KR100384465B1 - Illumination lamp having cartridge type negative ion generator - Google Patents

Abstract

PURPOSE: An illumination lamp having a cartridge type negative ion generator is provided to prevent an economical loss by exchanging only a malfunctioned negative ion generator when the negative ion generator has a fault. CONSTITUTION: An illumination lamp includes an upper case(1), a lower case(2), a negative ion generator(3), and an illumination tube(4). The upper case(1) has a printed circuit board therein. The printed circuit board is provided with a voltage circuit, a weighted capacitor and a stabilizer. The lower case(2) includes an inlet port(21), a cylinder(22) linearly connected to the inlet port(21) for forming a tunnel, and first and second electrode terminals. The negative ion generator(3) has a discharge pin making contact with the first electrode terminal, a charged tube electrically connected to the second electrode terminal, and an insulation tube(33).

Description

Lighting lamps with cartridge type negative ion generator

The present invention minimizes economic losses by maximizing the anion generating performance by the discharge pins and the charging plate, and extending the actual service life to the design life through the replacement or cleaning of the anion generating device which is paralyzed or degraded. A lighting lamp having a cartridge type negative ion generator is provided.

An air purifier is an anion released from an anion generator and is a kind of air purifier developed to remove decomposition of bacterial odor molecules such as sterilization and fungus, dust collection and tobacco smoke. Recently, the effects of negative ions can be seen only in expensive homes and large air cleaners in general homes and offices. In recent years, however, there have been attempts to apply the effects of these negative ions to lighting lamps that are much cheaper and smaller than air cleaners. Unexamined Utility Model Publication No. 95-34662, Japanese Patent Laid-Open No. 6-178821, Patent Publication No. 97-8480, Patent Publication Nos. 97-6047 and 2002-78792, Utility Model Publication No. 26693, and the like. .

Among these prior arts, lighting devices of the type 2, such as patent publication No. 97-6047, which allow anions to be released into the space formed in the center of the light tube cluster, are caused by the influence of electrons emitted from the light tube. Since the amount of negative ions generated is insignificant or most of the negative ions are lost, the negative ions are not effective in the same way, and this is the main cause of failure of practical use.

On the other hand, in Fig. 6A, in the conventional negative ion generator, the tip of the discharge pin a and the charge tube b is clean under the precondition that the discharge pin a is exactly positioned at the cross-sectional center of the charge tube b. It is maintained in the state, and the normal distance (c) between the tip of the discharge pin (a) and the tip of the charging tube (b) must maintain the design value so that when a negative ion is generated by discharge, a current of a predetermined pressure does not flow, so that a good negative Will emit.

However, if the tip of the discharge pin (a) and the tip of the charging tube (b) are blackened (d) due to dust, the normal distance (e) is shortened due to the blackening thickness, so as to c> c '. Changes to When the normal distance is shortened, the instantaneous voltage is so high that it is very abnormal. At this time, the adsorption of dust adsorbed due to the high voltage is a blackening phenomenon in the anion generator. The blackening phenomenon is not desirable for an anion generator built-in lighting lamp, and is a deadly phenomenon directly related to shortening the life of the lighting lamp.

Another cause of the blackening phenomenon is that the discharge pin is made of Cu and Al, which are susceptible to particle dropping due to the movement of electrons during discharge.

The second generation of negative ion generating device of the lighting lamp is prominent blackening phenomenon, the actual service life is too short. In general, the design life of an anion generator-equipped illumination lamp is known as 8,000 hours. If you look at the average daily use time of four hours, it is long enough to correspond to 2,000 days, or two years and two months. However, the third generation type negative ion generator built-in lighting lamp is only 360 ~ 1440 hours, depending on the usage environment, the period is only 3 to 12 months. The actual service life is too short.

In addition, the illuminating device of Utility Model No. 269693 is a technically advanced third generation type by solving the above-mentioned problems of the second generation by changing the discharge direction of the anion so that the anion is released to the main surface of the casing. Since the negative ion generator is built in to the case, for example, if the negative ion generator fails due to blackening or other reasons, the case, the booster circuit, the light tube, and other elements are unclear. It is difficult to avoid serious situations that can only be discarded, and the economic losses inevitably suffer.

