JPH01148065A - Dc-dc converter - Google Patents

Abstract

PURPOSE:To perform a good starting at the time of switching a power ON and to make it unnecessary to use elements having characteristic more excellent than required by turning OFF a Zener diode and preventing a protection circuit from operating for a specified period at the time of switching the power ON. CONSTITUTION:When a power switch 2 is turned ON, a transistor 16 is turned ON for a specified period of time determined by resistors 18, 19 and a capacitor 20. During the period of time, a parallel circuit of resistors 14 and 17 is connected between both ends of a load current sensing capacitor 13, and accordingly the resistance value of the resistor 14 is reduced by half. Therefore, voltage at a node of the resistor 14 and a Zener diode during that period of time becomes smaller than a set voltage under the influence of an internal impedance of a power source viewed from the capacitor 13. Further the Zener diode 15 is not turned ON, and the protection circuit does not operate. Therefore, even if a load current increases during the starting, the protection circuit does not operate and it is possible to start a DC-DC converter.

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention is applicable to D used as a power supply circuit for various electronic devices.
Regarding a C-DC converter.

[Summary of the invention]

The present invention can be used as a power supply circuit for various electronic devices.
Regarding the C-DC converter, the first direct current voltage is supplied to the collector of the switching transistor through the primary winding of the transformer, and a feedback circuit is provided between the collector and the base of the switching transistor to control the switching. The transistor is oscillated to obtain a second DC voltage from the secondary winding of this transformer, the load current is detected, a voltage corresponding to this detected current is obtained across the resistor, and this voltage is applied to the Zener diode. 1) In a C-DC converter, when the power is turned on, the resistance of this resistor is By lowering the value and turning off this Zener diode for a predetermined time,
This ensures a good start-up when the power is turned on, and eliminates the need to use elements with more characteristics than necessary.

(Prior art) D
A C-DC converter as shown in FIG. 4 has been proposed. In this Figure 4, 11) indicates a battery that constitutes the DC power supply, and the positive terminal of this battery +1) is connected to the power switch (2) and the primary winding (3a) of the current feedback transformer (3).
) and a primary winding (4a) of a transformer (4) to the collector of an npn transistor (5) constituting a switching transistor, and the negative electrode of this battery (1) is grounded. Also, the secondary winding (3b) of the current feedback transformer (3)
) is connected to the base of the transistor (5) through a series circuit of a capacitor (6) and a resistor (7) forming a feedback circuit, and the other end of this secondary winding (3b) is grounded. The emitter of transistor (5) is grounded. In this case, the transformer (4), the current feedback transformer (3), the capacitor (61) and the resistor (7) constitute a positive feedback circuit between the collector and base of the transistor (5), and this transistor (5) (4).

An oscillation circuit that oscillates at a frequency determined by a current feedback transformer (1 port), a capacitor (6), etc. is constructed. The primary winding (3a) of this power switch (2) and current feedback transformer (3)
) is connected to the base of this transistor (5) via a starting resistor (8) having a relatively large resistance value. In addition, one end of the secondary winding (4b) of the transformer (4) is connected to a diode (9) and a smoothing capacitor (
10) through the series circuit, and this secondary winding (4b
) to ground the other end. In this case this capacitor (lO)
A DC voltage corresponding to the winding ratio between the primary winding (4a) and the secondary winding (4b) of the transformer (4) is obtained between both ends of the transformer (4). The connection point between the diode (9) and the capacitor (10) is grounded via the electrode (to).

In addition, the negative end of the secondary winding (3b) of the current feedback transformer (3) is connected to the cathode of the negative rectifier diode (12),
The anode of this diode (12) is connected to the capacitor (13).
) to earth. In this case this capacitor (13)
A negative current corresponding to the load current is accumulated in the capacitor (13), and a negative DC voltage having a magnitude corresponding to the load current with the ground potential as a reference voltage is obtained across the capacitor (13). The connection point between this diode (12) and capacitor (13) is a resistor! (14) to ground. In this case, a negative DC voltage of a magnitude corresponding to the load current with the voltage across the capacitor (13), that is, the ground potential as a reference voltage, is obtained between both ends of the resistor (14). The connection point of this capacitor (13) and resistor (14) is connected to the base of the transistor (5) via a Zener diode (15) having a Zener voltage of, for example, 5.6V. In this case the resistor (
When the voltage across the transistor (14) becomes a Zener voltage, for example, 5.6 V or higher, the Zener diode (15) is turned on and this transistor (5) is turned off, thereby protecting this transistor (5). In the example shown in FIG. 4, when the wire sonar (2) is turned on, the switching transistor (5) becomes a transformer (4).

