KR20150110173A - The outside Fan control system for Inverters - Google Patents

Abstract

The present invention relates to a method for optimizing the processing of a fan fault situation in consideration of economic feasibility and efficiency and a control system, regarding the control of an outer fan of an inverter for power generation. The system is configured to supply a temporal margin to a control for maximally using the self-purification capacity of the fan.

Description

[0001] The present invention relates to an external fan control system for an inverter,

The present invention relates to a method and a control system for optimizing the processing of a fan fault situation in consideration of economy and efficiency in the external fan control of an inverter.

As in the solar power generation system, a large-capacity inverter for power generation is accompanied by a high-speed switching circuit and operates in a closed space, and heat is hardly emitted to the outside. If the heat radiation is not effectively performed, And the lifetime of the parts is inevitably shortened.

Therefore, in order to lower the heat inside the inverter, most of the power inverters are mainly applied with air cooling technology using an external fan directly exposed to the outside.

Patent No. 0961710 discloses an inverter cooling technique using a fan, and relates to a technique for improving energy efficiency by controlling a cooling fan drive in response to a temperature change by providing a cooling fan control unit.

In addition, Japanese Patent No. 1153178 aims at achieving the purpose of heat dissipation and energy efficiency by controlling the number of fans to be driven based on the temperature inside the inverter through the fan control unit.

As described above, various conventional technologies for improving the functional and economic efficiency of the fan operation have been proposed with respect to air-cooling technology using an external fan to improve the service life and performance of the inverter by circulating the heat inside the inverter.

However, in the problem of the conventional air cooling technology, there is a problem that the performance of the inverter for power generation is lowered due to the occurrence of an abnormal operation due to the foreign material or the surrounding environment, There was no.

FIG. 1 shows a configuration of a conventional fan fault signal detection circuit. In FIG. 1, a current according to the fan start is drawn into an inlet portion of a fan fault signal. B is a detection unit of a fan fault signal, and determines whether the current state is a fan trip state based on a voltage measured in C, as a reference. C is a measuring part of a fan fault signal. When the voltage is out of a constant voltage maintained during normal operation by using a comparator, the voltage value measured at the upper and lower ends of the comparator is changed. Then, (Fan fault signal). D is transferred to a DSP (digital signal process) circuit which can process signals by changing the signal when the fan operation is in the normal state and the signal when the fault is in the current state to the current type. .

2 is a waveform of a signal transmitted to the DSP (Digtal signal process). A is a waveform for applying a fan fault signal power when the SMPS of the fan operation power source is operated, and B Is the waveform of the inrush current flowing when the fan is started. C is the fan operation current waveform which is shown when the fan operation power is normally started. D is the fan operating current waveform shown in the fan locking state. In this case, since the fan is in the locked state, the fan is repeatedly started and stopped. Thus, the waveform of the square- The waveform is displayed.

As described above, the fan locking state is realized for the purpose of detecting the state of the external fan when an abnormal signal is generated by foreign matter or other factors, and notifying the consumer of the state of the fan.

However, in the prior art, since the fan locking state is immediately determined as an error and controlled, there is no room to utilize a temporal margin in which foreign matter can be removed by itself, and a plurality of fan locking information The reliability of the product is deteriorated.

In addition, the conventional inverter for power generation stops the operation of the inverter in the state of fan locking, which causes a decrease in the amount of generated power of the inverter. It is urgent to solve the above-mentioned problems.

The present invention improves the processing function of the fan locking signal and the fan fault signal at the software level, thereby improving the conventional problem at a more effective cost.

In order to achieve the above object, the present invention provides a system for controlling an external fan of an inverter, comprising: a controller for monitoring the operation state of the fan when a fan locking signal is generated, A lock count unit for determining whether or not a fan fault has occurred by comparing the set number of lock reference counts (Ref_lock_count), and a lock count unit for detecting a fan lock signal exceeding the set number of times, And an error processing section which is driven only when the inverter does not operate.

If the fan lock count is equal to or greater than the lock reference count (Ref_lock_count), the locking count unit may determine the fan abnormal state.

The error processing unit accumulates and counts the number of occurrences of the fan abnormal state (Daily count) including the case where the fan lock signal is generated or the fan does not operate normally in units of a predetermined period, and determines whether the fan count exceeds the preset reference frequency (Ref_daily_count) And may further include an error determination unit for determining before driving.

The error processing unit may be driven only when the number of occurrences of the fan abnormal state (Daily count) exceeds the reference frequency (Ref_daily_count) as a result of the error determination unit.

Further, the error processing section performs an automatic reset operation by software including an automatic reset mode.

The error processing unit may include a daily fault display function for reporting to a customer. The display processing unit accumulates a reporting service count (Display count) in units of a predetermined period, compares the count with a preset count (Ref_disp_count) You can decide whether to run a daily fault display.

According to the present invention, by providing a temporal margin to the external fan control so as to make full use of the natural recovery capability of the inverter, it is possible to minimize the adverse effect of the inverter generated by the external environmental factors, reduce the number of unnecessary shutdowns, Stability and reliability can be secured.

1 is an exemplary diagram of a conventional fan fault signal detection circuit.
2 is a diagram illustrating a signal transmitted to a conventional digital signal process (DSP).
FIG. 3 is a graph illustrating changes in the number of occurrences and occurrences of a fan locking signal according to the present invention.
4 is a block diagram illustrating a connection relationship among configurations according to the present invention.
5 is a process flowchart according to the present invention.
6 is a processing flowchart of the error mode.

The present invention counts the number of times of starting and stopping the fan in order to secure a time margin in which an error is naturally eliminated in the fan locking operation of the power generation inverter, and executes an error processing routine only when a predetermined count is exceeded. It is designed to minimize the power generation decrease due to fan stop by changing the alarm signal (Fan Fault Signal) to Daily Fault Report once a day.

