

A second alternative to the design of the thermal protection according to the invention is that the electric current at the mains supply can be switched off at the same time according to the diagram in Fig. 10, thus disconnecting the entire fluorescent circuit. This can be done in several ways. For example, it is connected to the fixed rail 1 and the sliding rail 2 after one stripped contact so as to switch on and off at the same time as the sliding rail 2 moves, or the contact from the fixed rail 1 can be mounted on the base of the thermal protection housing. These contacts are not drawn in the accompanying drawings. Both contacts will be connected to the mains terminals.

Similarly, this case can be solved by means of a microswitch which is fixed, for example, to the base of the thermal protection housing, and the insulator actuator 22 2 is adjusted to engage a microswitch in the closed position, which is also not shown in the drawings.

The thermal protection function according to the invention is as follows. The current of the fluorescent lamp circuit passes through the fixing conductive pin 11, the fixed strip 1 through the fixed contact 13 and the movable contact 12, the movable flexible arm 21 into the heating resistance wire 232 wound on the bimetallic actuator 23 to the switching glow plug and simultaneously through the suppression capacitor to the second fixing conductive pin.

If the fluorescent lighter in the circumference of the fluorescent body is damaged or the life of the fluorescent tube ends, the electric current through the circuit will increase, which will heat the bimetallic actuator 23, deflect it and slide the locking pin 24 out of the openings of the fixed rail 1 and sliding rail 2. under the pressure of the compression spring 4, the sliding bar 2 is moved to the open position, thereby opening the contacts of the electrical circuit. After replacing the fluorescent tube, by sliding the sliding bar 2 with the button 32 into the closed position, it ensures the flow of electric current through the circuit again.

The thermal protection according to the invention can be used with several fluorescent lamps used to illuminate rooms, halls and workplaces in companies and the like.

Claims (1)

Thermal protection located inside or outside the fluorescent lighter, included in the series of the starting circuit of the fluorescent luminaire, intended to disconnect the power supply, characterized in that it consists of a fixed strip (1) terminated at the lower end by a fixing conductive pin (11) the upper end of a rectangular bent stop (12) with a guide recess (16) having in its lower part an electrically non-conductive carrier (2) of a movable flexible arm (21) of a movable contact (22) and a bimetallic actuator (23) of a locking pin (24), a fixed contact (13) and a circular opening (14), above which a longitudinal guide groove (15) is formed and a sliding bar (3) located along the fixed bar (1) fitting with its tapered end (31) terminated by a button (32) of insulator into guide recess (16) of the fixed rail (1) and the lower part of which is bent as an actuator (33) of the movable flexible arm (21) of the movable contact (22) and that a lower hole (34) for the locking pin (24) is formed in the middle part. and place it above it between the guide pin (35) and the curved side guide wall (36), a compression spring (4) between the rectangularly bent stop (12) of the fixed rail (1) and the button (32) of the sliding rail (3).