FR2902535A1 - Operating parameters communication device for e.g. gas-fired boiler, has communication unit e.g. global positioning system modem, sending operating ratio at end of predetermined duration, and comprising part of content of memory - Google Patents

Abstract

The device has a nanoserver (5) programmed for reading operating parameters of an individual or collective boiler (1) with a predetermined increment. A memory (6) stores statistics, averages, sums and/or percentages of values of the parameters, during a predetermined duration. Reading and storage of new average values at a last increment leads to deletion of the statistics, averages, sums and/or percentages. A communication unit (9) e.g. global positioning system (GPS) modem, sends an operating ratio at an end of the duration, and comprises a part of a content of the memory.

Description

1 Statistical Memory Communication Device for Boiler

individual or collective

  The present invention generally relates to a communication device for individual or collective boiler comprising an electrical panel with a connector for enabling instantaneous reading of the operating parameters of said boiler for communication to the supplier and vice versa. As part of the heating industry, especially boilers, particularly gas, it is often common, even necessary, to be able to consult the operating parameters of the boiler, first to ensure the proper functioning of the boiler. boiler and the effects of wear and in a second time to establish a diagnosis of the boiler in case of malfunction and failure.

  This operation can be done in several ways. The first consists of sending a heating technician on site who plugs a reading device directly onto the electrical panel of the boiler so as to have access to the operating parameters. This operation is extremely cumbersome because it requires disturbing the user at home and monopolizing a technician for each boiler to study. It is obvious that this operation can not be implemented in the context of monitoring the operation of the boiler over its lifetime. In addition, in the event of a boiler failure, the user must inform the manufacturer and he must send a maintenance technician on site who has no prior information on the causes of the breakdown or malfunction. must therefore move with all the necessary equipment for all possible failures. In order to minimize these disadvantages, in particular to have an idea of the failure before any displacement, solutions have been proposed to implement devices to make the boilers communicating with the supplier or manufacturer and sometimes in both directions. In general, these devices only provide the manufacturer with the only error code for the boiler. At best, they can only provide information on the state of the boiler at the very moment of the failure, the appearance of an error code 2 triggering the reading of the operating parameters of the boiler. However, since the boiler is out of order, the parameters only represent the current state of the boiler. At most, the information contained in the transmitted error code makes it possible to limit the options as to the cause of the failure and thus limit the equipment to be carried away for troubleshooting or sometimes to give the user the possibilities to troubleshoot on his own. even his boiler. Nevertheless, the causes of the failure remain unclear because of the limited information provided to the manufacturer and the maintenance department. Under no circumstances can these devices make it possible to establish a prior diagnosis and longitudinal monitoring of the boiler, in particular by regularly checking the evolution of the operating parameters of the boiler, throughout its implementation, in order to Preventive power to identify a beginning of malfunction or a sign of fatigue of the boiler that could allow either to intervene before a failure that could be unpleasant for the user, or in case of failure to know beforehand failing organ and therefore minimize the troubleshooting hardware to ship and the diagnostic troubleshooting time. The inventors have therefore developed what is the object of the invention a communication device for individual or collective boiler comprising an electrical panel with connections to allow instantaneous reading of the operating parameters of said boiler for communication to the supplier and vice versa which overcomes all of these disadvantages, including having a preventive overview of boiler operating conditions and causes of malfunctions and thus provide optimized and more efficient troubleshooting solutions before The device according to the invention is characterized in that it comprises a nano-server programmed for and dedicated to the reading of said operating parameters of said boiler according to a determined increment, a memory , for storage for a fixed period of time, statistics, averages, som mes and / or percentages of the values of said operating parameters recalculated by the nano-server at each increment, reading and storing the new average values at said last increment causing the crushing or erasure of statistics, averages, sums and / or percentages 3 previously stored, and communication means for enabling the sending of an operating report at the end of the determined duration comprising all or part of the contents of the memory. This characteristic will also make it possible, in a preventive framework, to establish boiler operating statistics and thus to be able to predict future failures, in particular when an operating parameter shows that the boiler is clearly showing signs of aging. It will then be possible to intervene before the boiler stops working and thus avoid inconvenience to the user or in extreme cases a risk of avoidable danger. In the event of a confirmed failure of the boiler, this longitudinal monitoring of the boiler's operation will enable the supplier or the manufacturer to know in advance which part of the boiler has shown signs of failure or aging. Thus, it will be possible to communicate this information to the technician maintenance and troubleshooting technician so as to help in the diagnosis of the failure and therefore in the choice of equipment required for troubleshooting. Preferably, said increment has a value between 200 milliseconds and 2 seconds inclusive.

