The invention may be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. Moreover, in the figures, like referenced numerals designate corresponding parts throughout the different views.
A starter for a gas discharge light source, such as a fluorescent lamp, is capable of optimizing operation of a particular gas discharge light source being started with the starter. In addition, the starter is capable of adjusting operation during the life of the gas discharge light source as the characteristics of the particular individual gas discharge light source change. The starter is also capable of being operated with any current limiting device, such as a ballast, and can monitor operational parameters of the gas discharge light source following startup.
The gas discharge light source 104 may be a fluorescent lamp, a neon lamp, a sodium vapor lamp, a xenon flash lamp, or any other form of artificial light source(s) that generates visible light by flowing an electric current through a gas. The gas discharge light source 104 may include a first filament 110 and a second filament 112 disposed in the gas. The first and second filaments 110 and 112 may be any form of cathode. Accordingly, in some examples, both the first and second filaments 110 and 112 may be electrical filaments formed with metal that may give off electrons when heated. In other examples, the first filament 110 may be an electrical filament formed with metal that gives of electrons when heated, and the second filament 112 may be some other form of current conducting material. The gas discharge light source 104 may include a housing in which the starter 100 is disposed. The housing may form at least a portion of the gas discharge light source 14. Accordingly, the gas discharge light source 104 and the starter 100 may be an integrally formed unit. Alternatively, the starter 100 may be a replaceable component included in the housing of the gas discharge light source 104. In still another alternative, the starter 100 may be external to, and separable from, the gas discharge light source 104. In this example, the starter 100 may be directly or indirectly coupled with the gas discharge light source 104.
The starter 100 depicted in
The memory 122 may be any combination of volatile and non-volatile memory, such as for example a magnetic media and a flash memory or other similar data storage devices in communication with the processor 116. The memory 122 may store the electrical parameters measured and/or derived by the processor 116 during operation. The memory 122 may also store a software configuration of the starter 100. In addition, the memory 122 may be used to store other information pertaining to the functionality or operation of the starter 100, such as predetermined operational parameters, service records, etc. The memory 116 may be internal and/or external to the processor 116.
During operation, the starter 100 may monitor the current supplied to the gas discharged light source 104 on the power supply line 108 using the current sensor 118. The current sensor 118 may be any form of circuit or device capable of providing a signal output indicative of a sensed current. In one example, the current sensor 118 includes a shunt resistor. The current sensor 118 includes functionality to measure the voltage drop across the shunt resistor and convert the measured voltage to a current that is indicative of the current supplied to the gas discharge light source 104. The current signal output by the current sensor 118 may be provided to the processor 116 as a signal input on a current sensing line 126.
The processor 116 may also receive a lamp voltage indication signal on a lamp voltage line 128. The lamp voltage indication may represent a magnitude of voltage supplied by the power source 106 via the ballast 102 to the gas discharge light source 104. In the example of
The processor 116 may also receive a first filament voltage signal on a first filament voltage line 130, and a second filament voltage signal on a second filament voltage line 132. Similar to the lamp voltage line 128, the first and second filament voltage lines 130 and 132 may included transducers, filtering, etc., to condition and/or transform the respective filament voltages to be compatible with input capability of the processor 116.
The switch 120 may be controlled by an output signal from the processor 116 on a switch control line 134. The switch 120 may be toggled by the processor 116 between an open and a closed position as described later. The switch 120 may be coupled between the first filament 110 and the second filament 112. Accordingly, when closed, the switch 120 provides a hard wired series connection between the first filament 110 and the second filament 112. The switch 120 may be one or more semiconductors, silicon controlled rectifiers (SCRs), reed switches, relays, and/or any other circuit or mechanism capable of being toggled between a conducting and a non-conducting state as directed by the processor 116.
During operation, when the ballast 102 is initially energized by the power source 106, the processor 116 may toggle the switch 120 to a closed position. Thus, the first and second filaments 110 and 112 may be hardwired in series with the power source 106 via the ballast 102. In addition, the processor 116 may calculate a “rcold” filament resistance value (rcold) for the particular gas discharge light source 104 that is coupled with the starter 104. Calculation of rcold may be based on the current measured by the current sensor 118, and a measured voltage of at least one of the first and second filaments 110 and 112.
