1. A fault is tripped on the controller by the fireplace actions.
2. The controller checks the telephone line to see if it is being used, and if so waits a set amount of time after it is not used before dialing.
3. If/when the line is not in use, the controller performs any action necessary to reach an outside line.
4. The controller then dials the designated phone number to reach the remotely located computer system.
5. The receiving computer system picks up and waits for ready to send code from the fireplace controller.
6. The receiving computer system hears a “ready to send” code and transmits “ready to receive” code.
7. After hearing the ready to receive code, the fireplace controller sends the serial number with a coded signal indicating the fault code and other information about the fireplace.
8. When the transmission of information is completed, the fireplace controller will then wait until it hears the received successfully code from the receiving computer system. If the sequence makes it to this point but the fireplace controller does not hear the received successfully code, it must wait a predetermined time period and continue the sequence until the information is received successfully at the remote location.
9. After the fireplace controller receives the proper indication that the information has been transmitted, the lines on both ends are hung up.
10. The receiving computer system logs the information on, for example, a Microsoft Excel spreadsheet for viewing at the remote location.
11. The remote located computer system can automatically generate responsive signals to be sent to the fireplace controller, maintenance personnel, or the fireplace owner via, for example, a telephone transmission, an e-mail message, etc.

Table 1 (see below) lists some possible detectable faults along with their intended purpose, whether or not the fault should result in a forced shut down of a system, whether or not new sensors are needed over time, and an example hardware for use in detecting the fault. These example faults can be determined using one or more of the example sensors described with reference toFIG. 5.

TABLE I


Possible Detectable Faults

		Forced	New Sensor
Fault	Purpose	Shut down	Needed	Detection

Main Flame	Safety	yes	yes	UV sensor or 2-3 probes
Detection				similar to pilot circuit
Malfunctioning	Safety	yes	no	Circuit using FETs
Pilot Circuit				connected to IPI sensing
				probe - white wire
Ignition Time Out	Safety	yes	no	Inductive switch on spark
				line - orange wire
Soot Detection	Appearance	no	yes	Two leads in a finger
				weaved layout to detect
				voltage transferred
				between them
Hour Meter	Maintenance	no	no	Uses clock inside
				microcontroller and
				fireplace switch - brown
				wire
Overheating	Safety	yes	yes	Thermistor used to detect
				heat outside of box
Tamper Detection	Safety	no	no	Watch lines and sensors
				already connected for
				unexpected activity
Non-Use Hour	Maintenance	no	no	Separate internal counter
Meter				to count hours between
				uses
Gas Detection	Safety	yes	yes	Sensor on bottom of
				fireplace (more useful for
				LP but maybe not
				practical)

FIGS. 8 and 9 illustrate some example method steps related to monitoring and controlling operation of a fireplace.FIG. 8 illustrates the steps of monitoring with sensors the condition of a burner flame, a pilot flame, and a spark generation in the fireplace. The method also includes communicating information about the monitored conditions to remotely located computer and shutting off a gas supply to the fireplace when a predetermined monitored condition exists. The method still further includes generating control signals and alarms/reports with the remotely located computer system.

FIG. 9 relates to a method that includes providing a heating appliance having a combustion chamber, a burner, a pilot flame system, an ignition system, a valve, a controller, and a plurality of sensors. The method also includes a status of the burner, the pilot flame system, the ignition system, and the valve with the plurality of sensors. The method also includes controlling the burner, the pilot flame system, the ignition system and the valve in response to the monitored status, and communicating between the controller and a remotely located computer system in response to a predetermined monitored status.

Functional Options

The monitoring and control system described herein can provide a more definite safety/worry free fireplace operation. The following potential options, some of which are discussed above, can further enhance the overall functionality of the system.

1. Set hour Service Call. This feature could provide a service call when the fireplace reaches a certain number of hours of operation logged, it makes a call to get a “check-up.”
2. Wireless Phone Jack. This feature could be provided in order to make retrofitting easier, a wireless system could be used either to modulate the signal over the AC power lines, or to transmit the signal via radio frequencies (RF) to a module that is located at a phone jack.
3. Glass Temperature Sensor. This feature could be used to detect whether there is a higher temperature on the glass than it's rating.
4. Gas Line Pressure Sensor. This feature could be used to ensure that the gas line has a high enough pressure for the fireplace to operate properly.
5. Multiple Call/Contact Option. This feature could be used to place multiple calls concurrently (e.g., a dealer/manufacturer, the fireplace owner, or maintenance personnel). As an added feature, additional numbers or contact instructions could be added (cell number, email, text message, etc.).
6. Combustible Gas Detector. This feature could be used to detect no gas before sparking on a fireplace.
7. Tamper Detection. This feature could provide additional sensors or switches to indicate whether the glass has been off the fireplace, phone line has been disconnected, or any other areas to watch that would indicate the system has been changed by someone who does not have the ability to reset the history.

The system may include a connector for future “add-on sensors” that can go to different ports of the microcontroller such as I/O's, A/D or D/A converter lines. The system may also include the capability (e.g., via a serial port) for a service technician to retrieve the history of the fireplaces actions and/or problems from the microcontroller or communication transmission. Such capability may also include the possibility for future upgrades in code and a possibility of talking with another microcontroller that could be in an “added-on” device in the future.

The system may use LEDs as status indicators on the fireplace, at other locations in close proximity to the fireplace, or at the remote computer location. These visual indicators may be turned off or removed according to user preferences.

The examples provided above with reference to the attached Figures focus on gas burning decorative heating appliances such as fireplaces, stove, and fireplace inserts. The systems and methods described above could be modified to provide the same or similar functions for other types of decorative heating appliances such as, for example, electric, wood burner, and pellet fireplaces, stove and fireplace inserts. While such alternative heating appliances may not include a valve or the type of ignition system required for ignition of a gaseous fuel, such alternative heating appliances may include different types of ignition systems and heat sources that can be monitored and controlled with the assistance of sensors, as well as blowers, light fixtures, air filters, scent generating devices and other features that can be monitored and controlled.

In other example embodiments, the system may include sensors that monitor the fuel supply associated with the decorative heating appliance. For example, a sensor or other monitoring device may be used to monitor a pellet supply level for a pellet stove or fireplace, or a liquid propane (LP) supply level for a LP gas fireplace.

The present invention should not be considered limited to the particular examples or materials described above, but rather should be understood to cover all aspects of the invention as fairly set out in the attached claims. Various modifications, equivalent processes, as well as numerous structures to which the present invention may be applicable will be readily apparent to those of skill in the art to which the present invention is directed upon review of the instant specification.