JPH07286724A - Fan motor controller for hot water supplying apparatus - Google Patents

Abstract

PURPOSE:To rapidly reignite and to prevent an undershoot by removing an integration control item from a feedback control value calculation and calculating the feedback control value when a proportional control value of the feedback control amount for a fan motor becomes maximum during postpurging air supplying. CONSTITUTION:When a hot water supply faucet is closed in the state that combustion is executed so that a heat exchanging flow sensor 21 detects less than lowest water flow rate, a controller 30 instructs fire extinguishing of a burner 17, and starts an FF control for a fan motor 18. In order to correct an error of a set postpurging number of revolutions from real number of revolutions subsequently to the start of the FF control, an FB control is started by the proportional integration control of the motor 18. If the proportional control value of the FB control reaches maximum when a postpurging air supply operating time is not yet elapsed, the controller 30 thereafter removes the integration control item from an FB control calculation formula, and calculates the FB control value.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fan motor controller for a water heater.

[0002]

2. Description of the Related Art In a water heater equipped with an instantaneous heat exchanger and a burner for heating the instantaneous heat exchanger, the burner starts combustion when water of a minimum working water amount or more flows into the instantaneous heat exchanger, and the minimum working water amount. Combustion will be stopped when it becomes less than. Further, in many water heaters, the blower fan is controlled to a relatively low rotation speed for ignition so that ignition is performed under appropriate blown air at the start of combustion, and when the combustion is stopped, such as in the burner. In order to exhaust the exhaust gas efficiently and replace it with fresh air, post-purge air blowing at a relatively high speed is performed for a certain period of time.
When the amount of water equal to or more than the minimum working water flows again during the post-purge air blowing, the speed of hot-water supply is restarted promptly. There is also provided one that controls a fan motor so as to switch to the ignition rotation speed. Further, as a control means of the fan motor of the blower fan, there is one that controls by combining feedforward control (hereinafter referred to as FF control) and feedback control (hereinafter referred to as FB control). In that case, FB is used.
A control value calculation is also provided that is configured by a proportional control term and an integral control term.

[0003]

However, in the above-described conventional water heater, the fan motor control combining the FB control by the proportional-plus-integral control with the FF control is performed, and the blower fan is used when the hot water is re-extracted during the post-purging blow operation. Of the post-purge rotation speed (for example, the maximum rotation speed of 4660
rpm) to low ignition speed (eg 3100 rpm)
In the case of switching to and re-ignition,
It takes time to change from the post-purge rotation speed to the ignition rotation speed, which causes a problem of undershoot of hot water. The reason for this will be described with reference to FIG. 4. In the conventional water heater, as shown in FIG. 4, water of a minimum working water amount or more flows again during the post-purge air blowing operation, so that the rotation speed of the blower fan is ignited from the post-purge rotation speed. FIG. 5 is a diagram showing a change in the number of revolutions when the number of revolutions is changed to the number of revolutions and a change in the outlet heated water temperature accompanying the change. The upper part of FIG. 4 shows the passage of time from right to left. During the post-purge air flow shown on the right side of the above figure, the fan motor is driven with the FF control value so that the rotation speed of the blower fan becomes the set post-purge rotation speed, and the error between the set post-purge rotation speed and the actual rotation speed Is FB
It will be corrected by the control value. However, even if the actual fan motor drive output (voltage) reaches the upper limit, and if the actual rotation speed is lower than the set post-purge rotation speed, further increase in the rotation speed cannot be expected (see the symbols in FIG. 4). In the case shown by A), in that case, the proportional control value of the FB control reaches the maximum value and does not increase any more, and only the integral control value (I _{1 in} FIG. 4) accumulates. However, under such post-purge air blowing conditions, when water above the minimum operating water amount (MOQ) flows again, the controller performs FF control with the ignition rotation FF control value in order to switch the fan rotation speed to the set ignition rotation speed. At the same time as starting, it tries to correct the error between the actual rotation speed and the set ignition rotation speed by FB control.
Since the control value remains the integrated control value accumulated during the post-purge air blowing (I _{2 in} FIG. 4), it takes time for the actual rotation speed to drop to the set ignition rotation speed and to reach ignition. As a result, as shown in the lower diagram of FIG. 4, the hot water discharge temperature gradually decreases until re-ignition, and a large undershoot occurs, resulting in poor hot water discharge characteristics.

Therefore, the present invention solves the above-mentioned drawbacks of the conventional water heater, and the FB control is composed of proportional-plus-integral control.
In a water heater that controls the rotation of the fan motor by combining the controls, and the flow of more than the minimum working water flows again during the post-purging air blowing, the hot water heater is switched to the ignition air blowing for re-ignition. Providing a fan motor control device for a water heater that can quickly re-ignite by reducing the number of revolutions from the number of revolutions to the ignition number of revolutions, prevent undershoot during that period, and ensure good hot water discharge characteristics With the goal.