The processor 116 may calculate the gas discharge light source specific “cold” filament resistance value (rcold) for each of the first and second filaments 110 and 112. Alternatively, or in addition, the voltages or calculated gas discharge light source specific rcold values may be averaged. In one example, the power source 106 is an alternating current (AC) power source, and the processor 116 may calculate rcold by sampling the voltage and current at a determined sample rate, and converting the voltage and current to root mean squared (RMS) values. The determined sample rate may be a value stored in the memory 122 that is accessed by the processor 116. In one example, the sample rate may be greater than the frequency of the power source 106. In another example, the sample rate may be greater than about twice the frequency of the power source 106. In another example, the voltage and current may be processed through respective analog filters, and the filtered signals may be provided to the processor 116. The filtered signals provide by the analog filters may be proportional to the voltage and current and representative of the average voltage and current received by the analog filters.
Due to variations in materials and manufacturing, the calculated rcold value of a particular gas discharge light source 104 can vary widely, even among similarly manufactured light sources. In addition, as a gas discharge light source ages, the properties of the filaments and other materials may change causing non-uniform and unpredictable variation in the calculated rcold value of an individual gas discharge light source 104. Accordingly, determination of a gas discharge light source specific “cold” filament resistance (rcold) value may customize the starter 100 to optimize operation of the particular gas discharge light source 104 coupled therewith. Using the calculated rcold value, the first and second filaments 110 and 112 may be preheated for a period of time that is determined based on the calculated rcold value. The duration of the preheat cycle may be the period of time that the first and second filaments 110 and 112 are coupled in series with the power source 106 to allow the temperature of the first and second filaments 110 and 112 to increase to a desired temperature.
As the first and second filaments 110 and 112 are heated, free electrons may be given off into the gas present in the gas discharge light source 104. These charged particles reduce the resistance of a current path through the gas. When the temperature of the first and second filaments 110 and 112 have reached the optimum temperature to strike an arc in the gas discharge lamp, the processor 116 directs the switch 120 to open.
Since the first and second filaments 110 and 112 are no longer in series with the power source 106, a voltage difference develops between the first and second filaments 110 and 112. Due to the voltage difference, and the free electrons providing a low resistance path, an electrical arc is struck between the first and second filaments 110 and 112 ionizing the gas. The ionized gas forms a plasma that provides a current path between the first and second filaments 110 and 112 resulting in the emission of light waves. Accordingly, once the plasma is formed, the first and second filaments 110 and 112 are coupled in series with each other and the power source 106 via the plasma.
Optimizing the temperature at which a specific gas discharge light source 104 is transitioned from the preheat cycle to continued operation as a source of light can maximize the life of that particular gas discharge light source 104. In addition, the startup time of the gas discharge light source 104 can be optimized. Further, the reliability and repeatability of successfully striking an arc to light the gas discharge light source at the conclusion of the preheat cycle may be maximized. Since a hotter preheat tends to increase reliability and provide “instant” on capability, at the expense of longevity of the lamp, and a cooler preheat extends the life of the lamp, but tends to lower reliability of starting and increases startup time, there is a balance between increased longevity and reliability. A balance that enables optimization of the operation of the lamp can be achieved by customizing an arc temperature point achieved during the preheat cycle to be optimal for a particular individual gas discharge light source 104.
Optimizing the arc temperature point at which a specific gas discharge light source 104 is transitioned may be based on the measured and calculated specific rcold value and a “hot” filament resistance value (rhot) calculated by the processor 116. A calculated gas discharge light source specific “hot” filament resistance value (rhot) may be determined based on the calculated specific rcold value, and a characteristic ratio of rcold to rhot for a particular filament material included in the light source 104, and the particular type of gas discharge light source 104 coupled with the starter 100.
