JPH036738B2 - - Google Patents

Description

[Detailed Description of the Invention] Technical Field [0001] The present invention relates to a constant current device, and particularly to a constant current device that supplies a constant current to a load such as a relay amplifier by connecting a plurality of resonant converters in series. This invention relates to improvements in constant current devices.

Prior Art In an analog carrier communication system, a saturable reactor controlled constant current converter is generally used as a remote power supply device for supplying current to a repeater. This is a constant current converter that uses a saturable reactor in a constrained magnetized state and keeps the output current constant by controlling the firing angle of the saturable reactor. Its efficiency is 70% due to the switching losses of the inverter transistor and
The extent is the limit. Output current is 60mA ~ 160mA
It is used as a constant current device with a maximum output voltage of about 7KV.

In the case of long-distance power supply equipment for digital carrier communication systems, the output current reaches 500mA to 2A and the output voltage reaches a maximum of 15KV because the repeater amplifier that serves as the load is highly functional and the system is made redundant.
, and the output power of the device is increased by more than an order of magnitude than in analog carrier communication systems. For this reason, there is a demand for higher output and higher efficiency of the converter that constitutes the power supply device, and in recent years, constant current devices using resonant constant current converters with efficiency of 90% or more have been developed. In the resonant constant current converter, since the collector current of the inverter transistor is a sine wave, switching loss is eliminated, high efficiency can be achieved, and the device can be made smaller.

On the other hand, when a plurality of constant current converters are connected in series to a load and used in consideration of maintainability and redundancy, it is necessary to stabilize the load sharing among the plurality of converters. Therefore, as shown in Figure 1, multiple resonant constant current converters are used.
CONV ₁ ~ CONVn Connect in series to the load,
A constant current device is used in which a load sharing resistor 7 and a diode D are connected in parallel to the output section of each of the resonant constant current converters CONV ₁ to CONVn.

Each resonant constant current converter CONV ₁ ~ CONVn
consists of an inverter circuit 1 that inputs direct current and converts it to alternating current, a resonant circuit 2 that inputs the output of the inverter circuit 1 to a rectifier/smoothing circuit 3, and a resonant circuit 2.
a rectifier/smoothing circuit 3 that rectifies and smoothes the alternating current input through the rectifier/smoothing circuit 3; and a current detection circuit that detects the output current of the rectifier/smoothing circuit 3, outputs a voltage according to the output current, and inputs it to the control circuit 5. 6, a control circuit 5 that compares the voltage input from the current detector 6 with a reference voltage S and outputs a voltage Vc according to the difference, and a control circuit 5 that outputs a control voltage Vc output from the control circuit 5 at a corresponding frequency. The inverter circuit 1 converts and outputs the
A voltage-frequency conversion circuit 4 controls the switching frequency of the circuit, and a resistor 7 and a diode D for load sharing are connected in parallel to the output section of the circuit. The diode D is connected to bypass a resonant constant current converter that has stopped due to a failure or the like and to continue supplying current to the load by another resonant constant current converter.

Next, the operation of each resonant constant current converter will be explained. The inverter circuit 1 is an inverter that operates at the control frequency supplied from the voltage-frequency conversion circuit 4, and converts the DC input E into an AC output at the control frequency. The AC output of the inverter circuit 1 is input to a rectification/smoothing circuit 3 via a resonance circuit 2. The resonant circuit 2 is a series resonant circuit consisting of a chiyoke coil L and a capacitor C, and its resonant frequency is fres. Operating frequency of inverter circuit 1
When the ratio of fsw and fres, fsw/fres, is the duty ratio δ, the AC power input to the rectifier/smoothing circuit 3 depends on the duty ratio δ, and the output characteristics of the rectifier/smoothing circuit 3 in an uncontrolled state are as follows: The result is as shown in FIG.

