KR100272443B1 - An automatic apparatus of supplying pitch compound materials - Google Patents

Abstract

PURPOSE: An apparatus for automatically supplying composite material of oil and asphalt is provided to improve the productivity and the quality of the electronic ballast by injecting the composite material in an optimum condition. CONSTITUTION: An apparatus for automatically supplying composite material into an electronic ballast comprises a supporting bar(10) which is formed on an upper surface of a conveying device. A main tank(20) includes a heater for dissolving the composite material, a main impeller(22) and an auxiliary impeller(24) for agitating the composite material. An auxiliary tank(30) is communicated with one side of the main tank(20). The agitated composite material is transferred to the auxiliary tank(30) when the auxiliary impeller(24) is driven. A nozzle(31) is provided at an underside of the auxiliary tank(30). A cylinder is installed on the supporting bar. The cylinder includes a shaft for opening/closing the nozzle(31) and a rod for moving the shaft.

Description

Petroleum Asphalt Composite Material Automatic Feeding Device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a composite material automatic supply device for automatically supplying a composite material injected therein during the manufacture of an electronic ballast used in a lighting device. Particularly, the present invention relates to a sequential stirring and transportation of the petroleum asphalt composite material injected into the ballast. The present invention relates to an automatic petroleum asphalt composite material supplying device that can produce a ballast of the highest quality by injecting a composite material into a ballast in an optimal state under an optimal condition.

In general, the luminaire is composed of a light bulb and a ballast for supplying stable electricity to the light bulb, the performance of which is largely dependent on the quality of the ballast. This ballast is usually divided into electronic and conventional. The electronic ballast, unlike the conventional core ballast, eliminates flicker during lighting and has a power saving effect of at least 30% compared to the conventional ballast. This type of energy-saving electronic ballast has a tendency of increasing supply due to the demand for superior quality, such as low noise during use or initial lighting. The quality of the electronic ballast depends largely on the heat dissipation, impact resistance, and weather resistance of the ballast, and in order to impart such characteristics, a petroleum asphalt composite material is filled in the ballast. However, the petroleum asphalt composite material, which has been injected to provide impact resistance, heat resistance, and weather resistance to the electronic ballast, has been manually injected in the same way as the conventional ballast, so that the quality and performance are up to the original desired level. I can't reach it.

Petroleum asphalt composite materials used to provide weather resistance, heat resistance and impact resistance to electronic ballasts are mainly composed of petroleum asphalt and silicon powder, and are manufactured by adding a small amount of iron oxide. At this time, the petroleum asphalt (pitch) is 40 to 50%, silicon (SiO ₂ ) is mixed 50 to 60% to form a composite material. In particular, the electrical, chemical, and physical properties of petroleum asphalt are very sensitive to heat, and when used as raw materials, the properties of petroleum asphalt composites vary greatly depending on the histological change-degree of orientation depending on the degree of agitation with SiO _2. Special care is required. Therefore, care must be taken when dissolving the composite material and injecting it into the ballast so that there is no change in the properties of the original composite material.

Until now, petroleum asphalt composite materials were dissolved in gas as a heat source in the atmosphere and manually introduced into an electronic ballast. As such, when gas is used to dissolve the petroleum asphalt composite material, impurities generated during gas combustion are included in the petroleum asphalt composite material, and their inherent composition is destroyed, thereby deteriorating the characteristics of the excellent electronic ballast. .

As described above, when the petroleum asphalt composite material is manually stirred and dissolved as a gas, it is difficult to maintain a constant temperature and thus it is difficult to obtain a petroleum asphalt having smooth fluidity. When the ballast is introduced into the ballast in such a non-uniform state, it is impossible to obtain an electronic ballast having excellent weather resistance, heat resistance and impact resistance.

It is an object of the present invention to automatically carry out the stirring, conveying and discharging of petroleum asphalt composite material injected into the ballast sequentially, thereby injecting the composite material into the ballast in the best condition under optimum conditions to produce the highest quality ballast. It is to provide a composite material automatic supply device.

1 is an overall schematic view showing an automatic petroleum asphalt composite material supplying device according to the present invention,

Figure 2 is an enlarged detail view showing in more detail the composite material discharging unit of the automatic feeding device according to the present invention,

3 is a cross-sectional view taken along the line A-A of FIG.

