DE9411753U1 - Lamp circuit unit - Google Patents

Description

Patent Trust Company

for electric light bulbs mbH., Munich

Lamp circuit unit

The invention relates to a lamp, in particular a glow lamp, and an electrical circuit for operating or controlling this lamp according to claim 1.

A main application area for this type of lamp, in addition to auxiliary lighting, is signal and warning displays. When a change in the status of a system occurs, the lamp is activated and operated intermittently or continuously.

An electrical circuit is required for the control, which usually comprises several components arranged on a circuit board. For example, DE-PS 27 30 829 discloses a circuit for a glow lamp which operates the lamp continuously or intermittently depending on the position of a thermal switch. The disadvantage of these and similar previous concepts is the large amount of space required by the circuit board, which requires a spatial separation of the lamp and the control or operating electronics.

The invention is based on the object of eliminating the disadvantages mentioned and providing a compact unit consisting of a lamp and an electrical circuit. In addition, light beam shaping and guidance should optionally be possible to increase the light intensity in the direction of a preferred visible side of the lamp. In addition, the lamp-circuit unit should be protected against external influences such as shock loads.

This object is achieved according to the invention by the characterizing features of claim 1. Further advantageous embodiments of the invention are explained in the subclaims directed thereto.

The basic idea is to embed the lamp including the circuit arrangement in a block made of at least partially translucent insulating material, in particular plastic. The lamp and the circuit arrangement are completely

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or only partially surrounded by the block. This can be done, for example, by spraying or casting. In particular, a part of an electrical component, for example the connection surface of a component, can be led outwards using SMD (Surface Mounted Device) technology as a contact surface for making contact with a socket. The components of the circuit arrangement are fixed in their spatial position relative to one another and relative to the lamp bulb and the power supply lines by the insulating material. This has the advantage that a circuit board can be dispensed with entirely and the spatial positioning of the components can therefore be much more flexible and space-saving. In addition - in contrast to the flat circuit board - a largely spatial, close and therefore very compact arrangement of components and lines is possible. The insulating material, for example a plastic, has greater breakdown field strengths than the air that usually surrounds the components. This is especially true when operating in environments with high humidity, e.g. in damp rooms. The insulating block also offers protection against shock loads, such as those that can occur during handling or transport.

A main advantage of the invention - the integration of a lamp including ballast or control electronics within a unit - is made possible by a targeted selection of the design and placement of the electrical components near the power supply lines. The power supply lines can be led outwards at one or both ends of the lamp bulb by means of a seal, e.g. by pinching. An electrical component can advantageously also serve as a light-directing element, for example as an optical reflector to increase the light intensity in the direction of the visible side of the lamp circuit unit. A flat, film-like component, e.g. a film resistor or a film capacitor, which partially surrounds the lamp bulb, is suitable. The side of the foil-like component facing the lamp bulb is designed as a mirror surface, e.g. by vapor-depositing a metal such as silver, gold, aluminum, copper, or others. Part of the surface of the insulating block can also have the contour of a reflector and be provided with a reflective layer. If necessary, a protective layer, e.g. made of plastic, can be applied to the back. In addition, it is possible to arrange one or more components of the circuit on the side of the reflector facing away from the lamp bulb, i.e. on its back, for example by applying electrical components using SMD technology or layer technology. In individual cases, the specific arrangement of the components depends, among other things, on the following:

on the circuit used itself and on the designs used, namely conventional design, foil or SMD technology as well as layer technology.

The intermittent operation of a lamp is particularly important for signal or warning displays, since this mode of operation, with a suitably selected flashing frequency - typically in the range of 1 Hz to several Hz - has a more obvious signaling effect than, for example, continuous light.