That is, when the duty ratio δ is 1, the resonant circuit 2
The impedance of becomes 0, and the rectifier/smoothing circuit 3
The output impedance is low and has almost constant voltage characteristics, and as the duty ratio δ becomes smaller, the output impedance becomes higher and becomes saturated at a smaller current value. When the duty ratio δ is 0.5 or less, the output impedance becomes an almost constant finite value. Therefore, the output current can be controlled by changing the duty ratio δ.

The current detector 6 detects the output current of the rectifier/smoothing circuit 3.
Ipf is detected, a voltage proportional to the output current Ipf is output and supplied to the control circuit 5, and the control circuit 5 compares and amplifies the input voltage with a reference voltage S to generate a control voltage signal.
It outputs Vc and supplies it to the voltage-frequency conversion circuit 4. The voltage-frequency conversion circuit 4 converts the control voltage Vc into a corresponding frequency and converts the control voltage Vc into a corresponding frequency to the inverter circuit 1.
Controls the operating frequency fsw. That is, the duty ratio δ is controlled so that the output current Ipf of the resonant constant current converter is constant. Therefore, each of the resonant constant current converters CONV ₁ to CONVn outputs a constant current, and in the controlled state, the output impedance thereof becomes extremely high.

With this configuration, multiple resonant constant current converters can be used.
When CONV ₁ to CONVn are connected in series, if the output current of some resonant constant current converters fluctuates (within constant current control accuracy), load sharing will be disrupted, causing some resonant constant current converters to This will result in an excessive load. In order to prevent this, a load sharing resistor 7 is connected in parallel to the output section of each of the resonant constant current converters CONV ₁ to CONVn. If the resistance value of the load sharing resistor 7 is Rpf, the output impedance of each resonant constant current converter CONV will be a finite value Rpf, making it possible to stabilize load sharing.

Therefore, the impedance of the entire device in which n resonant constant current converters described above are connected in series is n・
Rpf, and the output current vs. output voltage characteristics are as shown in FIG. That is, as the load increases, in other words, as the output voltage V _OUT increases, the output current I _OUT
This has the disadvantage that the constant current characteristics are deteriorated. That is, when the load voltage is V _L , the load current decreases by ΔI and becomes I _L. The amount of decrease ΔI in the load current is expressed as ΔI=V _L /n·Rpf. This decrease △I is calculated by each resonant constant current converter.
The current flows through the load sharing resistor 7 connected to each output section of CONV ₁ to CONVn, and thereby,
A power loss Wr=V _L ² /n ² Rpf is generated. This loss makes traditional constant current devices less efficient and
The disadvantage is that it becomes larger due to heat dissipation measures.

In addition, multiple resonant constant current converters CONV ₁
~CONVn each incorporate a control circuit 5 and a current detection path 6, which is not economical. Furthermore, it is necessary to adjust the output current of each of the plurality of resonant constant current converters by adjusting the reference voltage S of the control circuit 5, and this adjustment requires equalizing the load sharing among the plurality of resonant constant current converters. It must be done while letting people know. Therefore, it takes a considerable amount of time to adjust the output current of the entire device to a predetermined constant current value.

OBJECT OF THE INVENTION The object of the invention is to solve the above-mentioned conventional drawbacks and
Power loss is reduced by not connecting load sharing resistors to multiple resonant constant current converters connected in series, and common control is achieved without providing a control circuit or current detector for each resonant constant current converter. Therefore, by outputting a constant current, it is possible to prevent deterioration of constant current characteristics due to an increase in load, downsize the device,
High efficiency and precision are possible, and
It is an object of the present invention to provide a constant current device that can easily adjust the output current in a short time.