With this in mind, if the discharge pin and the condenser are not known for some reason, or if the negative ion dysfunction or malfunction of the negative ion generator is found due to blackening, either replace it or simply replace the negative ion generator in the lamp. It is natural to think that if it can be removed, cleaned and reloaded, the economic losses due to the failure and blackening of the anion generator can be reduced.

The present inventors who have paid attention to this point have finally achieved remarkable achievements and have proposed the present invention after long research and experiment.

It is an object of the present invention to provide a lighting lamp having a negative ion generating device that can be used only to replace the negative ion generating device with a functional paralysis or deterioration, or to simply reload it by simply cleaning the discharge pins and charging tubes contaminated with dust. .

Another object of the present invention is to maximize the ability to generate negative ions by the discharge pin for the lamp and the charging plate.

Another object of the present invention is to provide a lighting lamp having a negative ion generating device that can promote the permanent generation of negative ions using a case.

The first object is to form a cylinder in the form of a straight tunnel-shaped space by the combination of the entrance and the cylinder in the lower case of the lighting lamp, and the negative ion generating device is configured in a cartridge type that is loaded to be detachable to the cylinder Simply by simply inserting the cartridge type negative ion generating device into the cylinder through the entrance and exit, the cartridge type negative ion generating device loaded in the cylinder can be easily improved.

In addition, the second problem is that the discharge pin and the charging tube are made of stainless steel having the property that particles are not dropped even when the electrons move during discharge, and at least one of the discharge pin and the charging tube is plated with platinum and the opposite element is used. It can be achieved by increasing the discharge rate as the main material for radical formation by inducing the role of a reducing catalyst by coating with inexpensive palladium, compared to platinum has a performance comparable to the charging rate of platinum.

The third object of the present invention can be achieved by coating the outer surface of at least one of the upper case and the lower case with tourmaline and ceramic so that a large amount of negative ions are permanently generated by ionization.

1 is an exploded view of a removable negative ion generating device and an illumination lamp according to the present invention

Figure 2 is a partial cutaway front view of a part of the light tube is omitted

3 is a transverse plan view of the lower case;

Figure 4 is a longitudinal side view of the negative ion generating device

Figure 5 is a cross-sectional plan view of the lower case of the state where the negative ion generator is loaded

Figure 6a, b is a reference diagram showing a case where the blackening phenomenon occurs in the conventional negative ion generating device

<Description of the code | symbol about the principal part of drawing>

2: lower case 3: cartridge type negative ion generating device

21: doorway 22: cylinder

23, 24: terminal hole 25, 26: electrode terminal

31: discharge pin 32: charging tube

33: insulated tube 33a, b: through hole

34: diffusion grill

In FIG. 1, the illumination lamp is composed of an upper case 1 and a lower case 2, an anion generator 3, and a plurality of illumination tubes 4.

Referring to FIG. 2, the upper case 1 includes a PCB 5 having a ballast. The PCB 5 is a voltage at a level suitable for generating negative ions and a necessary element to boost the voltage, and is a universal component that has been applied to the third generation lighting lamp described above together with the lighting tube 4.

In FIG. 3, the main wall of the lower case 2 has an entrance 21. This entrance 21 is a hole through which the cartridge type negative ion generating device 3 first attempted in the present invention. The cross section of the doorway 21 is provided with means for proper loading and easy detachment of the cartridge type negative ion generating device 3. For example, when the doorway 21 is a square hole, at least one corner of the corners is formed differently from the shape of the other corner. The configuration condition of the entrance 21 is that when the cartridge type negative ion generator 3 is accommodated, the terminal for the charge tube and the terminal for the discharge pin given to the cartridge type negative ion generator 3 are in the cylinder 22 of the lower case 2. It is necessary to assemble so as to contact the negative electrode generating electrode terminal and the boosting electrode terminal of the PCB (5) exposed inside. In other words, it is a means for preventing misassembly of the cartridge type negative ion generating device 3.

