JP5373701B2 - How to inherit operating conditions between control units - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make a new control unit succeed the operating condition of an existing control unit even when the versions of the control units before and after replacement are different. <P>SOLUTION: This method includes: an operating condition data readout step in which a control part 31b of a new control unit 20b reads out first version status data 42 held in an E<SP POS="POST">2</SP>PROM 40a of an existing control unit 20a when a switch 21 of the new control unit 20b of a second version is operated; a version determining step in which a control part 30b of the new control unit 20b determines whether or not the version of the new control unit 20b is different from that of the existing control unit 20a; and an operating condition data writing step in which the control part 31b of the new control unit 20b converts the first version status data 42 into second version status data and writes it in an E<SP POS="POST">2</SP>PROM 40b when the version of the existing control unit 20a is different from that of the new control unit 20b. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a method for inheriting operating conditions in an old control unit before replacement to a new control unit after replacement when replacing the control unit attached to the apparatus.

For example, in a gas hot water supply apparatus, operating condition data used when executing a hot water supply operation is held in a non-volatile memory such as an E ² PROM mounted on the control unit. Thus, by holding the operating condition data in the nonvolatile memory, it is possible to prevent the operating condition data from being lost at the time of a power failure, and to resume the hot water supply operation normally at the time of power recovery.

  Then, when replacing the control unit, a method has been proposed in which the operating condition data held in the non-volatile memory of the old control unit before replacement is transferred to the non-volatile memory of the new control unit after replacement. (For example, refer to Patent Document 1).

JP 2005-30709 A

  In the control unit, the specification change (version upgrade) may be performed to improve the control performance and the configuration of the operating condition data may be changed. Therefore, when the control unit attached to the device is replaced and the operating condition data is transferred from the old control unit before replacement to the new control unit after replacement, the version of the old control unit is different from the version of the new control unit. The transferred operating condition data may not be compatible with the new control unit.

  In this case, the operating condition set by the operating condition data in the old control unit is not normally inherited by the new control unit, and the apparatus may be operated under an incorrect operating condition.

  The present invention has been made in view of such a background, and even if the version of the old control unit before replacement is different from the version of the new control unit after replacement, the operating conditions of the old control unit are changed to the new control unit. It is an object of the present invention to provide a method for inheriting operating conditions between control units that can be succeeded to.

  The present invention has been made to achieve the above object, and when the control unit is replaced in an apparatus including the control unit, the operating conditions set in the old control unit before the replacement are changed. With respect to the method of passing on to the new control unit, the control unit is based on the operating conditions defined by the non-volatile memory capable of reading and writing data, the communication port, and the operating condition data held in the non-volatile memory. And a control unit that controls the operation of the device and transmits and receives data via the communication port.

  And the 1st invention has a plurality of versions from which the above-mentioned control part differs in the composition of the above-mentioned operation condition data, and when the communication channel between the communication port of the new control unit and the communication port of the old control unit is established, The control unit of the new control unit reads the operating condition data reading step for reading the operating condition data for the version of the old control unit held in the non-volatile memory of the old control unit, and the control unit of the new control unit A version determining step for determining whether or not the version and the version of the old control unit are different, and when the version determining step determines that the version of the old control unit and the version of the new control unit are different, the new control unit Control unit of the old control unit read from the non-volatile memory of the old control unit. The operating conditions data for use, and converts the operating condition data for versions of the new control unit, characterized in that it comprises a operation condition data writing step of writing to the nonvolatile memory of the new control unit.

  According to the first invention, when the communication path between the communication port of the old control unit before replacement and the communication port of the new control unit after replacement is established by the operation condition reading step, the control unit of the new control unit Thus, the operating condition data for the version of the old control unit held in the non-volatile memory of the old control unit is read.

  When the version determination step determines that the version of the old control unit is different from the version of the new control unit, the operation condition data writing step causes the control unit of the new control unit to store the nonvolatile memory of the old control unit. The operating condition data for the version of the old control unit read out from is converted into the operating condition data for the version of the new control unit, and written into the non-volatile memory of the new control unit.

  Therefore, in the new control unit, the control unit uses the operation condition data stored in the nonvolatile memory, thereby inheriting the operation condition set in the old control unit and controlling the operation of the device. Can do.