A preferred embodiment of the lamp circuit unit according to the invention therefore has a glow lamp within the insulating block and a known electronic flip-flop connected to it. In its simplest form, this consists of a resistor connected in series to a power supply, which charges a capacitor connected in parallel to the electrodes of the glow lamp. To operate the lamp circuit unit on alternating voltage, for example the mains supply with a mains frequency of 50 Hz and a mains voltage of 230 V, the flip-flop has a diode connected in series to a power supply. This limits the flow of current in one direction, so that the capacitor is initially charged. When the ignition voltage U^ is reached, the glow lamp ignites and burns with the burning voltage Uß between the electrodes. The capacitor discharges until the glow lamp goes out when the extinguishing voltage Ul is undershot. Ignition, burning and extinguishing voltages are essentially determined by a suitable choice of electrode spacing and material as well as the type and pressure of the filling gas. The flashing frequency fjj can be specifically influenced by the dimensioning of resistor R and capacitor C, whereby the following relationship applies approximately:

The resistor R also limits the discharge current through the glow lamp and thus influences its brightness. Typical resistance values, depending on the desired brightness, are in the order of a few 100 kQ. This means that the capacitance values required for the above-mentioned flashing frequencies are typically in the order of a few 100 nF.

The invention is explained in more detail below using some exemplary embodiments.

Figure la is a plan view of a neon lamp with a flip-flop circuit applied to a foil reflector, embedded in a transparent plastic block: for lateral light emission,
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Figure Ib is a front view of the lamp circuit unit of Figure la,

Figure 2 the back of the foil reflector from Figure 1,

Figure 3a is a side view of a glow lamp with a film capacitor acting as a reflector as well as a diode and a resistor in a conventional design, embedded in a transparent plastic block for lateral light emission,

Figure 3b is a front view of the lamp circuit unit from Figure 3a,

Figure 3c shows the top view of the visible surface of the lamp circuit unit from Figure 3a,

Figure 4a is a side view of a glow lamp with a flip-flop integrated into the power supply, embedded in a transparent plastic block,

Figure 4b is a front view of the lamp circuit unit from Figure 4a,
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Figure 4c is a plan view of the lamp circuit unit of Figure 4a,

Figures 1a and 1b show a top view and front view of a lamp circuit unit. It is suitable for lateral light emission and consists of the following components embedded in a transparent cuboid-shaped plastic block 1: a glow lamp 2 with a flat film 3 acting as a reflector and a flip-flop circuit applied to the side of the film 3 facing away from the lamp bulb - the back of the reflector (see Figure 2). The flip-flop circuit consists of the following components in SMD technology: a resistor 4 with a value of 220 kQ, a diode 5 and a capacitor 6 with a value of 450 nF. This results in a flashing frequency of approx. 5 Hz.

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The glow lamp 2 consists of a circular cylindrical lamp bulb 7 made of lead glass with an internal volume of approximately Ω,Π cm ³ . Inside the lamp bulb 7 there is a gas mixture of 99.95% neon and 0.05% krypton at a total filling pressure of 177 hPa. Furthermore, two axially and parallel elongated electrodes 8a, 8b made of metal are arranged inside. Their length and diameter are 3.5 mm and 0.9 mm respectively. The electrodes 8a, 8b are each connected to a power supply 9a, 9b. The lamp bulb 7 has a pinch foot 10 at its first end, through which the power supplies 9a, 9b are passed in a gas-tight manner, and a pump tip 11 opposite the pinch foot 10. The total length of the bulb 7 is approximately 13 mm.

The film 3 has a rectangular shape and is made of glass fiber reinforced epoxy. The film 3 is arranged parallel to the visible side 12 of the plastic block 1, the distance to the surface of the lamp bulb 7 being approximately 2 mm. The side of the film 3 facing the lamp bulb 7 and the visible side 12 is vapor-deposited with a reflective aluminum layer in a manner known per se. The side edges 13a, 13b of the film 3 are aligned parallel to the lamp's longitudinal axis. The back of the reflector film 3 is shown in detail in Figure 2. Along its side edges 13a, 13b, the back of the reflector film 3 is provided with a conductor track 14a, 14b. The SMD diode 5 is connected in series to the first conductor track 14a and the SMD resistor 4 is connected in series to the second conductor track 14b. The SMD capacitor 6 is arranged between the conductor tracks 14a, 14b - also directly on the back of the film 3. It is connected to both conductor tracks 14a, 14b by means of the connecting track 15.