Configuration of the Invention The constant current device of the present invention includes an inverter circuit that converts and outputs DC input to AC, a resonant circuit connected to the output of this inverter circuit, and an output of the inverter circuit that is inputted via this resonant circuit. A plurality of resonant constant current converters are connected in series, each having a rectifier/smoothing circuit that rectifies and smoothes the output signal, and a conversion circuit that converts the control signal input from the control circuit to control the operating frequency of the inverter circuit. A current detector is connected in series between the plurality of resonant constant current converters and the load, and the detection output of this current detector is compared with a reference voltage to determine the control current. In a constant current device equipped with a control circuit that outputs a common output to each conversion circuit, the conversion circuit is a voltage-frequency conversion circuit that converts a control voltage signal to a corresponding frequency, and the control circuit has an output A current-voltage conversion circuit that converts and outputs a control current into a control voltage is connected, and the output of this current-voltage conversion circuit is applied in parallel to each conversion circuit of the resonant constant current converter. .

Embodiments of the Invention Next, the present invention will be described in detail with reference to the drawings.

FIG. 4 is a block diagram showing a first embodiment of the present invention. That is, a plurality of resonant constant current converters CONV ₁ ′ to CONVn′ are connected in series, and a current is supplied to the load 9 through the common current detector 6 . And each resonant constant current converter
_CONV1 ' to CONVn' each include an inverter circuit 1, a resonant circuit 2, a rectifier/smoothing circuit 3, and a voltage-frequency conversion circuit 4 for controlling the operating frequency of the inverter circuit 1. The output frequency of the voltage-frequency conversion circuit 4 is controlled by a current-voltage conversion circuit 10, which will be described later. Therefore, each resonant constant current converter does not include a control circuit and a current detector for controlling the voltage-frequency conversion circuit 4, unlike the conventional example shown in FIG. In addition, each resonant type constant current converter CONV ₁ ′~
The diodes D connected to each output section of CONVn' are for bypass when the resonant constant current converter is stopped, and no resistor for load sharing is connected as in the conventional case.

The current detector 6 detects the output current I _OUT of the entire device, outputs a voltage proportional to the output current, and inputs the voltage to the control circuit CONT. The control circuit CONT is
A built-in comparator amplifier A compares and amplifies the input voltage with a reference voltage S, and the output of the comparator amplifier A is input to the base of the transistor TR via a resistor _R1 . The emitter of the transistor TR is grounded through a resistor _R2 , and the collector is connected to the negative pole of the power source E through the input winding of the current-voltage conversion circuit 10.
The positive terminal of power supply E is grounded. Therefore, the control circuit
From CONT, a control current Ic corresponding to the difference between the detection voltage of the current detector 6 and the reference voltage S flows into the current-voltage conversion circuit 10. Current-voltage conversion circuit 10
converts the control current Ic into a voltage and obtains the control voltage Vc
output, and the plurality of resonant constant current converters
It is supplied to each voltage-frequency conversion circuit 4 of _CONV1 ' to CONVn'. For the current-voltage conversion circuit 10, a magnetic amplifier using a saturable reactor, a current-voltage converter using a photocoupler, or the like can be used.

As described above, the voltage-frequency conversion circuit 4 of each resonant constant current converter controls the operating frequency of the inverter circuit 1 with a frequency corresponding to the control voltage Vc output from the current-voltage conversion circuit 10. That is, in this embodiment, the operating frequency of each inverter circuit 1 of a plurality of resonant constant current converters _CONV1 ' to CONVn' is controlled by a common control circuit.
Commonly controlled by CONT and current-voltage conversion circuit 10, the duty ratio δ of each resonant constant current converter is controlled so that the output current _IOUT of the entire device becomes a predetermined constant current. Therefore, the output impedance of this device has a very high value, and it is effective in preventing the conventional phenomenon in which the output current decreases as the load voltage increases.