  Next, according to a second aspect of the present invention, the control unit has a first version and a second version in which the configuration of the operation condition data is different, and the control unit of the first version stores the operation condition data for the first version in a nonvolatile manner. The control unit of the second version stored in the memory includes a data conversion unit that converts the operating condition data for the second version into the operating condition data for the first version, and the operating condition data for the second version When the operating condition data for the first version is held in the nonvolatile memory, and the communication path between the communication port of the new control unit of the first version and the communication port of the old control unit of the second version is established, The control unit of the new control unit reads the operation condition data for the first version stored in the non-volatile memory of the old control unit. And an operation condition data write step in which the control unit of the new control unit writes the operation condition data for the first version read in the operation condition data read step into the nonvolatile memory of the new control unit. It is characterized by that.

  According to the second invention, in the control unit of the second version, the data conversion unit converts the operation condition data for the second version into the operation condition data for the first version, and the operation condition for the first version. Data and operating condition data for the second version are held in the nonvolatile memory.

  When the operation condition reading step establishes a communication path between the communication port of the old control unit of the second version before the replacement and the communication port of the new control unit of the first version after the replacement, the new control The operating condition data for the first version held in the non-volatile memory of the old control unit is read out by the control unit of the unit.

  Then, in the operation condition data writing step, the control unit of the new control unit writes the operation condition data for the first version read out in the operation condition reading step in the nonvolatile memory of the new control unit.

  Therefore, the new control unit of the first version after replacement inherits the operating conditions set in the old control unit by using the operating conditions for the first version held in the nonvolatile memory of the new control unit. Thus, the operation of the device can be controlled.

  In the second invention, the control unit of the first version holds the operating condition data for the first version in a first area of the nonvolatile memory, and the control unit of the second version The operating condition data for the first version is retained in the first area of the nonvolatile memory, and the operating condition data for the second version is stored in a second area different from the first area of the nonvolatile memory. In the operation condition data reading step, the control unit of the new control unit uses the operation condition data stored in the first area of the non-volatile memory of the old control unit as the operation condition data for the first version. It is characterized by reading.

  According to this configuration, in the operation condition data reading step, the first version of the new control unit is configured such that the old control unit is non-volatile regardless of whether the old control unit is the first version or the second version. The operation condition data held in the first area of the memory can be easily read out as the operation condition data for the first version.

The block diagram of the hot water supply apparatus with which replacement | exchange of a control unit is performed. Explanatory drawing of the setting of the driving | running state in the control unit of a 1st version and a 2nd version. The flowchart of the setting process of the driving | running state in the control unit of a 1st version. The flowchart of the setting process of the driving | running state in the control unit of a 2nd version. Explanatory drawing when exchanging the control unit of the 1st version for the control unit of the 2nd version. Explanatory drawing of the inheritance of the operation state when replacing | exchanging the control unit of a 1st version for the control unit of a 2nd version, and when replacing the control unit of a 2nd version for a control unit of a 2nd version. Description of operation state inheritance when the control unit of the second version is replaced with the control unit of the first version, and how the state data for the first version and the state data for the second version are written to the E ² PROM Figure. Explanatory drawing when exchanging the control unit of a 2nd version for the control unit of a 1st version.

  Embodiments of the present invention will be described with reference to FIGS.

  Referring to FIG. 1, the hot water supply apparatus of the present embodiment (corresponding to an apparatus including the control unit of the present invention) includes a first burner 2-1 and a second burner 2-2 arranged side by side, A first heat exchanger 3-1 for hot water heated by the first burner 2-1, a second heat exchanger 3-2 for heating heated by the second burner 2-2, and the air supply chamber 5 , A can body 1 having a fan 6 for supplying combustion air to a first burner 2-1 and a second burner 2-2, and a control unit 20.

  The air supply chamber 5 is partitioned and defined by the distribution plate 4, and the air from the fan 6 enters the can 1 through a number of distribution holes 4 a formed in the distribution plate 4 from the air supply chamber 5. Supplied. Moreover, the 1st burner 2-1 and the 2nd burner 2-2 are comprised by the several unit burner 2a.

  The first heat exchanger 3-1 and the second heat exchanger 3-2 include a plurality of heat absorption fins 3a stacked with a gap in the front-rear direction, and a meandering heat absorption tube 3b penetrating these heat absorption fins 3a. It is comprised by. An upstream water supply pipe and a downstream hot water pipe (not shown) are connected to the heat absorption pipe 3b of the first heat exchanger 3-1. Then, the control unit 20 ignites the first burner 2-1 when the hot water tap at the downstream end of the hot water pipe is opened and water is passed through the first heat exchanger 3-1, and the set temperature from the hot water tap. A hot water supply operation for controlling the combustion amount of the first burner 2-1 is performed so that the hot water is discharged.