[0005]

In order to achieve the above object, a fan motor control device for a water heater according to the present invention starts combustion when an amount of water equal to or more than a minimum working water flows to an instantaneous heat exchanger, and an instantaneous type Combustion is stopped when the amount of water to the heat exchanger becomes less than the minimum amount of working water, and a fan motor for a blower fan that performs feedback control by proportional-plus-integral control in addition to feedforward control is provided. When the fan is stopped, the fan blower of the burner is blown with the post-purge rotation speed at the set post-purge rotation speed for a certain period of time. A fan in a water heater in which the ignition speed is set to a lower speed than the purge speed to perform re-ignition In the motor control device, when the proportional control value of the feedback control with respect to the fan motor becomes the maximum during the post-purge air blowing, the feedback is thereafter performed in the form of excluding the integral control term from the feedback control value calculation. It is characterized in that a controller for calculating a control value and issuing a control output command is provided.

[0006]

According to the features of the present invention, when the actual fan motor drive output reaches the upper limit value while the actual rotation speed is less than the set post purge rotation speed during the post-purging air blowing, the fan is further rotated. Since the motor drive output and the rotation speed do not increase, the proportional control value of the FF control becomes maximum at that time and does not increase any more. in spite of,
The integral control value of the FF control accumulates and increases with time if no action is taken. In the present invention, when the proportional control value of the FB control with respect to the fan motor becomes maximum, the integral control term is excluded from the FB control value calculation thereafter. Even if the rotation speed is switched to the ignition rotation speed after the post-purge airflow continues without reaching the purge rotation speed, there is no addition of the integral control value in the ignition rotation FB control combined with the ignition rotation FF control. The FB control is smoothly performed, and the set ignition speed can be quickly reduced. Therefore, the time until re-ignition is short, the hot water temperature that drops during that time is also small, the undershoot during re-hot-water discharge is sufficiently reduced, and the hot-water discharge characteristics are improved.

[0007]

EXAMPLES The present invention will be described below based on examples.
FIG. 1 is an overall configuration diagram of a water heater equipped with the device of the present invention, FIG. 2 is a flowchart showing a control mechanism of a fan motor by a controller, and FIG. 3 is a diagram showing the present invention. FIG. 6 is a diagram showing changes in the rotation speed of the blower fan when the rotation speed of the blower fan is switched from the post-purge rotation speed to the ignition rotation speed by flowing again, and the accompanying change in the outlet heated water temperature.

First, in FIG. 1, the water heater comprises an instantaneous heat exchanger 10, a water inlet pipe 11 for sending water to the heat exchanger 10, and a hot water outlet pipe 12 for discharging hot water heated by the heat exchanger 10. , A bypass pipe for bypassing water from the water inlet pipe 11 to the hot water outlet pipe 12
13, a mixing controller 14 for mixing and adjusting water from the bypass pipe 13 and hot water from the hot water outlet pipe 12, and a hot water supply pipe 15 connected to the downstream of the mixing controller 14. The instantaneous heat exchanger 10 is heated by a burner 17 such as an oil burner. The burner 17 includes a fan motor 18 for a blower fan. Reference numeral 21 is a heat exchange flow rate sensor, 22 is a water inlet temperature sensor, 23 is a hot water outlet temperature sensor, 24 is a hot water supply temperature sensor, and 25 is a fan rotation speed sensor. Further, 30 is a controller, and this controller 30 controls the entire apparatus, and includes a heat exchange flow rate sensor 21, an incoming water temperature sensor 22, and a hot water temperature sensor 2.
3. Input information from the hot water temperature sensor 24, fan speed sensor 25, and other sensors, and set hot water temperature information from a remote controller (not shown) to perform the necessary calculations and mix the required commands. It is sent to the controller 14, burner 17, fan motor 18, etc.

The fan motor control operation mechanism of the water heater by the controller 30 in the above water heater will be described with reference to FIGS. 2 and 3. When the heat exchange flow sensor 21 detects less than the minimum operating water amount (MOQ) by closing the hot water supply currant (not shown) in the state where combustion is being performed during the hot water supply operation by the water heater (YES in S1) Then, the controller 30 commands the extinction of the burner 17, and starts the FF control for the fan motor 18 in order to perform the post-purge air blowing operation of the blower fan at the set post-purge rotation speed (S2). The set post purge rotation speed of the blower fan is, for example, the maximum rotation speed of the blower fan of 4660 rpm.
Further, the FF control value is calculated corresponding to the set post-purge rotation speed. Then, following the start of the FF control, the FB control of the fan motor 18 is started in order to correct the error between the set post-purge rotation speed and the actual rotation speed (S).
3). The FB control is based on proportional-plus-integral control, and therefore the FB control value is calculated by the following equation. FB control value = proportional control value + integral control value Therefore, the total control value in the post-purge air blowing operation is the sum of the FF control value and the FB control value, and is calculated by the following formula. Total control value = FF control value + FB control value = FF control value + proportional control value + integral control value ... While the actual post-purge rotation speed is corrected to the set post-purge rotation speed by an equation such as When the post-purge air-blowing operation continues, that is, when the post-purge air-blowing operation time has not yet elapsed (S
If the proportional control value of the FB control reaches the maximum (Yes in S5), then the controller
30 excludes the integral control term from the FB control value arithmetic expression (S
6) Calculate the FB control value. Here, the situation in which the proportional control value of the FB control reaches the maximum means a situation in which the actual fan motor drive output reaches the upper limit, and the situation in which it cannot be increased any more (state indicated by symbol B in FIG. 3). In this situation, the proportional control value reaches the maximum value and does not increase any more, and if there is an integral control term, only that value will accumulate. However, in the present invention, when the proportional control value reaches the maximum, the integral control term is deleted from the FB control value arithmetic expression, so that the situation where the integral control value accumulates is eliminated.

