KR200408364Y1 - Stating equipment for inverter - Google Patents

Abstract

The present invention relates to an inverter starting device for starting an inverter that transfers power of a battery to a load, and more particularly, to an inverter starting device for starting an inverter only when a load is connected by automatically detecting whether a load is connected to the inverter. will be.

Inverter starting device of the present invention,

An inverter that converts the DC power of the battery into AC power and supplies power to the load; A load detector connected to an output terminal of the inverter and detecting whether the load is connected to the inverter; An inverter starter for automatically starting the inverter when there is a load connection signal from the load detector; And a driving voltage unit connected to the battery and outputting driving voltages for the load detection unit and the inverter starting unit.

       The load detecting unit connects the first rectifying unit and the output terminal of the inverter, and when the load is connected to the inverter, a relay unit through which a current flows, and a port for receiving current from the relay unit and transferring a load connection signal to the inverter starting unit. Characterized by including a coupler,

The inverter starter may include a first controller configured to control a first power changer of the inverter using a microcontroller, a second controller configured to receive a signal from the first controller and to control the second power converter, and the load detector And a power supply unit supplying power of the second rectifying unit to the first control unit when a load connection signal is input from the photocoupler.

Inverter, load detector, inverter starter, transformer, photocoupler, relay

Description

Inverter starter {STATING EQUIPMENT FOR INVERTER}

1 is a schematic circuit diagram of an inverter starting device according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: inverter 11: the first power conversion unit

12: second power conversion unit

20: load detection unit 21: relay unit

30: inverter starting unit 31: the first control unit

32: second control unit 33: power supply unit

40: driving voltage section 41: switching section

42: first rectifier 43: second rectifier

The present invention relates to an inverter starter for starting an inverter that transfers battery power to a load. More specifically, the present invention relates to an inverter starter for automatically starting an inverter only when a load is connected by automatically detecting whether a load is connected to the inverter. It is about.

An inverter drives a power tool by converting the DC power of the battery into an AC power to supply power to a load such as a power tool.

Thus, the conventional inverter for transmitting the power of the battery to the power tool is divided into two ways with and without the ON / OFF switch.

In the case of the ON / OFF switch, the inverter operates when the switch is turned ON and the inverter stops when the switch is OFF. This method is inconvenient that the user must always operate the ON / OFF switch. In addition, if the user installed the inverter in a place where the user does not have direct access to the inverter, this inconvenience becomes even greater.

Without an ON / OFF switch, a power tool (load) is connected to the inverter to transfer the power of the battery to the power tool unconditionally. This method does not require the user to operate the ON / OFF switch individually, but since the inverter is always turned on, the battery power is consumed so quickly that it is not efficient. In addition, it is cumbersome to disconnect the inverter from the battery and reconnect them each time the load is connected to prevent battery power consumption.

In particular, in a high-rise vehicle that raises a work bench such as a ladder to allow a worker to work on it, an inverter is usually installed in a battery mounted on the high-rise vehicle to drive a power tool using the power of the battery. Due to the nature of the vehicle, the inverter is not exposed to the outside, but is mounted deep inside the vehicle like an automobile engine. Therefore, even if the ON / OFF switch is attached, it is difficult to use the switch.However, if the inverter is always turned ON, the battery continues to consume power and the power consumption is large. Occurs.

The present invention has been devised to solve the above-mentioned conventional problems. There is no separate ON / OFF switch for starting the inverter, and the load detecting unit automatically detects whether the load is connected and starts the inverter only when the load is connected. The purpose of the present invention is to provide an inverter starting device which minimizes the power consumption of the battery and electrically isolates the battery side from the load side and eliminates the risk of electric shock.

Inverter starting device of the present invention for achieving the above object,

An inverter that converts the DC power of the battery into AC power and supplies power to the load;

A load detector connected to an output terminal of the inverter and detecting whether the load is connected to the inverter;

An inverter starter for automatically starting the inverter when there is a load connection signal from the load detector; And

And a driving voltage unit connected to the battery and outputting driving voltages for the load detecting unit and the inverter starting unit.