  The heat absorption pipe 3b of the second heat exchanger 3-2 is connected to a heating circuit such as floor heating via an unillustrated forward pipe and return pipe, and the control unit 20 burns the second burner 2-2. Then, the heating operation is performed in which the hot water is circulated through the second heat exchanger 3-2 in the heating circuit.

  In the can 1, a space between the first burner 2-1 and the first heat exchanger 3-1 and the second burner 2-2 and the second heat exchanger 3-2 is defined as the first burner 2. Is divided into a first combustion chamber 7-1 extending from -1 to the first heat exchanger 3-1, and a second combustion chamber 7-2 extending from the second burner 2-2 to the second heat exchanger 3-2. A partition wall 8 is provided.

  By providing the partition wall 8, the combustion gas of the first burner 2-1 is guided to the first heat exchanger 3-1 via the first combustion chamber 7-1, and the combustion gas of the second burner 2-2 is It is led to the second heat exchanger 3-2 via the second combustion chamber 7-2. The combustion gas heat-exchanged by the first heat exchanger 3-1 and the second heat exchanger 3-2 is discharged to the outside from an exhaust port 9a formed in the exhaust hood 9.

  The partition wall 8 has a hollow structure having two wall plates 81, 81 on the first combustion chamber 7-1 side and the second combustion chamber 7-2 side and a gap between the wall plates 81, 81. Yes. Each wall plate 81 has a shoulder portion 81a bent outward in the lateral direction and having a height equivalent to the upper end of the unit burner 2a, and a hanging plate portion 81b extending downward from the outer edge of the shoulder portion 81a toward the distribution plate 4. Is formed.

  The wide gap between the hanging plate portions 81 b and 81 b of both wall plates 81 and 81 communicates with the air supply chamber 5 through the communication holes 4 b formed in the distribution plate 4. In addition, a plurality of air blowing holes (not shown) are formed in the shoulder portion 81a of each wall plate 81.

  According to this configuration, a relatively large amount of air is supplied from the air supply chamber 5 to the gap between the hanging plate portions 81b and 81b, and a part of the air is between the wall plates 81 and 81 above the shoulder portion 81a. A cooling air flow is formed inside the partition wall 8 by flowing into the gap. Moreover, the cooling airflow which flows upward along the outer surface of each wall board 81 is produced | generated by the air which blows off from the air blowing hole of the shoulder part 81a. Therefore, the partition wall 8 is efficiently air-cooled from inside and outside, and the heat resistance of the partition wall 8 is ensured.

  Here, when fin clogging (occlusion of the gap between the heat absorption fins 3a) occurs in any one of the first heat exchanger 3-1 and the second heat exchanger 3-2, the first heat is generated. Combustion provided in the exhaust hood 9 above the exchanger 3-1 and the second heat exchanger 3-2 by the exhaust flow flowing through the other heat exchange and provided with this one heat exchanger The combustion gas in the room flows toward the partition wall 8 side.

  Even when the burner of the other heat exchanger is not combusting, the combustion gas in one combustion chamber is partitioned by being drawn by the air flow flowing from the air supply chamber 5 to the exhaust hood via the other heat exchanger. It flows unevenly toward the wall 8 side. When the hot water supply device is used for a long time in a state where the combustion gas in one combustion chamber flows in the direction of the partition wall 8 in this way, cooling with air becomes insufficient, and the partition wall is heated by the heat of the combustion gas. 8 may be damaged.

  Therefore, in the present embodiment, the rod-shaped temperature sensor 10 is inserted into the partition wall 8 from the front side of the can 1 and fixed. On both wall plates 81, 81 of the partition wall 8, a bulging portion 85 bulging outward in the lateral direction is formed at the insertion portion of the temperature sensor 10. By forming the bulging portion 85, the temperature sensing portion of the temperature sensor 10 is disposed in the space between the wall plates 81, 81 so as not to contact the wall plates 81, 81.

  Any one of the first heat exchanger 3-1 and the second heat exchanger 3-2, for example, the clogging of the fins of the second heat exchanger 3-2 occurs, and the combustion gas in the second combustion chamber 7-2 When the gas flows toward the partition wall 8 side, the temperature of the wall plate 81 located on the second combustion chamber 7-2 side becomes higher than normal. Therefore, the temperature sensor 10 receives the radiant heat from the wall plate 81, the temperature detected by the temperature sensor 10 becomes equal to or higher than a predetermined clogging determination temperature, and the occurrence of fin clogging can be detected.

