The present invention relates, in general, to electric space heaters, and, specifically, to portable electric heaters.
In the past, electric heaters were permanently installed into homes and businesses, by permanently attaching the heater to a baseboard region of a wall, and permanently wiring the heater into the home or business' electrical system. More recently, portable electric heaters, such as baseboard type heaters, have become popular. Such portable systems are used to either warm unheated spaces, or to augment the heating of spaces which are insufficiently heated by existing, built-in heating systems. Such portable electric baseboard heaters, while elongated, are typically relatively lightweight and portable. They typically include a conventional power cord and 3-prong electrical plug, for attachment to conventional AC outlets. Such heaters are typically designed to warm relatively small interior regions, on the order of a few hundred square feet in size or smaller.
The present invention comprises a low profile, portable electric heater apparatus. The heating apparatus has a heating element having a longitudinal axis, at least one thermistor, a reference resistor a capacitor; and a microcontroller. The microcontroller has port pins coupled to the at least one thermistor and the reference resistor. The microcontroller is capable of switching the direction of the port pins between input and output to alternatively and selectively place the reference resistor and the at least one thermistor in series with the capacitor to form two separate RC timing circuits.
In a preferred embodiment, the portable electric heater apparatus further includes an ambient temperature sensor, and the port pins are coupled to the at least one thermistor, the reference resistor, and the ambient temperature sensor. The microcontroller is capable of switching the direction of the port pins between input and output to alternatively and selectively place the reference resistor, the at least one thermistor, and the ambient temperature sensor in series with the capacitor to form three separate RC timing circuits.
Moreover, in a preferred embodiment, the at least one thermistor comprises a plurality of thermistors spaced at substantially even intervals along a line substantially parallel to the longitudinal axis of the heating element. Moreover, the at least one thermistor preferably comprises a plurality of thermistors, the plurality of thermistors being grouped into at least two banks, each bank having at least two thermistors wired in parallel. The microcontroller is capable of switching the direction of the port pins between input and output to selectively place each bank of thermistors in series with the capacitor to form two separate RC timing circuits.
In a preferred embodiment, the present portable electric heating apparatus has a housing having a substantially upright orientation, a heating element disposed within the housing, a power source coupled to the heating element; and at least one tip-over switch serving to disconnect the heating element from the power source when the housing is not in the substantially upright orientation. Moreover, in a preferred embodiment, the at least one tip-over switch comprises at least two tip-over switches, including a first tip-over switch and a second tip-over switch. The apparatus further includes a relay, at least one temperature sensor, and a microcontroller.
The relay has a closed and a normally open position, and is coupled to the heating element and the power source, such that the heating element is connected to the power source when the relay is in the closed position and is disconnected from the power source when the relay is in the normally open position. An output pin of the microcontroller switches the relay between the closed and normally open positions, through an intermediate transistor.
The first tip-over switch is disposed between the microcontroller and the relay and disconnects the microprocessor from the relay when the housing is not in the substantially upright orientation and, in turn, switches the relay to the normally open position. Moreover, the second tip-over switch is disposed between the microcontroller and the at least one temperature sensor, permitting the microprocessor to sense an abnormal condition when attempting to read the temperature sensor when the housing is not in the substantially upright orientation.
The present invention also comprises a method of sensing an overheating condition in a portable electric heater. The portable electric heater has a heating element, a reference resistor having a known resistance of R_Reference, at least one thermistor disposed proximate the heating element, and a capacitor. A reference resistor is placed in series with the capacitor to form a first RC timing circuit. An amount of time TIMER_Reference that it takes for a point between the reference resistor and the capacitor to reach a predetermined threshold voltage is determined. The at least one thermistor is placed in series with the capacitor to form a second RC timing circuit. An amount of time TIMER_BANK#1 that it takes for a point between the at least one thermistor and the capacitor to reach a predetermined threshold voltage is determined. A resistance value R_BANK#1 corresponding to the at least one thermistor is determined using the following equation:
Next, a table lookup of a temperature value corresponding to R_BANK#1 is performed. A test, or comparison to determine if the temperature value is indicative of an overheating condition is then performed.