The power supply lines 9a, 9b are attached to the first end of the conductor tracks 14a, 14b. These each have a circular arc-like section 16a, 16b between the foil 3 and the crimping foot 10 (see Figure 1a). The opposite end of the conductor tracks 14a, 14b is connected via a piece of wire 17a, 17b to a pin-shaped electrical connection 18a, 18b, which are led out of the plastic block 1. These two connections 18a, 18b are used to make electrical contact with a socket (not shown).

In one variant, the side of the surface of the plastic block opposite the visible side has a contour similar to a circular cylinder. This is coated with a metal film that acts as a reflector. The side of the metal film facing away from the lamp bulb is provided with an insulating layer, on which the

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A flip-flop circuit connected to a glow lamp, consisting of a capacitor, resistor and diode, is vapor-deposited using layer technology. A plastic layer is sprayed onto the circuit layer to protect it from damage.

Figures 3a to 3c show a longitudinal section, a front view and a top view (viewing direction according to arrow A) of a lamp circuit unit. In contrast to the embodiment in Figure 1, the glow lamp 19 has two-sided power leads 20a, 20b. In addition, the flip-flop is implemented using a film capacitor 21 and a diode 22 as well as a resistor 23 in a conventional miniature design.

The film capacitor 21, which acts as a reflector, consists of a multi-layer laminate made of alternating electrically conductive and dielectric layers. The electrically conductive layers consist of copper foil and are designed as two capacitor surfaces that interlock in a meandering manner and are insulated from one another by an epoxy film that acts as the capacitor's dielectric. The film capacitor 21 originally has a rectangular base. To optimize the radiation characteristics, it is concavely curved and shaped approximately as one half of a vertical circular cylinder that surrounds a portion of the lamp bulb 24. The axis of the associated circular cylinder runs approximately collinearly with the lamp's longitudinal axis, so that the side edges 25a, 25b of the film 21 are aligned parallel to the lamp's longitudinal axis. The film capacitor 21 is arranged at a distance of approximately 2 mm from the surface of the lamp bulb 24. The surface 26 of the film capacitor 21 facing the lamp bulb 24 is coated with chrome and acts as a mirror surface facing the visible side 27 of the plastic block 28.

The power supply lines 20a, 20b are guided through the pinch feet 29a, 29b on both sides of the lamp bulb 24 into the plastic block 28. There they each have an arcuate section 30a, 30b that describes half a circle in the plane of the pinches. The power supply lines 20a, 20b are then guided in the direction along the side edges 25a and 25b and contacted at two diagonally opposite corners on the back of the film capacitor 21. A conductor track (not shown) is applied along the side edges 25a, 25b, which form the connections of the film capacitor. They connect the power supply lines 20a, 20b to the diode 22 and the resistor 23, respectively. The diode 22 and the resistor 23 are

each arranged on the broad side of the pinch feet 29b and 29a facing the visible side 27 and perpendicular to the longitudinal axis of the lamp bulb 24. Their free connection is connected to the pin-shaped electrical external connections 32b and 32a by means of a piece of wire 31b and 31a.
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Figures 4a to 4c show schematically a side view, a front view and a top view (viewing direction according to arrow B) of another embodiment of a lamp circuit unit. In contrast to the embodiment in Figure 1, only the capacitor 33 of the flip-flop is designed as an SMD component. The resistor 34 and the diode 35 of type 1N4148, on the other hand, are implemented as conventional miniature components. This very simple design does not have an optical reflector. The plastic block 36 is shaped as a circular cylinder.