  Therefore, the control unit 20 performs correction to increase the rotational speed of the fan 6 when detecting fin clogging. In addition, when fin clogging is detected again after the correction, the control unit 20 stops the operation of the hot water supply device and puts it in an interlock (non-operable) state.

The control unit 20 is an electronic unit that includes a microcomputer 30 (hereinafter referred to as the microcomputer 30), an E ² PROM 40 (corresponding to the nonvolatile memory of the present invention), and the like, and sets operating condition data (operating conditions for the hot water supply device) The first version of the control unit 20a or the second version of the control unit 20b is provided in the water heater.

In the control unit 20a of the first version, the microcomputer 30a functions as the control unit 31a that executes the above-described hot water supply operation, heating operation, and the like by causing the microcomputer 30a to execute a control program for the hot water supply device. The E ² PROM 40a holds version data 41 indicating the version (first version) of the control unit 20a and operation state data 42 for a first version described later.

  In the control unit 20b of the second version, the microcomputer 30b executes the control program of the microcomputer 30b hot water supply device, so that the microcomputer 30b executes the above-described hot water supply operation, heating operation, and the like, and the first version and the second version. It functions as a data converter 32 that converts operating condition data between versions.

Further, the E ² PROM 40b includes version data 41 indicating the version (second version) of the control unit 20b, operation state data 42 for the first version, operation state data 43 for the second version, and for the first version. The operation state data 42 and the conversion map data 45 between the operation state data 43 for the second version are held.

  Next, with reference to FIG. 2, the setting of the operation state in the first version and the second version will be described. In the following, although the heating operation will be described, the same processing is performed for the hot water supply operation.

  In the control unit 20a of the first version, as shown in FIG. 2A, the operation state of the hot water supply apparatus in the heating operation is set to state 10 (standby state), state 20 (fan correction: fan 6 with respect to the target combustion amount). 3), and a state 30 (interlock: operation prohibited).

  In the second version of the control unit 20b, as shown in FIG. 2B, the operation state of the hot water supply apparatus in the heating operation is set to state 10 (standby state), state 20 (fan correction 2: target combustion amount). The rotational speed of the fan 6 is increased by 10%), the state 30 (interlock: operation prohibited), and the state 40 (fan correction 1: the rotational speed of the fan 6 relative to the target combustion amount is increased by 5%). To do.

  Next, the operation state setting process in the first version control unit 20a will be described with reference to the flowchart shown in FIG.

  When the hot water supply device is turned on, the control unit 31a of the first version control unit 20a sets the state to STEP 10 (standby state: no correction of the fan 6) at STEP1, and then the second burner 2-2 at STEP2. It is determined whether or not is burning. When the second burner 2-2 is not combusting, the process returns to STEP 1. When the second burner 2-2 is combusting, the process proceeds to STEP 3, and the detected temperature Ts of the temperature sensor 10 is equal to or higher than the fin clogging determination temperature Tup. Judge whether there is.

  When the detected temperature Ts of the temperature sensor 10 is equal to or higher than the fin clogging determination temperature Tup, the process proceeds to STEP 4 and the control unit 31a sets the second burner in the state 20 (fan correction: the rotation speed of the fan 6 is increased by 5%). Increase air supply to 2-2. On the other hand, when the detected temperature Ts of the temperature sensor 10 is lower than the fin clogging determination temperature Tup, the process branches to STEP1 and the state 10 is maintained.

  In subsequent STEP5, the control unit 31a determines whether or not the detected temperature Ts of the temperature sensor 10 is equal to or lower than the fin clogging temperature Tdown. When the detected temperature Ts of the temperature sensor 10 is equal to or lower than the fin clogging elimination temperature Tdown, the process branches to STEP 1 and the control unit 31a changes from the state 20 to the state 10 (fan correction → standby).

  On the other hand, when the detected temperature Ts of the temperature sensor 10 is higher than the fin clogging elimination temperature Tdown in STEP5, the process proceeds to STEP6, and the control unit 31a determines whether the detected temperature Ts of the temperature sensor 10 is equal to or higher than the operation stop determination temperature Tend. Determine whether.