(3) and the capacitor (6), etc., and the peak value of the frequency corresponding to this oscillation is determined by the DC voltage of the battery (1).The pulse is applied to the primary winding (4a) of the transformer (4). This is electromagnetically induced in this secondary winding (4b), and this transformer (
4) A DC voltage is obtained according to the turns ratio between the primary winding (4a) and the secondary winding (4b). Also this transformer (4)
The current corresponding to the load current on the secondary side of the transformer (4) is
A current corresponding to the magnitude of the load current flows through the secondary winding (4a) and is electromagnetically induced into the secondary winding (3b) via the primary winding (3a) of the current feedback transformer (3). (1
3), a negative voltage corresponding to this load current is accumulated, and a detection voltage e1 corresponding to this load current is obtained at the connection point between the resistor (14) and the Zener diode (15), and this load current is For example, when the voltage is 5A or less, this detection voltage is less than the Zener voltage of the Zener diode (15).For example, this detection voltage e1 is -5.6V or more, and this Zener diode (15) is off and this protection circuit is not affected. When this load current becomes, for example, 5A or more, the detected voltage e1 at the connection point of this resistor (14) and Zener diode (I5) becomes, for example, -5.6V or less, and this Zener diode (15) turns on. The base of the switching transistor (5) is set to a negative voltage to turn off the switching transistor (5), stopping oscillation and protecting the transistor (5) and the like.

[Problem that the invention seeks to solve]

However, in the conventional DC-DC converter as shown in Fig. 1, when the power switch (2) is turned on, the capacitor (10) etc. are not equally charged, so the load current reaches its maximum, resulting in a large current. flows, and at this time, even if there is no equivalent fault, the Zener diode (15) turns on and the base of the switching transistor (5) is pulled in the direction of turning off, making startup impossible or delaying startup. There was an inconvenience. In addition, in order to ensure startup when the power switch (2) is turned on, the overcurrent set point is set at a high point (large current), and an element such as a switching transistor with sufficiently large current capacity and other characteristics than necessary is used. was.

In view of this, it is an object of the present invention to ensure a good start-up when the power is turned on, and to eliminate the need to use elements with characteristics of d or higher.

(Means for Solving the Problems) The DC-DC converter of the present invention, for example, as shown in FIG. This switching transistor (
A feedback circuit (41, (3) is connected between the collector and base of
), (6), and (7) are provided to make this switching transistor (5) oscillate, and obtain a second DC voltage from the secondary winding (4b) of this transformer (4), as well as a negative (ti) This current is detected, a voltage corresponding to this detected current is obtained across the resistor (14), and this voltage is supplied to the base of this switching transistor (5) via the Zener diode (15). 5) In a DC-DC converter equipped with a protection circuit that controls and protects the base voltage, when the power is turned on, the resistance value of this resistor (14) is lowered, and this Zener diode (15) is It is designed to turn off for a predetermined period.

C effect] According to the present invention, the Zener diode is turned on for a predetermined period when the power is turned on.
)'' (15) is turned off and the protection circuit is disabled, so even if a large negative current flows when the power is turned on, it will not be possible to start up or there will be no delay in start-up, allowing for a good start-up. Therefore, there is no need to use elements with more characteristics than necessary to ensure startup, and the predetermined period during which this protection circuit is inactive is only the time required for startup, and is relatively short, allowing devices such as the switching transistor (5) to will not be destroyed.

〔Example〕

Hereinafter, one embodiment of the DC-1)C converter of the present invention will be explained with reference to FIG. In FIG. 1, parts corresponding to those in FIG. 4 are designated by the same reference numerals, and detailed explanation thereof will be omitted.