  Preferably, said determined duration has a value of one week. More preferably still, the operating parameters are chosen from the time under voltage, the burner operating time, the number of ignition attempts, the temperature and the evolution of the ionization current.

  Preferably, according to certain types of boilers, said connectivity for reading said parameters is a bus 12C arranged on the electric board of the boiler, or a RS232 serial link, or even an EMS bus. Advantageously, the general power supply of said devices is realized on the low voltage supply of the boiler. Depending on the boiler marks, the value of said voltage may be between 5 volts and 24 volts, terminals included. Indeed, certain types of boilers include, for example, a 24 volt power supply on which it is possible to connect and thus avoid any additional connection or any installation of battery which would be an additional constraint of congestion. However, if the boiler is equipped with a power supply with another type of voltage, it will be possible to adapt the device according to the invention to the available source of electricity. Advantageously, the device according to the invention may furthermore comprise a rotating buffer memory for storing the values of said operating parameters for a determined lapse of time of several increments, reading and storing the values of the last increment causing the erasure or erasure. overwriting the first stored values when said memory is full to enable the sending, in case of detection of a boiler failure, a failure report comprising all or part of the contents of the buffer. Thus, when an error code read and detected by the nanoserver appears, the information and in particular the error code and the operating parameters of the boiler stored during the determined period of time are transmitted to the supplier. . The analysis of this information and in particular the evolution of the operating parameters during the period of time determined by the transmitted error code then allows an accurate diagnosis of the fault and its cause.

  This useful information must therefore be stored in another memory complementary to the first and ideally configured as a rotating buffer. In this context, it can be provided that the determined period of time has a value between 10 seconds and 30 seconds inclusive.

  In particular, said communication means of the device according to the invention may be provided to receive remote commands analyzed and interpreted by the nano-server to be sent to said boiler. More particularly in this context the remote controls can be a request for transmission of the operating report, a request for one-off status transmission and / or troubleshooting commands. Indeed, it is expected that the device according to the invention will be able to communicate in both directions from the boiler to the supplier and vice versa. It will then be possible to send commands remotely by the communication means of the device to the nano-server so as to give orders from outside. In particular, it will thus be possible to request the device to send the operating report in advance. Preferably, said communication means are a modem. This particular characteristic will furthermore make it possible to use the telephone network for the communication and sending of reports and / or point states generated by the devices according to the invention. Optimally, said modem that equips the devices according to the invention is a GSM modem.

  In this context, we will use mobile phone technology for communication and sending reports and / or ad-hoc reports. In this context, the device according to the invention may also include an integrated GSM antenna or deported in the case where the boiler they equip is located at a place where the GSM network is weak or nonexistent.