In the situation where the integral control term is deleted, water more than the minimum working water amount (MOQ) flows through the instantaneous heat exchanger again during the post-purge air blowing operation (Yes in S7),
The controller 30 starts the FF control with the FF control value corresponding to the set ignition rotation speed in order to switch the rotation speed of the blower fan from the post-purge rotation speed to the set ignition rotation speed (S8). The set ignition rotation speed is a rotation speed for providing an air flow rate that allows good ignition, and is set to a value lower than the set post purge rotation speed (4660 rpm), for example, 3100 rpm. Then, following the start of the FF control for the ignition rotation, the FB control of the fan motor 18 is started in order to correct the error between the set ignition rotation speed and the actual rotation speed (S).
9). Since the FB control in this case goes through the step S6, there is no accumulation of the integrated value, and therefore the difference between the set ignition speed and the actual speed is rapidly corrected by the FB control (the upper diagram of FIG. 3). . When the actual rotation speed reaches the set ignition rotation speed (YES in S10), the controller 30 commands the burner 17 to perform the ignition operation (S11). Since the rotation speed control to the ignition rotation speed is promptly performed, the time required for that is shortened, and the undershoot of the discharge water temperature during that time is slight, resulting in good discharge characteristics (see the lower diagram of FIG. 3).

In the step S4, the post-purge air is not sent when the post-purge air is not supplied again during the post-purge air blowing operation (NO in S7) and the post-purge time has elapsed (YES in S4). Finished,
A standby state is entered (S12). If the proportional control term of the FB control reaches the maximum (NO in S5) or more than the MOQ (YES in S7) during the post-purge air blowing operation,
The integral control term is not deleted from the FB control value arithmetic expression.

[0012]

According to the present invention, which has the above-described structure,
According to the fan motor control device of the water heater described in (1), when the proportional control value of the feedback control with respect to the fan motor becomes maximum during the post-purging air blowing, the integral control term is calculated from the feedback control value thereafter. Since a controller that performs feedback control value calculation in the excluded form and issues a control output command is provided, ignition occurs after the post-purge air blowing continues with the actual rotation speed at the maximum drive output not reaching the set post-purge rotation speed. Even if the rotation speed is switched to the rotation speed, feedback control can be performed smoothly because the integral control value in the ignition rotation feedback control combined with the ignition rotation feedforward control is not accumulated, and the set ignition rotation speed can be quickly set. The number of rotations can be reduced. Therefore, it is possible to shorten the time until re-ignition, and to perform re-melting with good tapping characteristics in which the degree of undershoot is sufficiently reduced.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram of a water heater equipped with the device of the present invention.

FIG. 2 is a flowchart showing a fan motor control mechanism by a controller.

FIG. 3 is a graph showing changes in the rotation speed of the blower fan when the rotation speed of the blower fan is switched from the post-purge rotation speed to the ignition rotation speed by re-flowing a minimum amount of working water during the post-purging blow operation. FIG. 5 is a diagram showing a change in outlet heated water temperature associated therewith.

FIG. 4 shows a change in the rotation speed of the blower fan when the rotation speed of the blower fan is switched from the post-purge rotation speed to the ignition rotation speed in the conventional water heater when the minimum working water amount or more flows again during the post-purging blow operation. It is a figure which shows the progress of and the change of tap water temperature accompanying it.

[Explanation of symbols]

 10 Instantaneous heat exchanger 11 Inlet pipe 12 Outlet pipe 13 Bypass pipe 14 Mixing controller 15 Hot water pipe 17 Burner 18 Fan motor for blower fan 21 Heat exchange flow rate sensor 22 Inlet temperature sensor 23 Outlet temperature sensor 25 Fan speed sensor 24 Hot water supply Temperature sensor 30 controller

Claims (1)

[Claims] 1. The combustion is started when a water amount exceeding the minimum working water amount flows into the instantaneous heat exchanger, and the combustion is stopped when the water amount to the instantaneous heat exchanger becomes less than the minimum working water amount. In addition to the feed-forward control, the fan motor for the blower fan is used for feedback control by proportional-plus-integral control.When the combustion is stopped, the blower fan of the burner is set to post for a certain time at the set post-purge rotation speed. When purging air is blown, and when there is running water over the minimum working water amount during the post-purging air blowing, the fan rotation speed is switched from the post-purging rotation speed to the ignition rotation speed set to a lower rotation speed to perform re-ignition. A fan motor control device for a hot water supply device, which controls the fan motor during the post-purging air blowing. When the proportional control value of the feedback control becomes maximum, after that, the feedback control value calculation is performed in the form of excluding the integral control term from the feedback control value calculation, and the controller that issues the control output command is provided. A fan motor control device for water heaters.