In a preferred embodiment, the step of determining an amount of time TIMER_Bank#1 that it takes for a point between the at least one thermistor and the capacitor to reach a predetermined threshold voltage comprises is performed by a) determining an amount of time TIMER_Bank#1_Sample that it takes for a point between the at least one thermistor and the capacitor to reach a predetermined threshold voltage; b) storing TIMER_Bank#1_Sample in memory; c) discharging the capacitor; repeating steps a through c until a plurality of TIMER_Bank#1_Sample values are stored in memory; and then averaging at least two of the TIMER_Bank#1_Sample values to obtain the TIMER_Bank#1 value. Moreover, the step of averaging at least two of the TIMER_Bank#1_Sample values to obtain the TIMER_Bank#1 value comprises the sub-steps of discarding a TIMER_Bank#1_Sample value having a maximum value; discarding a TIMER_Bank#1_Sample value having a minimum value; and averaging the remaining TIMER_Bank#1_Sample values stored in memory. In a preferred embodiment, a total of eighteen TIMER_Bank#1_Sample values are stored in memory, and a total of sixteen TIMER_Bank#1_Sample values are averaged.
Moreover, the step of determining an amount of time TIMER_Reference that it takes for a point between the reference resistor and the capacitor to reach a predetermined threshold voltage preferably comprises the sub-steps of: a) determining an amount of time TIMER_Reference_Sample that it takes for a point between the reference resistor and the capacitor to reach a predetermined threshold voltage; b) storing TIMER_Reference_Sample in memory; c) discharging the capacitor; repeating steps a through c until a plurality of TIMER_Reference_Sample values are stored in memory; and averaging the values of at least two of the TIMER_Reference_Sample values to obtain the TIMER_Reference value. The step of averaging at least two of the TIMER_Reference_Sample values to obtain the TIMER_Reference value preferably comprises the sub-steps of: discarding a TIMER_Reference_Sample value having a maximum value; discarding a TIMER_Reference_Sample value having a minimum value; and averaging the remaining TIMER_Reference_Sample values stored in memory. A total of eighteen TIMER_Reference_Sample values are preferably stored in memory, and a total of sixteen TIMER_Reference_Sample values are preferably averaged.
The present low profile heater apparatus 10 is shown in
Within housing 11, an elongated electric heating element 36 extends along a longitudinal axis of the housing. In a preferred embodiment, to facilitate the distribution of radiant heat energy, heating element 36 includes four of sets of blades, or fins, radiating from a longitudinal axis of the heating element, at ninety degree angles, relative to each other, and being substantially “X”-shaped in cross section. Heating element 36 is held in place within housing 11 by two opposing insulating plates 38, 39, each of which has an aperture accepting an opposing end of heating element 36. Each insulation plate is, in turn, held within cooperating recesses in the interior surfaces of the end caps. A stainless steel spring 37 further secures heating element 36 between insulating plates 38 and 39.
An elongated temperature limit control printed circuit board (“PCB”) 40 is also disposed within housing 11, parallel to the longitudinal axis of the heating element and in close proximity to heating element 36 and along a significant portion of the length of heating element 36. A plurality of affixation plates 41 secure PCB 40 within housing 11 proximate heating element 36.
A mica plate 92 is disposed within housing 11 and held in place between end cap halves 15 and 16 of end cap 14. Mica plate 92 electrically insulates the control components of the present low profile heater apparatus, contained within end cap 14, from insulation plate 39.
As shown in
A wiring diagram of the control components is shown in
A schematic diagram of the present low profile heater apparatus is shown in
Microcontroller 60 controls the overall operation of the present heater apparatus. In a preferred embodiment, microcontroller 60 comprises an EM78P468NH 8-bit microcontroller, manufactured by Elan Microelectronics Corp. of Hsinchu, Taiwan R.O.C. Microcontroller 60 preferably includes an 8-bit Reduced Instruction Set (“RISC”) processor, with on-chip watchdog timer, data memory, program memory, programmable real time clock counter, bi-directional data, tri-state input/output (“I/O”) ports, and LCD drivers. A precision resistor 91 is coupled to XIN pin 61 of the microcontroller and cooperates with a temperature compensating capacitor within microcontroller 60 to provide a time base, or clock for operation of the microcontroller.