The driving voltage unit may include a switching unit for generating a square wave by switching a DC voltage of a battery, a first rectifying unit for outputting a DC voltage for the load detection unit, a second rectifying unit for outputting a DC voltage for the inverter starting unit, and the It characterized in that it comprises a transformer for transmitting the power of the switching unit to the first rectifier and the second rectifier,

The load detection unit is connected to the output terminal of the first rectifier and the inverter, when the load is connected to the inverter relay unit for the current flow;

And a photo coupler configured to receive a current from the relay unit and transmit a load connection signal to the inverter starting unit.

The inverter rectifies a first power converter converting a DC power of a battery into a square wave, a transformer boosting a square wave of the first power converter, and a boosted square wave of the transformer, and converts the alternating current to output a load. Characterized in that it comprises a power conversion unit,

The inverter starter may include a first controller configured to control a first power changer of the inverter using a microcontroller, a second controller configured to receive a signal from the first controller and to control the second power converter, and the load detector And a power supply unit supplying power of the second rectifying unit to the first control unit when a load connection signal is input from the photocoupler.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic circuit diagram of an inverter starting apparatus according to the present invention, the present invention is an inverter 10 for transferring the power of the battery (1) to the load (2), and a load ( 2) a load detection unit 20 for detecting whether a connection is made, an inverter start unit 30 for receiving a signal from the load detection unit 20 to start the inverter 10, the load detection unit 20 and an inverter start unit It can be seen that it comprises a drive voltage unit 40 for supplying a drive voltage to (30).

The inverter 10 includes a first power converter 11 for converting a DC voltage of the battery 1 into high frequency switching to a square wave, a transformer T2 for boosting a square wave of the first power converter 11, And a second power conversion unit 12 rectifying the square wave boosted by the transformer T2, switching the DC signal again, converting the same into an alternating current of about 230 V, and outputting the same to the load 2.

The driving voltage unit 40 supplies voltages for the load detector 20 and the inverter starter 30. The driving voltage unit 40 is connected to the battery 1, the switching unit 41 for switching the DC voltage to generate a square wave, and the high frequency transformer for stepping down (or step-up) the square wave of the switching unit 41 And a first rectifying unit 42 and a second rectifying unit 43 rectifying the AC voltage transmitted through the high frequency transformer T1 and outputting a DC voltage of about 12V, respectively. The first rectifier 42 supplies a voltage Vb for the load detector 20, and the second rectifier 43 supplies a voltage Va for the inverter starter 30.

The load detection unit 20 includes a relay unit 21 and a photo coupler PT2. The relay unit 21 connects the driving coil 21c, which receives the driving voltage Vb from the first rectifying unit 42, the first rectifying unit 42, and the output terminal of the inverter 10 or the second control unit 32. The first switch 21a, the output terminal of the inverter 10, and the second switch 21b for turning on / off the photo coupler PT2.

The inverter starter 30 receives a signal from the first control unit 31 and the first control unit 31 that controls the switching of the first power converter 11, and switches the second power converter 12. The first control unit 32 receives the load 2 connection signal from the second control unit 32 and the photo coupler PT2 of the load detection unit 20 to control the driving voltage Va of the second rectifying unit 43. It comprises a power supply 33 for transmitting to (31).

Hereinafter, with reference to the circuit diagram of Figure 1 will be described in detail the operation of the inverter 10 starting device of the present invention.

First, when the load 2 is not connected to the output terminal of the inverter 10, since the two terminals of the output terminal of the inverter 10 are in the open state, current does not flow from the first rectifying section 42 to the relay section 21. Otherwise, since the transistor Q1 of the power supply 33 is in an OFF state, no current flows from the second rectifier 43 to the first controller 31. That is, the battery 1 consumes only the minimum current for operating the switching section 41 of the driving voltage section 40.

Hereinafter, in describing the operation of the inverter 10 starting device when the load 2 is connected to the output terminal of the inverter 10, Va denotes an output voltage of the second rectifying portion 43, and Vb denotes an output of the first rectifying portion 42. Output voltage, D is a diode, R is a resistor, Q is a transistor, PT is a photocoupler, and a terminal means a switch terminal of the relay unit 21.