In this example, the positive terminal of the battery (11) constituting the DC power supply is connected to the power switch (2), the primary winding (3a) of the current feedback transformer (3), and the primary winding (4a) of the transformer (4). The negative electrode of this battery (1) is connected to the collector of the npn transistor (5) constituting the switching transistor through the terminal, and the negative electrode of this battery (1) is grounded.Also, one end of the secondary winding (3b) of the current feedback transformer (3) is Capacitors (6
) and a resistor (7) through a series circuit of the transistor (
5), the other end of this secondary winding (3b) is grounded, and the emitter of the transistor (5) is grounded. In this case transformer (4), current feedback transformer (3)
, the capacitor (6) and the resistor (7) are transistors (
5) constitute a positive feedback circuit between the collector and the base,
This transistor (5) constitutes an oscillation circuit that oscillates at a frequency determined by the transformer X (4), @current feedback transformer (3), capacitor (6), etc. This *gap switch (2)
The connection point of the primary winding (3a) of the current feedback transformer (3) is connected to the base of this transistor (5) via a starting resistor (8) with a relatively large resistance value.

In addition, one end of the secondary winding (4b) of the transformer (4) is connected to a diode (9) that constitutes a rectifier circuit and a flat capacitor (
10) through the series circuit, and this secondary winding (4b
) to ground the other end. In this case this capacitor (lO)
A DC voltage corresponding to the winding ratio between the primary winding (4a) and the secondary winding (4b) of the transformer (4) is obtained between both ends of the transformer (4). The connection point between the diode (9) and the capacitor (10) is grounded via a load (11).

In addition, the negative end of the secondary winding (3b) of the current feedback transformer (3) is connected to the cathode of the negative rectifier diode (12),
The anode of this diode (12) is connected to the capacitor (13).
) to earth. In this case this capacitor (13)
A negative load corresponding to the load current is accumulated in the capacitor (13), and a negative DC voltage having a magnitude corresponding to the load current with the ground potential as a reference voltage is obtained across the capacitor (13). The connection point between this diode (12) and the capacitor (13) is grounded via a resistor "a (14). In this case, the voltage across the capacitor (13), that is, the ground A negative DC voltage of a magnitude corresponding to the load current with the potential as the reference voltage can be obtained.This capacitor (13
) and the resistor (14) are connected to the base of the transistor (5) via a Zener diode (15) having a Zener voltage of, for example, 5.6 . In this case, the voltage across the resistor (14) is the Zener voltage, for example 5.6
When this happens, the Zener diode (15) turns on and the transistor (5) turns off, stopping oscillation and protecting the transistor (5). These are constructed in the same manner as in FIG.

In addition, in this example, the connection point of the diode (12) and the capacitor (13) is connected to the emitter of the npn transistor (16), and the collector of this transistor (16) is connected to the same low resistance as the resistor 1 (14). value resistor (17)
The connection point of this diode (12) and capacitor (13) is connected to the base of this transistor (16) through a resistor II (1B), and the base of this transistor (16) is connected to the ground through a resistor (1B). 19) and capacitor (
Ground through the series circuit of resistors (18) and (19), and connect a capacitor (20) in parallel between both ends of the series circuit of resistors (18) and (19).
) is connected to the discharge diode (21).

In this case, resistor (1B) (19) and capacitor (
20) is determined by the time used to start up this DC-DC converter.