On the other hand, the output characteristics of each resonant constant current converter of this device are the same as those shown in FIG. That is, it has a certain finite value of output impedance. Therefore, this output impedance provides the same effect as a conventional load sharing resistor, and the load sharing is balanced by the output impedance. This output impedance changes depending on the duty ratio δ, but if the resonant frequency of the resonant circuit 2 and the conversion ratio of the voltage-frequency conversion circuit 4 of each resonant type constant current converter are set equal, the common control voltage
The duty ratio δ of each resonant constant current converter controlled by Vc is equal, so the output impedance is also equal, and the load is shared equally. That is, it is possible to equally share the load of each resonant constant current converter without connecting a load sharing resistor as in the conventional case. The output voltage Vpf of each resonant constant current converter is 1/n of the output voltage V _OUT of the entire device. Note that the duty ratio δ is approximately
In the range below 0.5, the output impedance of the resonant constant current converter is an almost constant finite value (the slopes are parallel in Figure 2), so the range of change in duty ratio δ is 0 to 0.5. It is desirable to do so for stable operation.

This embodiment does not use a resistor for load sharing as in the conventional case, so power consumption corresponding to the power loss is reduced and efficiency is improved. Further, there is no need to take measures against the heat generation of the load sharing resistor, and the device can be downsized. In addition, the output impedance of the entire device is extremely high, which prevents a decrease in output current due to an increase in load, making it possible to obtain extremely accurate constant current characteristics. In addition, the control circuit
Since a plurality of resonant constant current converters are commonly controlled by the CONT and the current-voltage conversion circuit 10, the number of parts is reduced compared to the conventional method, which is economical. Furthermore, the output current of this device is adjusted by adjusting the reference voltage S of the control circuit CONT, which eliminates the need to make adjustments while equalizing the load sharing with each resonant constant current converter, as in the conventional case. It will be released. Therefore, the time required to adjust the output current can be significantly reduced.

In addition, multiple resonant constant current converters
One of CONV ₁ ' to CONVn' has failed, and in order to replace that resonant constant current converter with a good one,
When removed from the device, it is bypassed by the diode D connected in parallel to its output, and can continue to supply constant current to the load by another normal resonant constant current converter. can.

FIG. 5 is a block diagram showing a second embodiment of the invention. In this case, in the collector circuit of the transistor TR of the control circuit CONT shown in FIG.
A power supply e insulated from the ground is inserted in series, and the current-voltage conversion circuit 12 is constituted by a resistor R having one end connected to the ground and the other end connected to the positive terminal of the power supply e. The rest is the same as the embodiment shown in FIG. 4, and the same numbers and symbols indicate the same components. Now, if the input impedance of the voltage-frequency conversion circuit 4 of each resonant constant current converter is r ₁ and the resistance value r ₂ of the resistor R is set as r ₂ 〓r ₁ , the control voltage Vc is almost
Ic・r ₂ , and the voltage is proportional to the control current Ic. This control voltage Vc is supplied to the voltage-frequency conversion circuit 4 of each resonant constant current converter, and each resonant constant current converter is connected to the control circuit CONT.
are commonly controlled by the terminals to supply a constant current to the load. The current-voltage conversion circuit 12 is composed only of a resistor R, and the power supply e of the control circuit CONT is a rectifier and smoothing circuit by adding a winding to the oscillator (Royer oscillator, Jensen oscillator, etc.) for the power supply circuit of the comparison amplifier A. It is possible to configure by adding . Therefore, this embodiment is more economical than the first embodiment and can provide similar functions and effects.

FIG. 6 is a block diagram showing a third embodiment of the present invention, in which a plurality of current detectors 6
₁ to 6m are connected in series, their respective outputs are input to a plurality of control circuits CONT ₁ to CONTm, and the outputs of the plurality of control circuits CONT are connected in parallel, so that the control current Ic ₁ to Icm is The added control current Ic is caused to flow into the current-voltage conversion circuit 12. The configuration of each control circuit CONT is the same as the second embodiment shown in FIG.
The current-voltage conversion circuit 12 is composed of a resistor R. The current-voltage conversion circuit 12 converts the combined control current Ic into a voltage, outputs the control voltage Vc, and controls the duty ratio δ of each resonant constant current converter CONV. Therefore, Vc≒Ic・r ₂ =(Ic ₁ +Ic ₂ +...+Icm)・r ₂ . If one control circuit fails, the remaining control circuits can supply control current to maintain the output current at a predetermined value. That is,
Through redundant design, it is possible to reduce the failure rate of the control system to an extremely small value of several FIT or less. Regarding other effects, please refer to the above-mentioned first and second
This is similar to the embodiment. Incidentally, since the control circuits of the first and second embodiments both output a control current, if a plurality of control circuits are provided and their outputs are connected in parallel, it is easy to perform the process shown in FIG. (It is not easy to combine multiple control voltages).