In the example of
As previously discussed, a gas discharge light source specific “cold” filament resistance (rcold) value is calculated based on the voltage and current when the gas discharge light source is initially energized and begins preheating. Based on the graph of
where the ratio rhot/cold is a lamp resistance ratio at a determined temperature that can be obtained from a graph, such as
Referring again to
The duration of the preheat cycle may be automatically adjusted by the processor 116. As previously discussed, calculated rhot target may be adjusted automatically by the processor 116 to adjust the preheat temperature if the calculated light source specific “hot” filament resistance (rhot) value is reached but the light source does not light when the switch 120 is opened. Specifically, the processor 116 may adjust the preheat time by automatically adjusting the lamp resistance ratio within a determined range. For example, where the range of the lamp resistance ratio where an arc can be struck for a particular gas discharge light source is between about 4.0 and about 6.5, the lamp resistance ratio of about 4.0 may be used initially to calculate the light source specific target “hot” filament resistance value (rhot). However, when the lamp fails to light, the processor may automatically use about 5.0 and then about 6.0, for example, as the lamp resistance ratio (if needed) to get the gas discharge light source 104 to strike an arc and light.
In addition to optimizing lamp life and optimizing startup time, calculation of lamp specific rhot and rcold values may also be used as a diagnostic tool. For example, if the calculated rcold value changes suddenly, or is outside a predetermined range based on material and/or manufacturing variables, the processor 116 may generate an alarm, or disable further starts of the gas discharge light source. Alternatively, or in addition, if the duration of the preheat cycle to reach the calculated light source specific target “hot” filament resistance (rhot) value is greater than a predetermined time, the processor 116 may alarm or disable further starts of the gas discharge light source 104.
In one example scenario, the processor 116 may determine the calculated lamp specific rcold value is outside the range and alarm that the lamp is damaged, or that the wrong lamp is installed. In another example scenario, such as in the case of gas discharge light source for use in a tanning bed, the processor 116 may calculate the lamp specific rcold value and then calculate the lamp specific rhot value. If the calculated lamp specific rhot value is outside a predetermined range, the processor 116 may leave the gas discharge light source in preheat mode until the filaments 110 and 112 in the light source 104 burn up, forcing replacement of weak bulbs in the tanning bed based on predetermined minimum required output of the bulbs.
Since the starter 100 may be automatically “tuned” for operation with any gas discharge light source 104 by calculating a light source specific rcold, the starter 100 may be used with any ballast 102 or light source 104. Accordingly, since no component matching is needed, the starter 100 may be a stand alone productized component, and/or may be productized as a component included in a light source and/or ballast. Also, the climate, such as temperature, within which the light source 104 is used can be automatically compensated for by the starter 100.
The power supply 304 may be a DC supply capable of converting alternating current (AC) to direct current (DC). Alternatively, the power supply 304 may be an AC supply, a power conditioner, an uninterruptable power source, a battery, a solar panel, and/or any other mechanism or device capable of supplying power to the starter 300. The power supply 304 may be regulated or unregulated, and may include an internal power source, such as a battery, a solar panel, a charging capacitor, etc. The power supply 304 may be coupled with a ground connection 306, and provide DC power to the processor 116 on a voltage supply line 308. The processor 116 may also be coupled with the ground connection 306.
The processor 116 includes a communication port 310 that enables communication with the computer 302. Communication may be serial and/or digital, and may occur via TCPIP, RS232, or any other form of communication format and/or protocol. Communication may be wireless and/or wireline, and may be over a dedicated communication path, or over a network. The communication port 310 may be used to communicate commands and/or data between the processor 116 and the computer 302.
In one example, the computer 302 may be used to download data to the processor 116 such as lamp resistance ratio vs. temperature graph data, a maximum preheat time, a range of a calculated lamp specific rcold value, or any other predetermined or determined values, etc, via the communication port 310. Alternatively, or in addition, the computer 302 may be used to capture and store measured values, operational parameters, or any other data uploaded from the processor 116 via the communication port 310. The computer 302 may also be configured to perform computer related functionality, such as, network access, application execution, data manipulation, etc., using a user interface that can includes a graphical user interface (GUI), keyboard, pointing selection device, etc. Accordingly, data transfer and storage, data analysis, data manipulation, etc. may be performed with the computer 302.