When the load (2) is connected, current flows through Vb-terminal 3-terminal 4-D2-R8-load (2)-terminal 6-terminal 8-R7-PT2 and this current signal is supplied to the power supply through PT2. It will generate a signal indicating that the load 2 is connected.

When load (2) is connected, current flows through Va-R4-Q2 through PT2 and Q2 turns on. Through turned on Q2, current flows through the current path of Va-Q1-R1-Q2 again and Q1 becomes conductive.

When Q1 conducts, the power of Va is supplied to the first control unit 31, the microcontroller inside the first control unit 31 is operated, and the current flows through R3 to maintain the conduction state of Q2 in the microcontroller. To supply.

The microcontroller then supplies current through the path of R5-PT1. In response to the current signal of PT1, the current path of Vb-PT1-R6-Q3 is conducted and Q3 is turned on.

The driving coil 21c of the relay unit 21 is operated through Q3, whereby the terminal 3-terminal 4 contact of the first switch 21a is moved to the terminal 3-terminal 5 contact, and the second switch ( Open terminal 6-8 of 21b). In this manner, the load detection unit 20 is electrically separated from the output terminal of the inverter 10.

On the other hand, the power supply of Vb supplies power to the second control unit 32 through the terminal 3-terminal 5 of the first switch 21a.

Thereafter, the circuit of the battery 1, the first power converter 11, the transformer T2, and the second power converter 12 is controlled by the first controller 31 and the second controller 32. Inverter 10 is operated.

When the load 2 is disconnected from the output terminal of the inverter 10, the current flowing through the output terminal of the inverter 10 becomes 0, and the microcontroller of the first control unit 31 detects the first power conversion unit 11. OFF and cut off the supply current to R3 and R5. As a result, the terminal 3-terminal 5 contact of the relay switch 21 of the first switch 21a moves to the terminal 3-terminal 4 contact, and the terminals 6-8 of the second switch 21b SHOT.

As described above, the inverter 10 starting device of the present invention has a battery (1) and the load (2) is a high-frequency transformer (T1) of the transformer T2 and the drive voltage unit 40 of the inverter 10 and It can be seen that it is separated by the photo coupler (PT1, PT2) and complete insulation.

As described above, the present invention does not have a separate ON / OFF switch for supplying power to the load, and the load detection unit automatically detects whether the load is connected and starts the inverter only when the load is connected, thereby minimizing battery power consumption and economical efficiency. It is excellent and the battery side and load side are insulated by transformer and photocoupler, so there is no risk of electric shock.

In the above description of the present invention with reference to the accompanying drawings for the inverter starting device of a specific circuit diagram, but the present invention can be variously modified and changed by those skilled in the art, such variations and modifications belong to the protection scope of the present invention Should be interpreted as

Claims (5)

An inverter that converts the DC power of the battery into AC power and supplies power to the load; A load detector connected to an output terminal of the inverter and detecting whether the load is connected to the inverter; An inverter starter for automatically starting the inverter when there is a load connection signal from the load detector; And And a driving voltage unit connected to the battery and outputting driving voltages for the load detecting unit and the inverter starting unit. The method of claim 1, The driving voltage unit is a switching unit for generating a square wave by switching the DC voltage of the battery, a first rectifying unit for outputting a DC voltage for the load detector, a second rectifier for outputting a DC voltage for the inverter starter and the switching Inverter starting device characterized in that it comprises a transformer for transmitting the negative power to the first and second rectifier. The method of claim 2, The load detection unit is connected to the output terminal of the first rectifier and the inverter, the relay unit for the current flows when the load is connected to the inverter, And a photo coupler configured to receive a current from the relay unit and transmit a load connection signal to the inverter starter. The method according to any one of claims 1 to 3, The inverter rectifies a first power converter converting a DC power of a battery into a square wave, a transformer boosting a square wave of the first power converter, and a boosted square wave of the transformer, and converts the alternating current to output a load. Inverter starting device comprising a two power conversion unit.       The method of claim 4, wherein The inverter starter may include a first controller configured to control a first power changer of the inverter using a microcontroller, a second controller configured to receive a signal from the first controller and to control the second power converter, and the load detector And a power supply unit for supplying power of the second rectifying unit to the first control unit when a load connection signal is input from the photocoupler.

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