  When the detected temperature Ts of the temperature sensor 10 is equal to or higher than the operation stop determination temperature Tend, the process proceeds to STEP7, and the control unit 31a changes from the state 20 to the state 30 (fan correction → interlock state). In this case, the control unit 31a stops the combustion of the second burner 2-2.

  Then, in the next STEP 8, the interlock release operation is waited, and when the interlock release operation is performed, the process proceeds to STEP 1. The interlock release operation is performed when the second heat exchanger 3-2 is cleaned and the fin clogging is eliminated.

  On the other hand, when the detected temperature Ts of the temperature sensor 10 is lower than the operation stop determination temperature Tend in STEP 6, the process branches to STEP 4, and the control unit 31a continues the heating operation in the state 20 (fan correction 1).

  3, in the control unit 20a of the first version, the control unit 31a performs the state 10 (standby) and the state 20 according to the degree of fin clogging of the second heat exchanger 3-2. (Fan correction: Fan rotation speed is increased by 5%), and three operation states, state 30 (interlock) are set.

  Next, the operation state setting process in the control unit 20b of the second version will be described according to the flowchart shown in FIG.

  When the hot water supply apparatus is turned on, the control unit 31b of the second version control unit 20b sets the state 10 in STEP 10 (standby state: no correction of the fan 6), and in the subsequent STEP 11, the second burner 2-2. It is determined whether or not is burning. When the second burner 2-2 is not combusting, the process returns to STEP 10, and when the second burner 2-2 is combusting, the process proceeds to STEP 12, and the detected temperature Ts of the temperature sensor 10 is the first fin clogging determination temperature Tup1. It is determined whether this is the case.

  When the detected temperature Ts of the temperature sensor 10 is equal to or higher than the first fin clogging determination temperature Tup1, the process proceeds to STEP13, and the control unit 31b sets the state 40 (fan correction 1: the rotation speed of the fan 6 is increased by 5%). The supply amount of air to the second burner 2-2 is increased. On the other hand, when the detected temperature Ts of the temperature sensor 10 is lower than the first fin clogging determination temperature Tup1, the process branches to STEP10 and the state 10 is maintained.

  In subsequent STEP 14, the control unit 31b determines whether or not the detected temperature Ts of the temperature sensor 10 is equal to or lower than the first fin clogging temperature Tdown1. When the detected temperature Ts of the temperature sensor 10 is equal to or lower than the first fin clogging elimination temperature Tdown1, the process branches to STEP 10, and the control unit 31b changes from the state 40 to the state 10 (fan correction 1 → standby).

  On the other hand, when the detected temperature Ts of the temperature sensor 10 is higher than the first clogging elimination temperature Tdown1 in STEP14, the process proceeds to STEP15, and the controller 31b determines whether the detected temperature Ts of the temperature sensor 10 is equal to or higher than the operation stop determination temperature Tend. Judge whether or not.

  When the detected temperature Ts of the temperature sensor 10 is equal to or higher than the operation stop determination temperature Tend, the process branches to STEP 20, and the control unit 31b changes from the state 40 to the state 30 (fan correction 1 → interlock). In this case, the control unit 31b stops the combustion of the second burner 2-2. Then, in the next STEP 21, an interlock release operation is waited, and when the interlock release operation is performed, the process proceeds to STEP 1.

  On the other hand, when the detected temperature Ts of the temperature sensor 10 is lower than the operation stop determination temperature Tend in STEP 15, the process proceeds to STEP 16, and the control unit 31b detects the detected temperature Ts of the temperature sensor 10 equal to or higher than the second fin clogging determination temperature Tup2. Determine whether or not.

  When the detected temperature Ts of the temperature sensor 10 is equal to or higher than the second fin clogging determination temperature Tup2, the process proceeds to STEP 17, and the control unit 31b sets the state 20 (fan correction 2: the rotational speed of the fan 6 is increased by 10%), The supply amount of air to the second burner 2-2 is further increased. On the other hand, when the detected temperature Ts of the temperature sensor 10 is lower than the second fin clogging determination temperature, the process branches to STEP 13 and the state 40 is maintained.

  In subsequent STEP 18, the controller 31b determines whether or not the detected temperature Ts of the temperature sensor 10 is equal to or lower than the second fin clogging temperature Tdown2. Then, it is determined whether or not the detected temperature Ts of the temperature sensor 10 is equal to or lower than the second fin clogging elimination temperature Tdown2. When the detected temperature Ts of the temperature sensor 10 is equal to or lower than the second fin clogging temperature Tdown2, the process branches to STEP13, and the control unit 31b changes the state 20 to the state 40 (fan correction 2 → fan correction 1).