The processor 116 may execute instructions stored on a computer readable medium, as previously discussed, to receive and process input signals and generate and transmit output signals. The processor 116 includes a plurality of inputs and outputs (I/O) that may include digital signals and/or analog signals. The digital and analog signals may be voltage signals and/or current signals. In
The current input line 312 also may be coupled with the current sensor 118 via a current line 326, which is also coupled with the ground connection 306. The current line 326 includes a plurality of resistors 328 configured to scale an output signal of the current sensor 118. In
The first voltage input line 314 may be coupled with a plurality of scaling resistors 332 included in a ballast line 334. The ballast line 334 may be coupled with the ballast 102 and the ground connection 306. The scaling resistors 332 may scale a voltage of the ballast 102 to a range compatible with the first input voltage (V1) of the processor 116. Alternatively, the ballast voltage could be received directly by the processor 116, and the scaling resistors 332 may be omitted.
In
The second voltage input line 316 is coupled with a plurality of scaling resistors 342 included in a first filament voltage line 344. The first filament voltage line 344 is coupled with the ground connection 306 and a first filament pin 348 coupled with a first filament 110 included in the gas discharge light source 104. The first filament 110 is also coupled with the ground connection 306 via a second filament pin 350.
The third voltage input line 318 is coupled with a plurality of scaling resistors 352 included in a second filament voltage line 354. The second filament voltage line 354 is coupled with the ground connection 306 and a third filament pin 356. The third filament pin 356 is coupled with one end of a second filament 112 included in the gas discharge light source 104, and a fourth filament pin 358 is connected with the other end of the second filament 112. Thus, the voltage across the second filament 112 may be sensed via the third filament pin 356 and the fourth filament pin 358. The scaling resistors 352 may be omitted when the processor 116 is capable of directly receiving the voltage sensed at the third filament pin 356.
The third filament pin 356 is also coupled with the first filament pin 348 via the switch 120 and a current limiting resistor 360. Accordingly, when the switch 120 is closed, the first and second filaments 110 and 112 are coupled in series via the first and third filament pins 348 and 356, and the current is limited by the current limiting resistor 360. In other examples, current limiting is unnecessary and the current limiting resistor 360 may be omitted. The switch 120 is opened and closed via digital output signal (Out) generated by the processor 116 on the switch control line 134. The switch 120 is operated by the processor 116 to toggle between a preheat mode (closed) and an operation mode (open) as previously discussed.
The fourth voltage input line 320 is coupled with a plurality of scale resistors 362 included in a third filament voltage line 364. The third filament voltage line 364 is coupled with the ground connection 306, the current resistor 330, and the fourth filament pin 358. Accordingly, a portion of the third filament voltage line 364 provides voltage and current from the ballast 102 to the gas discharge light source 104. Thus, the scale resistors 362 provide scaling of the voltage provided to the gas discharge light source 104. Alternatively, the scale resistors 362 may be omitted and the voltage may be supplied directly to the processor 116.
As previously discussed, the second input voltage (V2) with respect to the ground connection 306 is representative of the voltage across the first filament 110. Using the input current (I1) and the voltage (V2) across the first filament 110, the processor 116 calculates the cold resistance of the first filament 110 (rcoldfil1) as:
at block 410. At block 412, the input current (I1) and the third and fourth input voltages (V3 and V4) are used by the processor 116 to calculate the cold resistance of the second filament 112 (rcoldfil2) as:
An average cold resistance (rcoldavg) or (rcold) for the specific gas discharge light source 104 may be determined by the processor 116 by:
at block 414. Alternatively, the cold resistance of the first filament 110 and the cold resistance of the second filament 112 may be used separately. At block 416, based on the calculated rcold average that is specific to the gas discharge light source 104, the processor 116 calculates a target rhot. The calculated target rhot is specific to the gas discharge light source 104, and may be determined from Equation 1 based on a determined preheat temperature and ratio characteristic information stored in memory, such as the example ratio characteristic information illustrated in
At block 420, the processor 116 samples the current (I1) and the second, third and fourth voltages (V2, V3 and V4), and may calculate an average measured filament resistance (rmeas) of the specific gas discharge light source 104. As previously discussed, the current and voltages may be sampled at a predetermined sample rate and integrated to obtain RMS values. Based on the calculated average measured filament resistance (rmeas), the processor 116 determines if the duration of the preheat cycle is complete at block 422. If the time for the preheat cycle is not complete, the processor 116 determines if the preheat time has exceeded the predetermined maximum preheat time at block 424. If the maximum preheat time has not been exceeded, the processor 116 returns to block 420 and repeats sampling, etc.