  Still in this context, said modem is intended to send the operating reports, failure and / or the point states of the boiler and / or receive the remote commands by SMS. Preferably in this context, the device of the invention may further include a SIM card dedicated to sending SMS and associated with a mobile phone number and a mobile network. Still in this context, said operating reports are coded on 2 SMS. In addition, the point states are coded on 1 SMS. Finally, said failure reports are coded on 3 SMS. Once the SMS messages are sent, a telephony operator receives them and concatenates them in the form of text files. The text files can then, in particular for the failure reports and the one-off statuses of the boiler, be sent to the supplier or the manufacturer by mail via the Internet network and decoded using appropriate decryption software 30 so as to generate a fault report or a one-time report that can be displayed on a computer screen. Moreover, and especially for the weekly operation reports, the text files can be sent by the telephony operator to the supplier or the manufacturer by FTP server. These so-called files will feed a database of statistics. The invention will be better understood on reading the detailed description given below with reference to the drawing in which: - the single figure shows a device according to the invention for a boiler and having a GSM modem. In the drawing, there is shown a boiler), for example individual, with its electrical panel 2. This electrical panel comprises 2 comprises a connector 3, such as for example a bus I2C, through which are accessible is in instantaneous reading the operating parameters of said boiler 1. Through this bus 12C and through the 24-volt power supply 4 available on the electrical panel, a nano-server 5 is connected to the electrical panel 2.

  This nano-server 5 is programmed and dedicated to reading said operating parameters of the boiler 1 according to a determined increment. These parameters are generally accessible in instantaneous reading, for example according to the boiler model equipped with the device according to the invention, via the bus 12C of the electrical panel.

  In general, it is decided to program the nano-server so that a reading is performed in an increment of 250 milliseconds. From these values, the nano-server performs the calculation of statistics, averages, sums and / or percentages thereof and stores the result in a memory 6. This memory is fully managed and controlled by the nano-server.

  At each reading, every 250 milliseconds, the statistics (in the broadest mathematical sense) of each value of each parameter are recalculated. The new calculated statistics are then stored in this memory either by erasing or overwriting the values obtained at the previous increment. These average values are intended to be stored for a fixed period, for example a week. An additional rotating buffer memory 7, or buffer, is also available in the device, which will be used to store the raw results 7 of readings of the values of the operating parameters for a given period of time. It will be effective to keep the values of the last 10 seconds. Once the memory 7 is full, the next reading at the next increment is stored in the buffer memory 7 after erasing the values of the first reading or by overwriting them. The device finally comprises a GSM modem 9 for communication by the mobile telephone network. This modem is equipped with a SIM card dedicated to sending SMS and associated with a mobile phone number, unique for 10 each boiler concerned, and a mobile phone network. The modem is connected to the nano-server via a connection 8 and it is expected to add an integrated GSM antenna 10 and can be deported if necessary. Each week, the nano-server 5 is programmed to send by its modem 9 and the GSM network which is attached thereto an operating report containing the statistics of all the operating parameters of the boiler during the past week. These values are usually encoded in binary or hexadecimal. One or more SMSs, 2 in the case of an operating report, including the parameters and the statistical values, are then generated by the nano-server and are sent via the modem to the maintenance department of the provider. The SMS are concatenated by a telephony operator to form a single text file sent to the supplier or the manufacturer by FTP server. These so-called files will feed a database of statistics. This text file will contain all the values of the memory of the nano-server. Especially designed decryption software will then allow the text file to reproduce all the quantities sent and generate a report of operation displayable on a computer screen and directly usable by the maintenance technician to analyze the evolution of the operation of Boiler. The use of the rotating buffer memory 7 is identical. The nanoserver is then programmed to read the operating parameters 8 of the boiler 1. It can, in case of failure, encounter an error code. In this case, the nano-server sends the contents of its buffer memory in whole or in part according to predetermined times, for example the values of the operating parameters at 10, 8, 6, 4, 3, 2 and 1 seconds.