Explanation of symbols on the main parts of the drawings

10: support 11: cover

20: main tank 21, 25: motor

22: chiefeller 23: agitator

24: auxiliary impeller 30: auxiliary tank

31: nozzle 32: transfer pipe

40: discharge means 41: pneumatic cylinder

42: Load 43: Link

44: shaft 45: high pressure nut

50: transfer means 60: preheat heater

70: control panel 80: cooling fan

90: support plate 91: holder

92: pressed fixing plate 93: cylinder fixing plate

100: ballast 110: composite material

As described above, the present invention provides a device for supplying and supplying petroleum asphalt composite material to an electronic ballast, comprising: a support having a transport means along which an upper surface of the ballast is seated and transported; A main tank refitted on one side of the support and having a heater for dissolving the composite material accommodated therein, and a main and a secondary impeller for stirring the dissolved composite material driven by a motor; It is fixed in communication with one side of the main tank receives the transported agitated composite material by the drive of the auxiliary impeller, has a heater therein and always maintain the supplied composite material at a constant temperature nozzle provided on the lower surface Auxiliary tank for discharging injection into the ballast through; And a shaft which opens or closes the nozzle of the auxiliary tank, and a contraction-expanded rod connected to open and close the nozzle by moving the shaft up and down, the cylinder vertically mounted on the support. Is achieved.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall schematic view showing a petroleum asphalt composite material automatic supply apparatus according to the present invention.

As shown, the main tank 20 is installed on the upper left side of the support 10, the main tank 20 is provided with a chimpel 22 which is driven in connection with the motor 21, the stirring portion 23 flows into the tank. Therefore, the stirring portion 23 of the chimney 22 is to agitate the composite material charged in the main tank 20, wherein the main tank 20 is provided with a resistance heater (not shown) The composite material is dissolved before stirring. The auxiliary impeller 24 is also installed in the main tank 20 spaced apart from the main impeller 22 by a predetermined distance, and is continuously driven by the composite material stirred by the main impeller 22 driven by the ear canal motor 25. While supplying to the auxiliary tank (30).

The auxiliary tank 30 is connected in a small size to the right side of the main tank 20 to receive the agitated composite material by driving the auxiliary impeller 24 from the main tank 20. The auxiliary tank 30 is provided with a nozzle 31 downward, together with a discharge means 40 for opening or closing the nozzle 31 and for discharging the composite material downward. The discharge means 40 will be described in detail with reference to FIG. 2. In particular, the auxiliary tank (30) is provided with a resistance heater (not shown) is heated to a constant temperature while the agitated composite material is discharged through the nozzle 31 in the optimum state, the optimum conditions to the electronic ballast located below Temporarily store for injection.

Below the auxiliary tank 30, the transfer means 50 is installed on the support 10, the electronic ballast is seated and transferred to the transfer means 50, and the nozzle 31 of the auxiliary tank 30 is moved. The composite material discharged through is charged. At this time, the detection sensor is provided in the vicinity of the conveying means 50 into which the composite material is charged and detects the excess or under degree of the composite material charged into the ballast, and automatically adjusts the moving speed of the conveying means 50 to the composite to the ballast. Allow the material to be charged in the appropriate amount. In particular, the preheating heater 60 is installed at the front of the portion where the composite material is charged so that the stabilizer is preheated to an appropriate temperature before charging the composite material to the ballast so that the loaded composite material is well bonded with the ballast. In addition, the support 10 is provided with a control panel 70 where the heating temperature, the moving speed of the transfer means 50, the cooling fan 80, the preheating heater 60, the operating state of the pneumatic cylinder 41 can be grasped. The instrument is attached.

Reference numeral 80 which is not described is a cooling fan for cooling the composite material loaded into the ballast, and reference numeral 11 denotes a cover for protecting and storing the auxiliary tank 30 and the cooling fan 80.

Figure 2 is an enlarged detail view showing in more detail the composite material discharging unit of the automatic feeding device according to the present invention.