A power-on reset circuit 76, with residual voltage protection, is coupled to external reset pin 65 of the microcontroller. A plurality of capacitors are coupled to the LCD bias voltage pins 66 of the microcontroller. LCD control output pins 67 of microcontroller 60 are coupled directly to LCD display 33. Power-on Light Emitting Diode (“LED”) 64 is coupled to I/O port pin 73 of the microcontroller, and is accordingly under software control. Transistor driver 77 and LCD backlight 26 are coupled to I/O port pin 74 of the microcontroller, enabling microcontroller 60 to turn the backlight on and off under software control. In a preferred embodiment, microcontroller 60 turns off the LCD backlight after a predetermined delay, such as eight seconds, following each user input.
Heating element control I/O port pin 75 permits microcontroller 60 to turn heating element 36 on and off under software control, by switching the digital signal output by this pin between high and low logic levels. First tip-over switch 47 is wired between heating element control I/O port pin 75 and the base of transistor driver 78. The collector of transistor driver 78 is, in turn, coupled to the coil of normally open relay 79. Whenever first tip-over switch 47 is electrically closed, microcontroller 60, via heating element control I/O port pin 75, is able to switch transistor 78 to, in turn, energize the coil of relay 79. This, in turn, closes relay 79, and completes a circuit between AC line conductor 42, heating element 36, and AC neutral conductor 43. This, in turn, causes heating element 36 to produce and radiate heat.
Control button assembly 28 (
Temperature limit control PCB 40 (
As shown in
Through the use of a plurality of thermistors, regularly spaced along the heating element and in close proximity thereto, an over-temperature condition occurring substantially anywhere along the length of the heating element will be sensed by at least one of the thermistors, resulting in a prompt system shutdown of the present low profile heater apparatus.
The organization of the six thermistors into two banks, relative to microcontroller 60, has the advantage of permitting all six thermistors to be sensed, without having to individually couple each transistor input and output to a dedicated I/O pin of the microcontroller. This reduces the overall I/O pin requirement of the microcontroller, or the number of pins which must be dedicated for thermistor sampling. Accordingly, this leaves additional I/O pins available for other functions. Moreover, the use of banks of thermistors permits multiple thermistors to be sampled simultaneously by the microcontroller, speeding the sampling cycle for the total number of thermistors.
The use of two separate tip-over switches, at two different locations in the overall circuitry, is considered to provide an added level of safety. As shown in
Reference resistor 89, which preferably comprises a 51K ohm, 1% precision resistor, is coupled between reference resistor control I/O port pin 70 of microcontroller and capacitor 90. Ambient temperature sensing thermistor 88 is coupled between ambient thermistor control I/O port pin 71 (through an intermediate resistor) and capacitor 90. Ambient temperature sensing thermistor 88 preferably comprises an epoxy sealed NTC thermistor rated at 50K ohm+/−3%, with a material coefficient B value of 3590K+/−1%.
By controlling the direction and state of I/O port pins 70, 71, 68 and 69, microcontroller 60 can separately place capacitor 80 in series with: reference resistor 89, ambient temperature sensing thermistor 88, second thermistor bank 84, and first thermistor bank 80, respectively.
First tip-over switch 47 and second tip-over switch 59 may be of the ball-rolling or mercury (or other conductive fluid-containing) variety, and are both oriented on printed circuit boards within the present apparatus such that they are electrically closed whenever the apparatus is in its proper, vertical orientation, resting upon all four rubber feet. Whenever the apparatus is tipped on its side, is upside down, or is otherwise oriented other than substantially vertical, tip-over switches 47 and 59 transition to an electrically open state, and remain so until proper orientation of the apparatus is restored.
As shown in
Pressing Mode button 96 causes the apparatus to switch between temperature setting and timer modes. When in timer mode, as shown in
As shown in
A flowchart of certain operations performed by the circuitry and microcontroller of the present heater apparatus is shown in
Next, at step 203 of
Next, at step 204 of
Next, at step 205 of
Where R_Reference is the known resistance value of reference resistor 89, TIMER_Reference is the mean, or average of the sixteen samples of capacitor 90 charging times with the reference resistor as discussed above, and TIMER_Bank#1 is the mean time of sixteen samples of capacitor 90 charging times with the first bank of thermistors, as discussed above. Next, the calculated resistance of R_Bank#1 is used as an index into a predetermined lookup table stored within microcontroller 60, with each potential value of R_Bank#1 having a corresponding temperature value. The lookup table entry corresponding to a resistance of R_Bank#1 is a temperature value, named TEMP_Bank#1.