  On the other hand, when the detected temperature Ts of the temperature sensor 10 is higher than the second fin clogging elimination temperature Tdown2 in STEP 18, the process proceeds to STEP 19, and the control unit 31b detects the detected temperature Ts of the temperature sensor 10 equal to or higher than the operation stop determination temperature Tend. Determine whether or not.

  When the detected temperature Ts of the temperature sensor 10 is equal to or higher than the operation stop determination temperature Tend, the process proceeds to STEP 20, and the control unit 31b changes from the state 20 to the state 30 (fan correction 2 → interlock). On the other hand, when the detected temperature Ts of the temperature sensor 10 is lower than the operation stop determination temperature Tend, the process branches to STEP 17 and the control unit 31b continues the heating operation in the state 20 (fan correction 2).

  4, in the control unit 20b of the second version, the control unit 31b performs the state 10 (standby) and the state 20 according to the degree of fin clogging of the second heat exchanger 3-2. Four operating states are set: (Fan correction 2: fan rotation speed up 10%), state 30 (interlock), and state 40 (fan correction 1: fan rotation speed up 5%).

[Replacement of control unit from first version to second version]
Next, a procedure for replacing the first version of the old control unit 20a attached to the hot water supply apparatus with the second version of the new control unit 20b will be described with reference to FIG.

  The replacement operator first removes the old control unit 20a from the hot water supply device, attaches the new control unit 20b to the hot water supply device, and connects the communication port 24 of the old control unit 20a and the communication port 24 of the new control unit 20b to the communication cable 60. Connect with.

Then, the replacement worker connects the new control unit 20 b to the commercial power supply 50 through the power connector 25. From the AC power supplied from the commercial power source, the DC power source 23 generates DC power and supplies it to the microcomputer 30b and the E ² PROM 40b, thereby starting the microcomputer 30b. Further, DC power is supplied from the new control unit 20b to the old control unit 20a via the communication cable 60, and the microcomputer 30a of the old control unit is also activated.

  Next, the replacement operator operates the switch 21 of the new control unit 20b. Thereby, the transfer of the status data from the old control unit 20a to the new control unit 20b is instructed, and the following “operation condition data reading step” is performed by the control unit 31a of the old control unit 20a and the control unit 31b of the new control unit 20b. , “Version determination step” and “operation condition data writing step” are executed.

"Operation condition data read step"
The control unit 31b of the new control unit 20b requests status data from the control unit 31a of the old control unit 20a. In response to this request, the control unit 31a of the old control unit 20a transmits the state data 42 for the first version held in the E ² PROM 40a to the new control unit 20b via the communication cable 60. The control unit 31b of the new control unit 20b writes the status data 42 for the first version received from the old control unit 20a in the work area of the E ² PROM 40b.

"Version judgment step"
The control unit 31b of the new control unit 20b requests the version data 41 from the control unit 31a of the old control unit 20a, and the control unit 31a of the old control unit 20a holds in the E ² PROM 40a in response to this request. The version data 41 (in this case, data indicating the first version) is transmitted to the new control unit 20b.

  The control unit 31b of the new control unit 20b determines whether the version of the old control unit 20a is the first version or the second version based on the version data 41 received from the old control unit 20a.

"Operation condition data writing step"
In the example of FIG. 5, since the old control unit 20a is the first version, the control unit 31b of the new control unit 20b uses the state data 42 for the first version of the old control unit 20a (state 10: standby, state 20: According to the conversion map shown in FIG. 6A, the state data 43 for the second version (state 10: standby, state 20: fan correction 2) , State 30: interlock, state 40: indicates one of fan correction 1).

The conversion map data 45 is held in advance in the E ² PROM 40b of the second version control unit 20b.

Then, the control unit 31b of the new control unit 20b writes the status data 43 for the second version obtained by the conversion into the second area AD2 of the E ² PROM 40b. Thereby, the state set in the old control unit 20a of the first version is succeeded to the new control unit 20b of the second version.

Note that when the old control unit before the replacement is the second version, it is not necessary to convert the state data. Therefore, as shown in FIG. 6B, the control unit 31b of the new control unit 20b The state data 43 for the second version received from the unit 20b is written as it is into the second area AD2 of the E ² PROM 40b. In this case, the state set in the old control unit 20b of the second version is succeeded to the new control unit 20b of the second version.