The support plate 90 supports and supports the auxiliary tank 30 and the pneumatic cylinder 41 on the support (not shown). In detail, the support plate 90 supports and secures the auxiliary tank 30 to the supporting object so as to be spaced apart from the ballast which is seated and transported by the above-described transport means. A pneumatic cylinder 41 is placed in the upper portion of the auxiliary tank 30 to fix and support it. The pneumatic cylinder 41 is fixed to the fixing plate 92 by pressing the holding plate 91 on the support plate 90, and then fixed the cylinder fixing plate 93 in the lower portion thereof to mount the pneumatic cylinder 41. The rod 42 of the pneumatic cylinder 41 is positioned downwardly and is coupled to the shaft 44 by the link 43. The shaft 44 enters the auxiliary tank 30 so that its end opens / closes the nozzle 31. The shaft 44 also has the function of removing the blockage of the nozzle inlet by the composite material blocking the nozzle 31. In particular, a high-pressure nut 45 is attached to the outer periphery of the shaft 44 to seal the outside and the inside of the tank, and the composite material remaining in the auxiliary tank 30 before being charged to the ballast is caused by an external pollution source. To prevent contamination. As shown, the nozzle 31 is formed by protruding the bottom surface of the auxiliary tank 30. In addition, the transfer pipe 32 connected to the side wall of the auxiliary tank 30 allows the composite material to be transferred from the main tank to the auxiliary tank 30 while maintaining a constant temperature.

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 1, showing that the composite material 110 discharged from the nozzle is charged and transferred into the ballast 100 seated on a pair of right and left transfer means 50.

The operation of the present invention will now be described in detail with reference to conductive surfaces.

The composite material 110 charged into the main tank 20 is dissolved by a resistance heater in the main tank 20, and then the motor 21 is driven to rotate and stirr the main impeller 22. Then, the composite material 110 is moved toward the auxiliary impeller 24, and in this state, the auxiliary impeller 24 is also driven to supply the composite material 110 by stirring again into the auxiliary tank 30. The agitated and supplied composite material 110 waits for a discharge state in the auxiliary tank 30. At this time, the resistance heater in the auxiliary tank 30 is operated to prevent the composite material 110 from hardening. Keep it at a certain temperature. In such a state, when the ballast 100 seated on the conveying means 50 is positioned below the nozzle 31, the pneumatic cylinder 41 is operated to contract the rod 42, so that the shaft 44 connected thereto is raised. Accordingly, the end of the shaft 44 blocking the nozzle 31 opens the nozzle inlet to discharge the composite material 110 in the auxiliary tank 30 downward through the nozzle 31 by a predetermined amount. The discharged composite material 110 is injected into the ballast 100, the ballast 100 after the injection is moved to the cooling fan 80 by the transfer means 50 to be radiated heat-cooled.

As described above, the present invention sequentially performs the stirring, conveying, and discharging of the petroleum asphalt composite material injected into the ballast, thereby injecting the composite material into the ballast in the best condition under optimum conditions, thereby degrading defective products or quality. Prevents the production of the highest quality ballast. By such production automation, there is an effect that can ultimately reduce production costs and increase production.

Claims (5)

In the device for supplying and injecting petroleum asphalt composite material into the electronic ballast, A support having a transporting means along which the ballast is seated and transported along an upper surface thereof; A main tank refitted on one side of the support and having a heater for dissolving the composite material accommodated therein, and a main and a secondary impeller for stirring the dissolved composite material driven by a motor; It is fixed in communication with one side of the main tank receives the transported agitated composite material by the drive of the auxiliary impeller, has a heater therein and always maintain the supplied composite material at a constant temperature nozzle provided on the lower surface Auxiliary tank for discharging injection into the ballast through; And And a cylinder for opening or closing the nozzle of the auxiliary tank, and a cylinder that is contracted and expanded to open and close the nozzle by opening and closing the shaft and vertically mounted on the support. 2. The petroleum asphalt composite material of claim 1, wherein the conveying means is speed-adjusted so as to appropriately convey the electronic ballast seated on the upper side according to the stirring degree of the petroleum asphalt composite material and the discharge amount discharged from the nozzle. Feeder. The support plate according to claim 1, wherein the support plate fixes the cylinder at a predetermined interval from an upper portion of the support, a press fixing plate for fixing the cylinder to the support plate, a support for fixing the press fixing plate to the support plate, and the press fixing plate. A petroleum asphalt composite material automatic supply device, characterized in that it is fixed to the bottom surface of the cylinder fixing plate for mounting the cylinder. The petroleum asphalt composite material automatic feeding device according to claim 1, wherein the nozzle is fixed to be separated from the auxiliary tank, and the discharge amount can be adjusted according to the stirring degree and the chemical composition of the composite material. . 5. The petroleum asphalt composite material automatic feeding device according to claim 1 or 4, wherein the nozzle protrudes from the auxiliary tank to remove foreign substances by the end of the shaft.