Referring to
Otherwise, transition is taken to step 207, and a test is performed, to determine if TEMP_Bank#1 is less than 113 degrees centigrade and greater than or equal to 107 degrees centigrade. If so, the apparatus is considered to be in a high temperature condition, though not so high as to require a complete system shutdown. Rather, transition is taken to step 221. In step 221, referring to
Otherwise, if TEMP_Bank#1 does not indicate either an excessive or high temperature condition, transition is taken to step 208, where the system continues its normal work pattern. Next, transition is taken to step 209.
Next, at step 209 of
Next, at step 210 of
Where R_Reference is the known resistance value of reference resistor 89, TIMER_Reference is the mean, or average of the sixteen samples of capacitor 90 charging times with the reference resistor as discussed above, and TIMER_Bank#2 is the mean time of sixteen samples of capacitor 90 charging times with the second bank of thermistors, as discussed above. Next, the calculated resistance of R_Bank#2 is used as an index into a predetermined lookup table stored within microcontroller 60, with each potential value of R_Bank#2 having a corresponding temperature value. The lookup table entry corresponding to a resistance of R_Bank#2 is a temperature value, named TEMP_Bank#2.
Referring to
Otherwise, transition is taken to step 212, and a test is performed, to determine if TEMP_Bank#2 is less than 113 degrees centigrade and greater than or equal to 107 degrees centigrade. If so, the apparatus is considered to be in a high temperature condition, though not so high as to require a complete system shutdown. Rather, transition is taken to step 224. In step 224, referring to
Otherwise, if TEMP_Bank#2 does not indicate either an excessive or high temperature condition, transition is taken to step 213, where the system continues its normal work pattern. Next, transition is taken to step 214.
Next, at step 214 of
Next, at step 215 of
Where R_Reference is the known resistance value of reference resistor 89, TIMER_Reference is the mean time of sixteen samples of capacitor 90 charging times with the reference resistor as discussed above, and TIMER_Ambient is the mean time of sixteen samples of capacitor 90 charging times with the second bank of thermistors, as discussed above. Next, the calculated resistance of R_Ambient is used as an index into a predetermined lookup table stored within microcontroller 60, with each potential value of R_Ambient having a corresponding temperature value. The lookup table entry corresponding to a resistance of R_Ambient is a temperature value, named TEMP_Ambient.
Next, at step 216, a comparison is made, to determine if TEMP_Ambient is greater than the target temperature setting (either the default target temperature setting of 75 degrees Fahrenheit or another target temperature setting selected by the user using the control buttons in temperature setting mode). If so, transition is taken to step 226. Otherwise, transition is taken to step 217.
In step 226, referring to
In step 217, a comparison is made to determine if TEMP_Ambient is equal to the target temperature setting. If so, transition is taken to step 227. Otherwise, transition is taken to step 218.
In step 227, the current output state of I/O pin 75, controlling the state of transistor 78 and, in turn, relay 79 and heating element 36, is maintained (i.e., left in its current state). Transition is then taken to step 203.
In step 218, a test is made to determine if the sensed ambient temperature has only recently fallen below the target level. If so, transition is taken to step 227. Otherwise, transition is taken to step 219.
In step 219, the sensed ambient temperature is below the target temperature, and the system is seeking to raise temperature levels. In step 219, referring to
The foregoing steps are repeatedly cycled, towards achieving or maintaining a desired temperature, absent an excessively high or high temperature condition.
It will be understood that modifications and variations may be effected without departing from the spirit and scope of the present invention. It will be appreciated that the present disclosure is intended as an exemplification of the invention and is not intended to limit the invention to the specific embodiment illustrated and described. The disclosure is intended to cover, by the appended claims, all such modifications as fall within the scope of the claims.
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