Since this example is configured as described above, the battery switch (2
) is turned on, the voltage between the base and emitter of the transistor (16) becomes as shown in Figure 2A, and this transistor (16) is turned on for a predetermined time determined by the resistors (18), (19) and the capacitor (20). TO turns on,
During this time, a parallel circuit of resistors (14) and (17) is connected between both ends of the capacitor (13) for detecting the load current, so the resistance value of the resistor (14) becomes, for example, □. . Therefore, the voltage Vo at the connection point between the resistor (14) and the Zener diode (15) during this period becomes smaller than the set voltage VL due to the relationship with the internal impedance of the power supply as seen from the capacitor (13), as shown in FIG. 2B. The Zener diode (15) is not turned on and the protection circuit does not operate. Therefore, even if the load current becomes thick during this startup, this protection circuit will not operate and this DC-DC converter can be started. . In this case, even if the load (11) is in a stone fault state, this start-up time To is relatively short, so it will not destroy elements such as the transistor (5). Therefore, when the power switch (2) is turned on, the switching transistor (5) oscillates at a frequency determined by the transformer (4), (3) and the capacitor (61, etc.), and the peak value of the frequency corresponding to this oscillation is the pulse determined by the DC voltage of the battery (11). Next winding (4a
), which is electromagnetically induced in this secondary winding (4b), and the primary winding (4a) and secondary winding (4b)' of this transformer (4) are connected to both ends of the capacitor (10). A DC voltage can be obtained according to the turns ratio. Moreover, after this start-up time To, a current corresponding to the load current on the secondary side of this transformer (4) flows to the primary winding (4a) of the transformer (4), and a current corresponding to the magnitude of this load current flows into the primary winding (4a) of the transformer (4). The current is electromagnetically induced to the secondary winding (3b) through the primary winding (3a) of the current feedback transformer (3), and a negative 14
The grapes are accumulated and the resistor (14) and Zener diode (
15) at the connection point with the detection voltage e1 according to this load current.
is obtained, and when this load current is, for example, 5 A or less, this detection voltage is below the Zener voltage of the Zener diode (15), for example, this detection voltage e1 is -5.6 V or above,
This Zener diode (15) is off and this protection circuit does not work, but when this load current becomes, for example, 5A or more, this resistor (14) and Zener diode (
The detected voltage e1 at the connection point of 15) becomes, for example, -5.6V or less, and this Zener diode (15) turns on, making the base of this switching transistor (5) a negative voltage, turning off the switching transistor (5), and turning off this switching transistor (5). Oscillation stops and this transistor (5) etc. are protected.

Therefore, according to this example, even if a large load current flows when the power is turned on, there is no inconvenience that startup becomes impossible or startup is delayed, and startup can be performed satisfactorily. For this reason, there is no need to use elements with characteristics more than necessary to ensure this activation.

Further, FIG. 3 shows another embodiment of the DC-DCC type of the present invention. This figure 3 shows the current feedback transformer (3) in figure 1.
The tertiary winding (4c) for feedback is connected to the transformer (4) without providing
One end of this tertiary winding (4c) is connected to the base of the transistor (5) via a series circuit of a feedback capacitor (6) and a resistor (7), and this tertiary winding (4c) is 4
One end of C) is grounded through a series circuit of a negative rectifying diode (12) and a capacitor (13), and the other end of this tertiary winding (4c) is grounded. The rest of the structure is the same as in FIG. 1. In this example in Fig. 3 as well, the tertiary winding (4C) of the transformer (4) is the primary winding (4a) and the secondary winding (
4b), it is easy to understand that the same effects as in FIG. 1 can be obtained.

It goes without saying that the invention of the face tree is not limited to the above-described embodiments, and can take various other configurations without departing from the gist of the invention.

〔Effect of the invention〕

According to the present invention, 1! #There is an advantage that a good start-up can be performed at the time of input, and there is no need to use elements with characteristics higher than necessary.

[Brief explanation of the drawing]

Fig. 1 is a connection diagram showing one embodiment of the DC-DCC type of the present invention, Fig. 2 is a diagram for explaining Fig. 1, and Fig. 3 is a connection diagram showing another embodiment of the present invention. Figure 4 shows the conventional DC
- It is a connection diagram showing an example of a DC converter. (1) is a battery, (2) is a power switch, (3) is a current feedback transformer, (4) is a transformer, (5) is a switching transistor, (6), (10), (13)
and (20) are capacitors, (7) and (14) respectively.
, (17), (18) and (19) are resistors respectively, (9) and (12) are diodes respectively, (11
) is a load, (15) is a Zener diode, and (16) is a transistor.

Claims (1)

[Claims] A first DC voltage is supplied to the collector of the switching transistor via the primary winding of the transformer, and a feedback circuit is provided between the collector and the base of the switching transistor to cause the switching transistor to oscillate, and A second DC voltage is obtained from the secondary winding of the transformer, the load current is detected, a voltage corresponding to the detected current is obtained across the resistor, and the voltage is applied to the switching transistor via the Zener diode. DC-D equipped with a protection circuit configured to control and protect the base voltage of the switching transistor by supplying it to the base of the switching transistor.
1. A DC-DC converter, characterized in that when power is turned on, the resistance value of the resistor is lowered and the Zener diode is turned off for a predetermined period.