FIG. 3 is a graph illustrating a process of receiving a fan locking signal from the S / W and accumulating and counting the fan locking signal according to the number of occurrences.

The present invention does not perform a fault processing routine immediately when a fan locking signal is input, but uses a cumulative counting process to compare the set number of occurrences with the set number of occurrences, By repeating, it provides a temporal margin to the control.

Accordingly, when the number of times the fan lock signal is generated exceeds the preset number, it is determined as a fan fault state and the routine is executed.

FIG. 4 is a block diagram showing a connection relationship between the elements constituting the control system of the present invention, including a locking count unit 10 for making a judgment on a fan locking signal, an error judgment (20) and an error processing section (30) which is an error processing routine.

FIG. 5 is a flowchart showing a process of a control system according to the present invention.

The process flow of the locking count unit 10 will be described first. After the fan starts to operate normally (s10), the fan operation state is continuously monitored (s11) and the fan locking state is confirmed s12), and counts the number of fan lock signal generation times (Fan_lock_count).

If the number of times the fan lock signal is generated (Fan_lock_count) is equal to or greater than a preset reference number of times of locking reference (Ref_lock_count), or the fan does not operate normally as a result of the determination in step s12, the fan failure state is determined to be a fan fault state (S13).

Even if a fan lock signal is generated, the fan is repeatedly operated and stopped until the preset number of lock reference times (Ref_lock_count) is reached, and a time margin is provided for the control.

The present invention can minimize the burden on the execution of the error processing routine by providing the error determination unit 20 before branching directly to the error processing routine when the fan is abnormal.

The error determination unit 20 accumulates the number of times the fan lock signal generation cumulative count reaches the locking reference count Ref_lock_count or the fan does not operate normally and the number of times of driving is cumulatively counted in the occurrence count of the fan abnormal state Daily count .

If the number of occurrences of the counted fan abnormality state (Daily count) is greater than a reference number (Ref_daily_count), which is a set reference value for a predetermined period, the error processing routine is driven. If the count is less than the reference number of times (Ref_daily_count) The lock count section 10 is driven again to normally operate the fan (s20).

That is, by setting the number of occurrences for a predetermined period such as once a day, the daily reference frequency (Ref_daily_count) with respect to the fan anomaly state, the temporal margin is maximized in control so that the fan anomaly state can be naturally removed.

If the reference number Ref_daily_count is exceeded in the error determination unit 20, the error mode of the error processing unit 30 is performed (s30).

The fault mode has a processing flow as shown in Fig.

The error mode includes an S / W auto reset step (s301) for initiating the operation of the apparatus by software control and eliminating the error, which is automatically performed by the software without user intervention.

The error mode also includes a user reporting service. The user reporting service of the present invention limits the number of reporting services (display count) to a predetermined number of times (eg, once a day) (Ref_disp_count), and if the number of reporting services (Display count) does not exceed the reporting reference count (Ref_disp_count) (s302), the user performs a daily fault display step, which is a user reporting operation, (S303). Thereafter, a manual reset fault maintenance (s31) will be performed by the user's intervention.

If the number of reporting services exceeds the reporting reference number (Ref_disp_count), the error signal is masked without performing a daily fault display, and then the operation branches to the fan operating step (s10) It starts operation.

This makes it possible to optimize the error reporting for the customer, minimize the disruption situation for entering the manual mode, and solve the problems of stable operation of the system and reduction of power generation.

The manual reset fault maintenance (s31) corresponds to a task of directly intervening and repairing when the user recognizes an error situation by a daily fault dispaly or the like. Is minimized.

The technical scope of the present invention shall include matters which are obvious from the description of the specification, and the substitutions and modifications of the constituents within the scope of the present invention should be considered as belonging to the scope of the present invention.

10: locking count section 20: error judgment section
30:

Claims (10)

A system for controlling an external fan of an inverter,
When the fan locking signal is generated while monitoring the operation state of the fan, accumulation of the fan lock count is started while the normal operation of the fan is maintained, and the number of locked reference times (Ref_lock_count) fault), and
And an error processing unit which is driven only when a fan locking signal is generated beyond the set number of times or when the fan does not operate normally. The apparatus according to claim 1,
Wherein when the fan lock count is equal to or greater than a lock reference count (Ref_lock_count), it is determined that the fan is abnormal. The apparatus according to claim 1,
The number of occurrences of the fan abnormal state (Daily count) including the case where the fan locking signal is generated or the fan is not operating normally is accumulated and counted in units of a predetermined period, and an error judgment is made to judge whether the fan has exceeded the daily reference count (Ref_daily_count) Further comprising: a control unit for controlling the fan of the inverter. The apparatus according to claim 3,
Wherein the fan control unit is operated only when the number of occurrences of the fan abnormal state (Daily count) exceeds the preset reference frequency (Ref_daily_count) as a result of the determination by the error determination unit. 4. The external fan control system of claim 3, wherein the error determination unit sets the reference frequency (Ref_daily_count) to one per day. The apparatus according to claim 1,
And an automatic reset operation is performed in software, including an automatic reset mode. The apparatus according to claim 1,
And a daily fault display function for reporting to the customer. 8. The apparatus according to claim 7,
The method as claimed in any one of claims 1 to 3, wherein the display unit counts the number of reporting services (Display count) in units of a predetermined period and compares the counted number of times with a reference frequency (Ref_disp_count) set during the corresponding period to determine whether to perform a daily fault display . 9. The apparatus according to claim 8,
And a daily fault display is performed only when the number of reporting services does not exceed the reporting reference count (Ref_disp_count). 9. The apparatus according to claim 8,
Wherein the number of reporting reference times (Ref_disp_count) of the user reporting service is once per day.

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