  In addition, during the execution of the “operation condition reading step”, “version determination step”, and “operation condition data writing step”, the control unit 31b of the new control unit 20b must transfer data to the 7-segment LED 22. Is displayed. The control unit 31b displays a message indicating that on the 7-segment LED 22 when the data transfer is normally completed, and displays a message indicating that on the 7-segment LED 22 when the data transfer is abnormally ended.

  Here, as described above, the second version control unit 20b attached to the hot water supply device is in the state 10 (standby), the state 20 depending on the state of fin clogging in the second heat exchanger 3-2. (Fan correction 2), state 30 (interlock), and state 40 (fan correction 1) are set, and the data is written in the second area AD2.

Then, when setting the state for the second version, the control unit 20b acquires the state for the first version by the conversion map shown in FIG. 7A, and the state data 42 for the first version is Write to the first area AD1 of the E ² PROM 40b. As a result, in the control unit 20b of the second version, as shown in FIG. 7 (b), the status data 42 for the first version and the status data 43 for the second version are both held in the E ² PROM 40b. It is supposed to be in a state.

  In this embodiment, the “version determination step” is executed after the “operation condition data reading step” is executed. However, after the “version determination step” is executed first, the “operation condition data reading step” is executed. You may do it.

[Replacement of control unit from second version to first version]
Next, a procedure for replacing the second version old control unit 20b attached to the hot water supply apparatus with the first version new control unit 20a will be described with reference to FIG.

  Similar to [Replacement of the control unit from the first version to the second version] described above, the replacement operator removes the old control unit 20b from the hot water supply apparatus, attaches the new control unit 20a to the hot water supply apparatus, and installs the old control unit. The communication port 24 of 20b and the communication port 24 of the new control unit 20a are connected by a communication cable 60.

  The replacement worker connects the new control unit 20 a to the commercial power supply 50 by the power connector 50. Thereby, as described above, DC power is supplied to the new control unit 20a and the old control unit 20b, and the microcomputer 30a of the new control unit 20a and the microcomputer 30b of the old control unit 20b are activated.

  Next, the replacement operator operates the data movement start switch 21 of the new control unit 20a. Thereby, the transfer of the status data from the old control unit 20b to the new control unit 20a is instructed, and the following “operation condition data read step” and “operation condition data write step” are executed.

"Operation condition data read step"
The control unit 31a of the new control unit 20a requests the control unit b of the old control unit 20b to transmit the state data for the first version held in the first area AD1 of the E ² PROM 40b. In response to this request, the control unit 31b of the old control unit 20b transmits the status data 42 for the first version held in the first area AD1 of the E ² PROM 40b to the new control unit 20a.

"Operation condition data writing step"
The control unit 31a of the new control unit 20a writes the status data 42 for the first version received from the old control unit 20b in the first area AD1 of the E ² PROM 40a. As a result, the state set in the old control unit 20b of the second version is succeeded to the new control unit 20a of the first version.

  If both the old control unit before replacement and the new control unit after replacement are the first version control unit 20a, the new control unit Requests transmission of the status data 42 for the first version held in the one area AD1.

In the “operation condition data writing step”, the control unit 31a of the new control unit 20a uses the first version status data 42 received from the old control unit 20a as the first area of the E ² PROM 40a of the new control unit 20a. Write to AD1. Thereby, the state set in the old control unit 20a of the first version is succeeded to the new control unit 20a of the first version.

  During the execution of the “operation condition reading step” and the “operation condition data writing step”, the control unit 31a of the new control unit 20a displays on the 7-segment LED 22 that data is being inherited. The control unit 31a displays a message indicating that on the 7-segment LED 22 when the data transfer is normally completed, and displays a message indicating that on the 7-segment LED 22 when the data transfer is abnormally completed.

In the present embodiment, in the first version control unit 20a, the first version status data is held in the first area AD1 of the E ² PROM 40a, and in the second version control unit 20b, the E ² PROM 40b. In the first area AD1, state data 42 for the first version is held, and state data 43 for the second version is held in the second area AD2, but the state data 42 and 43 are held in arbitrary areas. You may do it. In this case, the first version control unit 20a after the exchange transmits the first version status data to the old version old control unit 20a or the second version old control unit 20b before the exchange. The old control unit may send the first version status data to the new control unit in response to the request.