  In the same way, 3 SMS are generated by the nano-server to send via the modem to the service provider of the provider, the parameters and their point values at these times. The process of concatenation and decryption remain the same. In the context of the point states, another statistical data base reading software is developed to generate reports, graphs and / or visualizations of these statistics. As the device according to the invention allows a communication in both directions, that is to say from the boiler to the supplier or the manufacturer and vice versa, it offers the possibility of receiving requests from a distance 15 (by SMS in particular) transmission of the buffer at a time t. This is called the point state of the boiler. This state takes the same parameters as the failure reports, but instead of being on 10 seconds, they are represented at time t. The device thus designed also offers the possibility of remotely modifying the settings of the boiler by a super technician of the maintenance service of the supplier or the manufacturer. An interface may be designed by the telephony operator in charge of the communication of the boiler to enter commands that will then be transformed by the telephony operator into an SMS. This SMS is then received and analyzed by the nano-server, which sends the command to the boiler via the I2C bus, the RS232 serial link or the EMS bus of the boiler according to the model. For example, this command may be the modification of the heating setpoint temperature. The device according to the invention finally offers the possibility of remotely modifying the settings of the boiler directly by the end customer, by sending an SMS to the nano-server. It will of course in this context limit the possible interventions of the customer to avoid transmission errors or erroneous or untimely orders likely to put the boiler down or putting the customer in danger.

Claims (18)

  1. Communication device for boiler (1) individual or collective comprising an electrical panel (2) with a connector (3) to allow instantaneous reading of the operating parameters of said boiler (1) for communication to the supplier and reciprocally characterized in that it comprises a nano-server (5) programmed for and dedicated to the reading of said operating parameters of said boiler (1) according to a determined increment, a memory (6), for storage for a fixed period of time of the statistics , means, sums and / or percentages of the values of said operating parameters recalculated by the nano-server at each increment, reading and storing the new average values at said last increment resulting in the overwriting or deletion of the statistics, means, sums and / or percentages previously stored, and means of communication (9) to enable the sending of a function report at the end of the determined duration comprising all or part of the contents of the memory (6).   2. Device according to claim 1, characterized in that said increment has a value between 200 milliseconds and 2 seconds inclusive.   3. Device according to one of claims 1 or 2, characterized in that said determined duration has a value of one week.   4. Device according to any one of claims 1 to 3, characterized in that the operating parameters are selected from the time under voltage, the burner operating time, the number of ignition attempts, the temperature and the evolution of the ionization current ...   5. Device according to any one of the preceding claims, characterized in that said connector (3) for reading said parameters is a bus I2C arranged on the electrical board of the boiler, an RS232 serial link or an EMS bus . 10   6. Device according to any one of the preceding claims, characterized in that the general supply of said devices is performed on the low voltage supply of the boiler.   7. Device according to any one of the preceding claims, characterized in that it further comprises a rotating buffer memory (7) for storing the values of said operating parameters for a predetermined period of time of several increments, the reading and the storage of the values of the last increment resulting in the erasure or overwriting of the first stored values when said memory is full to allow the sending, in the event of detection of a boiler failure, a failure report comprising all or part of the contents of the buffer (7).   8. Device according to claim 7, characterized in that the determined lapse of time has a value between 10 seconds and 30 seconds inclusive.   9. Device according to any one of the preceding claims, characterized in that said communication means are provided to receive remote commands analyzed and interpreted by the nanoserver to be sent to said boiler.   10. Device according to claim 9, characterized in that the remote controls are a request for transmission of the operating report, a request for one-off status transmission and / or troubleshooting commands.   11. Device according to any one of the preceding claims, characterized in that said communication means (9) are a modem.   12. Device according to claim 11, characterized in that said modem is a GSM modem. 30 11   13. Device according to claim 12, characterized in that it further comprises a GSM antenna (10).   14. Device according to one of claims 12 or 13, characterized in that said modem is provided to send the operating reports, failure and / or the point states of the boiler and / or receive remote commands by SMS.   15. Device according to claim 14 characterized in that it further comprises a SIM card dedicated to sending SMS and associated with a mobile phone number and a mobile phone network.   16. Device according to one of claims 14 or 15, characterized in that the operating reports are coded on 2 SMS   17. Device according to one of claims 14 or 15, characterized in that the point states are coded on 1 SMS.   18. Device according to one of claims 14 or 15, characterized in that the failure reports are coded on 3 SMS. 15