In another example, the processor 116 may samples the current (T1) and the second, third and fourth voltages (V2, V3 and V4), and calculate a filament resistance (rmeas) for each of the first and second filaments 110 and 112. In this example, the calculated filament resistances (rmeas) are compared to respective calculated target rhot values for each of the respective first and second filaments 110 and 112. The processor 116 may conclude the duration of the preheat time when the calculated filament resistances (rmeas) of both the first and second filaments 110 and 112 exceed respective calculated target rhot values. Alternatively, the processor 116 may conclude the duration of the preheat time when either one of the calculated filament resistances (rmeas) exceed the respective calculated target rhot values.
If the predetermined maximum preheat time has been exceeded at block 424, the processor 116 may generate an alarm at block 426. Alternatively, or in addition, the processor 116 may disable the starter 300, set a flag to disable additional starts, and/or continue preheating until the filaments 110 and 112 are melted as previously discussed. In another example, the processor 116 may open the switch 120 to conclude the preheat cycle when the predetermined maximum preheat time is reached in an attempt to strike the arc even if the calculated target rhot has not yet been reached. Accordingly, the processor 116 in this example will allow the duration of the preheat cycle to continue until, either the average measured filament resistance (rmeas) reaches the gas discharge light source specific target rhot as calculated by the processor 116, or the duration of the preheat cycle exceeds a determined time, whichever occurs first. If the preheat cycle exceeds the determined time, and the arc is not successfully struck when the preheat cycle is concluded, the processor 116 may recalculate the rhot target with a higher desired strike temperature, as previously discussed, and return to block 420 to commence with the preheat cycle.
If, at block 422, the determined preheat time has been reached (rmeas is substantially the same as the calculated target rhot), the processor 116 directs the switch 120 to open at block 430. At block 432, the processor 116 samples the voltage and current inputs while the switch 120 is open. At block 434, the processor 116 determines if the arc has been struck based on the current and voltage samples. If the arc has been struck, the processor 116 continues sampling and collecting operating data at block 436. If the arc was not struck, the processor 116 determines if a maximum rhot value has been reached at block 438. The maximum rhot value may be calculated from Equation 1 based on a lamp resistance ratio determined with the maximum arc strike point temperature. If the maximum rhot value has been reached, the processor 116 generates an alarm at block 440. Alternatively, or in addition, the processor 116 also may disable the starter 300, set a flag to disable additional starts, or continue preheating until the filaments 110 and 112 are melted, as previously discussed. If at block 438, it is determined by the processor 116 that the maximum rhot has not yet been reached, the processor 116 calculates a new target rhot at block 442 using a higher arc strike point temperature (lamp resistance ratio), and returns to block 418 to store the new target rhot, and again attempt to preheat the gas discharge light source 104.
The previously described starter is capable of automatically customizing the duration of the preheat cycle of a gas discharge light source to which the starter is coupled. Following-entry of information identifying the type of gas discharge light source, and the type of filament thereof the starter may select a corresponding ratio resistance vs. temperature curve (characteristic ratio, information) from memory. Alternatively, the corresponding ratio resistance vs. temperature curve (characteristic ratio information) may be downloaded to the starter. In addition, a maximum preheat time may be entered and stored in memory, or downloaded to the starter.
Based on a measure voltage and current at the beginning of each preheat cycle, a gas discharge light source specific “cold” resistance value (rcold) may be calculated by the starter and used to determine a duration of the preheat cycle. The duration of the preheat cycle is automatically customized by the starter for the particular gas discharge light source coupled thereto. Thus, as the gas discharge light source changes over time, the starter can automatically adjust the duration of the preheat cycle based on the re-calculated rcold value. In addition, the duration of the preheat cycle is automatically optimized to provide reliability and longevity of the gas discharge light source. The starter may also perform a diagnostic function by confirming that the calculated rcold value is within an acceptable range, monitoring the duration of the preheat cycle, and determining whether the arc is successfully struck. Also, the starter is capable of multiple attempts to strike the arc with automatically adjusted corresponding durations of the preheat cycle when the arc is not successfully struck.
While various embodiments of the invention have been described, it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible within the scope of the invention. Accordingly, the invention is not to be restricted except in light of the attached claims and their equivalents.