The entrance 21 is connected to the cylinder 22. The cylinder 22 is straight. In addition, the entrance 21 and the cylinder 22 are combined to form a straight tunnel to accommodate the cartridge type negative ion generating device 3. Therefore, a mechanical tolerance is applied between the entrance 21, the cylinder 22, and the cartridge type negative ion generator 3 so that the cartridge type negative ion generator 3 can freely enter and exit.

Terminal holes 23 and 24 are formed on the left and right sidewalls of the cylinder 22 with a distance difference therebetween, and intermediate portions of the electrode terminals 25 and 26 are exposed to each terminal hole 23 and 24. Loaded. The first electrode terminal 25 is connected to the circuit for generating negative ions of the PCB 5 to be physically contacted and electrically connected to the discharge pin 31 of the cartridge type negative ion generator 3, and the second electrode terminal ( 26 is in electrical contact with the charging tube 32 of the negative ion generating device (3). In addition, the electrode terminals 25 and 26 are provided with spring-like elasticity as the contact portions 25a and 26a which are bent in a semicircle with the middle of the length of the band metal plate. The contact portions 25a and 26a are the portions to which the discharge pin 31 side terminal or the electrification tube 32 of the negative ion generator 3 selectively contacts, and at the same time is loaded on the cylinder 22 through the entrance 21. Receiving the cartridge type negative ion generator 3 to the storage chamber 21 of the lower case 2 by elastically clamping the terminal of the discharge pin 31 side of the negative ion generator 3 and the outer circumferential surface of the charging tube 32. It will stabilize your posture.

1 and 4, the cartridge type negative ion generating device 3 is configured to be freely loaded or removed from the cylinder 22 through the entrance 21 of the lower case 2. The cartridge type negative ion generator 3 is fixed by inserting the discharge pin 31 in the center of the insulated tube 33, and the rear end of the charge tube 32 is fixed to the outer side of the discharge pin 31. In addition, the rear end portion 31a of the discharge pin 31 is in physical contact with the first electrode terminal 25 when the cartridge type negative ion generating device 3 is loaded so as to span the entrance 21 and the cylinder 22. It bends in the crank shape exposed to the through-hole 33a of the insulated tube 33 as much as possible.

In addition, in addition to the above-described through hole 33a, another through hole 33b is drilled in the insulating tube 33. The through hole 33b is perforated so that the rear end of the charging tube 32 is exposed to contact the electrode terminal 26 for the boost circuit. A diffusion grill 34 is attached to the end of the insulator tube 33 so that negative ions generated therein smoothly diffuse out of the lower case 2. The diffusion grill 34 may be formed integrally with the insulating tube 33 by injection.

The total length of the cartridge type negative ion generator 3 in which the diffusion grill 34 is combined is set equal to the length of the entrance 21 and the cylinder 22 combined, and the cartridge type negative ion generator 3 is installed in the lower case 2. It is preferable in design to make use of the design by preventing the end of the cartridge type negative ion generating device 3 from protruding from the entrance 21 when it is loaded.

On the other hand, the discharge pin 31 and the charging tube 32 is made of stainless steel. Stainless steel, unlike Cu and Al, which are materials for discharge pins and charge tubes of conventional anion generators, does not blacken even when electrons move when discharged.

At least one of the discharge pin 31 and the charge tube 32 is plated with platinum, and the other component is coated with palladium. For example, the discharge pin 31 is plated with platinum and the charge tube 32 is coated with palladium, and when the charge tube 32 is plated with platinum, the discharge pin 31 is coated with palladium. Plating of the discharge pins 31 and the charge tube 32 with platinum can be considered, but the plating cost is high, which is burdensome. Platinum has the best electrification among metals. Palladium has a similar charge rate to platinum, but at a much lower cost, reducing the cost of coating.

In this way, if the discharge pin 31 and the charging tube 32 is selectively coated with platinum or palladium, the role of a reducing catalyst can be induced and used as a main material for radical formation, thus maximizing the amount of negative ions generated by increasing the charge rate. This becomes possible. Abundant anion diffusion means that air purification, deodorization and sterilization can be maximized.