  Moreover, in this Embodiment, although control unit 20a, 20b with which a hot-water supply apparatus is equipped was shown, this invention is applicable also to the control unit with which another apparatus is equipped.

In this embodiment, E ² PROM is used as the nonvolatile memory of the present invention, but other types of nonvolatile memory such as flash memory may be used.

  In the present embodiment, the control units 20a and 20b having two types of versions of the first version and the second version are shown. However, the present invention is also applied to control units having three or more types of versions. Is possible.

  Further, in the present embodiment, as the operation condition data of the present invention, the operation state data corresponding to the degree of fin clogging (first version state data 42, second version state data 43) is shown. Similar to the operation state data, the hot water supply set temperature data and the adjustment data of the actuator (proportional valve for changing the flow rate of the fuel gas supplied to the first burner 2-1) are similar between the control units. Can be inherited at.

  In this embodiment, the old control unit 20 before replacement and the new control unit 20 after replacement are connected by the communication cable 60 to establish a communication path. However, communication between the old control unit and the new control unit is performed wirelessly. A path may be established.

DESCRIPTION OF SYMBOLS 1 ... Can body, 2-2 ... 2nd burner, 3-2 ... 2nd heat exchanger, 6 ... Fan, 10 ... Temperature sensor, 20a ... Control unit of 1st version, 20b ... Control unit of 2nd version, 30a: a microcomputer provided in the first version control unit, 30b: a microcomputer provided in the second version control unit, 31a: a first version control unit, 31b: a second version control unit, 32 ... data conversion parts, 40a ... first version ^E 2 PROM provided in the control unit of the, 40b ... second version of a provided ^E 2 PROM to the control unit, 41 ... version data, 42 ... state data for the first version, 43 ... Status data for the second version.

Claims (3)

When replacing the control unit in an apparatus equipped with a control unit, the operating condition set in the old control unit before replacement is inherited by the new control unit after replacement,
The control unit controls the operation of the device based on an operation condition defined by an operation condition data held in the nonvolatile memory capable of reading and writing data, a communication port, and the nonvolatile memory. And a controller that transmits and receives data via the communication port, and has a plurality of versions with different configurations of the operating condition data,
When the communication path between the communication port of the new control unit and the communication port of the old control unit is established, the control unit of the new control unit uses the version for the version of the old control unit held in the non-volatile memory of the old control unit. An operation condition data read step for reading operation condition data;
A version determination step in which the control unit of the new control unit determines whether the version of the new control unit is different from the version of the old control unit;
When the version determination step determines that the version of the old control unit is different from the version of the new control unit, the control unit of the new control unit reads the version of the old control unit read from the non-volatile memory of the old control unit. The operation condition data between the control units is converted to operation condition data for the version of the new control unit and written to the non-volatile memory of the new control unit. Succession method. When replacing the control unit in an apparatus equipped with a control unit, the operating condition set in the old control unit before replacement is inherited by the new control unit after replacement,
The control unit controls the operation of the device based on an operation condition defined by an operation condition data held in the nonvolatile memory capable of reading and writing data, a communication port, and the nonvolatile memory. And a control unit that transmits and receives data via the communication port, and has a first version and a second version that have different configurations of the operating condition data,
The control unit of the first version holds the operating condition data for the first version in the nonvolatile memory,
The control unit for the second version includes a data conversion unit that converts the operation condition data for the second version into the operation condition data for the first version, and the operation condition data for the second version and the first version Operating condition data is stored in non-volatile memory,
When the communication path between the communication port of the new control unit of the first version and the communication port of the old control unit of the second version is established, the control unit of the new control unit holds in the non-volatile memory of the old control unit An operation condition data reading step for reading out the operation condition data for the first version,
The control unit of the new control unit includes an operation condition data write step of writing the operation condition data for the first version read in the operation condition data read step into the nonvolatile memory of the new control unit, To transfer operating conditions between control units. In the operating condition succession method between control units according to claim 2,
The control unit of the first version holds the operating condition data for the first version in the first area of the nonvolatile memory,
The control unit for the second version holds the operating condition data for the first version in the first area of the nonvolatile memory, and the operating condition data for the second version is stored in the nonvolatile memory. Hold in a second area different from the first area,
In the operation condition data reading step, the control unit of the new control unit reads the operation condition data held in the first area of the non-volatile memory of the old control unit as the operation condition data for the first version. A method for inheriting operating conditions between control units.

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