Effects of the Invention As described above, the present invention provides a current detector that connects a plurality of resonant constant current converters in series to supply current to a load and detects the output current of the entire device; a control circuit that compares and amplifies the output voltage of the converter with a reference voltage and outputs a control current; and a control circuit that converts the control current output from the control circuit into a control voltage and outputs the voltage of the plurality of resonant constant current converters.
A current-to-voltage conversion circuit is provided to supply the frequency conversion circuit, and the duty ratio of the plurality of resonant constant current converters is commonly controlled so that the output current of the entire device becomes a constant value. Prevents the phenomenon that the output current decreases as the load increases,
Can supply high precision constant current. Moreover, instead of connecting a load-sharing resistor to the output of each resonant constant current converter as in the past, the configuration utilizes the unique output impedance characteristics of the resonant constant current converter to equalize the load distribution. Therefore, it is possible to reduce the loss that conventionally occurred in the load sharing resistor, reduce power consumption, and provide a compact constant current device with high efficiency and no need for measures against heat generation.

Further, since the present invention has a configuration in which the duty ratio of a plurality of resonant constant current converters is commonly controlled, each resonant constant current converter does not need to have a built-in current detector and control circuit for control. It is possible to reduce the number of parts as a whole and is economical. Additionally, this device allows for easy adjustment of the output current, eliminating the need for the complicated work of adjusting each resonant constant current converter while equalizing the load sharing among multiple resonant constant current converters. It can be adjusted in a single time.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an example of a conventional constant current device, and FIG. 2 is a diagram showing the output characteristics of each of the conventional resonant constant current converters in an uncontrolled state.
FIG. 3 is a diagram showing the output characteristics of the entire device in the control state of the conventional example, and FIGS. 4 to 6 are block diagrams showing first to third embodiments of the present invention, respectively. In the figure, 1: inverter circuit, 2: resonant circuit, 3: rectifier/smoothing circuit, 4: voltage-frequency conversion circuit, 5: control circuit, 6,6 ₁ to 6m: current detection circuit, 7: load sharing circuit. Resistance, 9: Load, 10:
Current-voltage conversion circuit, 12: Current-voltage conversion circuit, CONV ₁ ~ CONVn, CONV ₁ ′ ~ CONVn′: Resonant constant current converter, CONT, CONT ₁ ~
CONTm: Control circuit, E, e: Power supply, D: Diode.

Claims (1)

[Scope of Claims] 1. An inverter circuit that converts DC input into AC, a resonant circuit connected to the output of this inverter circuit, and rectifies and smoothes the output of the inverter circuit that is input via this resonant circuit. A plurality of resonant constant current converters are connected in series, each of which includes a rectifier/smoothing circuit that outputs the inverter circuit, and a conversion circuit that converts the control signal input from the control circuit to control the operating frequency of the inverter circuit. A current detector is inserted in series between a plurality of resonant constant current converters and the load, and the detection output of this current detector is compared with a reference voltage to determine the control current from each conversion circuit of the resonant constant current converter. In the constant current device, the conversion circuit is a voltage-frequency conversion circuit that converts a control voltage signal into a corresponding frequency, and the control circuit includes a control circuit that outputs a control current A constant current device, characterized in that a current-voltage conversion circuit is connected to convert and output a control voltage into a control voltage, and the output of the current-voltage conversion circuit is applied in parallel to each conversion circuit of the resonant constant current converter.