When the cartridge type negative ion generating device 3 is accommodated in the cylinder 22 through the inlet and outlet 21, it appears as shown in FIG. 4. At this time, the rear end portion 31a of the discharge pin 31 is in contact with the first electrode terminal 25 and the outer circumferential surface of the charging tube 32 is in contact with the second electrode terminal 26 to be electrically connected. And the diffusion grill 34 is located exactly on the outer surface of the doorway (21).

As shown in the example, when the entrance 21 is formed at both ends of the cylinder 22, one end of the cartridge type negative ion generator 3 housed in the cylinder 22 is pushed with the finger toward the opposite side to the length of the finger tip. The cartridge type negative ion generating device 3 is pushed out to the opposite entrance 21 by pushing. Pull out the end of the negative ion generating device (3) is pulled out is separated from the doorway (21). When the lamp is used, the amount of negative ions released is less than before, so that the discharge pin 31 and the charging tube 32 need to be cleaned, or when the broken negative ion generator 3 is replaced with a new one.

In addition, the outer surface of at least one case, such as the outer surface of the upper case 1, the outer surface of the lower case 2, and the outer surface of the upper case 1 and the lower case 2, may be coated with tourmaline, which is tourmaline and ceramic. It may be. This increases the amount of oxygen, the emission of far infrared rays, and the amount of anions generated. In particular, tourmaline reacts with moisture in the air rather than charged electrons by using a small amount of radioactive element movement, so that the excitation in the state where the kinetic energy of the tourmaline field is higher-the internal energy absorbed by the gas molecule is the lowest value inherent in the gas molecule. If it exceeds, the kinetic energy is absorbed and the internal energy of the gas molecule is increased. The electrons of the energy release phenomena trying to return to the ground state become free electrons out of the orbit of the atom, so that a large amount of negative ions are permanently generated by ionization. do. Thus, high anion is expected.

The above description relates to an illumination lamp in which the entrance and exit 21 is formed on both sides of the cylinder 22, but the entrance and exit 21 may be provided only on one side. In this case, when the cartridge type negative ion generator 3 is loaded into the cylinder 22, the diffusion grill 34 stays slightly protruding out of the entrance 21 so that it can be picked up and removed by the nail tip. Such changes belong to the technical scope of the present invention.

As described above, the lighting lamp having the cartridge type negative ion generating device according to the present invention can be reloaded after replacement and separation cleaning of the negative ion generating device when the function of the negative ion generating device is paralyzed and degraded. Therefore, it is very economical compared to the conventional method of discarding the entire use of the lamp due to the failure of the negative ion generating device, deterioration of the function.

In the cartridge type negative ion generating device according to the present invention, as the reduction catalyst is increased by coating of platinum or palladium on the discharge pin and the charging plate, the amount of negative ions is increased by maximizing the charging rate according to radical formation. The effect of negative ions can be dramatically increased.

Claims (3)

An upper case 1 having a PCB 5 having a voltage circuit, a boost circuit and a ballast; An entrance 21 perforated on the main surface, a cylinder 22 connected in a straight line to the entrance 21 to form a tunnel, and installed to protrude into the cylinder 22 with a distance difference between the left and right side walls of the cylinder 22. A lower case 2 having a first electrode terminal 25 and a second electrode terminal 26 of one PCB 5; An electric charge tube connected to the discharge pin 31 and the second electrode terminal 26 which is free to enter and exit the cylinder 22 through the entrance 21 and is in electrical contact with the first electrode terminal 25. (32), a cartridge type negative ion generating device (3) combined with an insulating tube (33) having a diffusion grill (34) formed at an outer end thereof; Lighting lamp having a cartridge type negative ion generator, characterized in that consisting of; The method of claim 1, wherein the cartridge type negative ion generator 3 has a cartridge type negative ion generator, one of the discharge pin 31 and the charging tube 32 is plated with platinum and the other is coated with palladium. Lighting lamp. The lighting lamp according to claim 1, wherein at least one of the upper case (1) and the lower case (2) has a cartridge type negative ion generating device whose outer surface is coated with tourmaline.