The components of the flip-flop circuit are arranged in a spatially compact manner directly adjacent to the pinch foot 10 of the glow lamp 2. For this purpose, the SMD capacitor 33 is connected in parallel to the power supply lines 37a and 37b directly adjacent to the end of the pinch foot 10. The power supply lines then each have an arcuate section 38a, 38b that describes half a circle in the plane perpendicular to the pinch. This is followed by the diode 35 and the resistor 34, each electrically connected in series to a power supply line, which, viewed from above, are arranged essentially below the SMD capacitor 33. The power supply lines 37a, 37b run from the free ends of the diode 35 and the resistor 34, again via a circular arc-shaped section 39a, 39b, to the external contacts 40a, 40b arranged on the pinch-foot-side face of the block 36. This targeted, space-saving arrangement of the components limits the volume required for the flip-flop to approx. 5-5-5 mm^.

The invention is not limited to the embodiments given. In particular, individual features of different embodiments can also be combined with one another.

Claims (13)

-8-Protection claims 1. Lamp circuit unit, with - a lamp, in particular a glow lamp (2; 19), with a lamp bulb (7; 24), - an electrical circuit with two or more electrical components (4-6; 21-23; 33-35), - electrical power supplies (9a, 9b; 16a, 16b; 17a, 17b; 20a, 20b; 30a, 30b; 31a, 31b; 37a-39a, 37b-39b) which connect the lamp and the electrical circuit to each other and to external contacts (18a, 18b; 32a, 32b; 40a, 40b) which enable the connection of a supply voltage, - optionally an optical reflector (3; 21), and - a block (1; 28; 36) consisting of at least partially transparent insulating material, in which the lamp bulb (7; 24), the electrical circuit (4-6; 22; 23; 33-35) and, if applicable, the optical reflector (3; 21) are at least partially embedded. 2. Lamp circuit unit according to claim 1, characterized in that the electrical circuit is designed as a flip-flop (4-6; 21-23; 33-35). 3. Lamp circuit unit according to claim 2, characterized in that, in the case that the lamp is designed as a glow lamp (2; 19), the flip-flop circuit consists essentially of a capacitor (6; 21; 33), a resistor (4; 23; 34) and optionally a diode (5; 22; 35), the resistor (4; 23; 34) and optionally the diode (5; 22; 35) being connected in series to the power supply lines (9a, 9b; 16a, 16b; 17a, 17b; 20a, 20b; 30a, 30b; 31a, 31b; 37a-39a, 37b-39b) and the capacitor (6; 21; 33) being connected in parallel to the glow lamp (2; 19). 4. Lamp circuit unit according to claim 1, characterized in that, in the case that the lamp circuit unit contains an optical reflector, this is formed by a film (3) which is mirrored on at least one side, the mirror side facing the lamp bulb (7). -9- 5. Lamp circuit unit according to claim 4, characterized in that the foil is additionally designed as a foil resistor. 6. Lamp circuit unit according to claim 4, characterized in that the film is additionally designed as a film capacitor (21). 7. Lamp circuit unit according to claim 1, characterized in that, in the case that the lamp circuit unit contains an optical reflector, this is designed as a reflective layer applied to a partial area of the surface of the block 8. Lamp circuit unit according to claim 4 to 7, characterized in that all or some of the components (4-6) of the electrical circuit are arranged on the back of the reflector (3). 9. Lamp circuit unit according to one of claims 4 to 6, characterized in that the film (3) has a substantially rectangular basic shape, wherein the two power supply lines (9a, 9b) of the lamp (2), optionally via one or more electrical components, are each connected to a corner point of the film (3) and wherein the two free corner points are connected to external contacts (18a; 18b), optionally via one or more electrical components (4; 5) by means of power supply lines (17a; 17b). 10. Lamp circuit unit according to one of the preceding claims, characterized in that at least one of the electrical components is formed using layer technology. 11. Lamp circuit unit according to one of the preceding claims, characterized in that at least one of the electrical components is designed using SMD technology (4-6). 12. Lamp circuit unit according to claim 11, characterized in that the connection surface of at least one SMD component serves as an external contact. 13. Lamp circuit unit according to one of the preceding claims, characterized in that the insulating block (1; 28; 36) consists of plastic