CN201307830Y - Frequency conversion circuit - Google Patents

Abstract

The utility model discloses a frequency conversion circuit. The circuit comprises a rectifying circuit, a filter circuit, a low-frequency square wave generator; the rectifying circuit is used for converting a received high-frequency AC signal into a DC signal; the filter circuit is connected with the rectifying circuit; the low-frequency square wave generator is connected with the filter circuit and is used for generating a low-frequency square wave AC signal; the low-frequency square wave generator comprises a timer, two capacities C4 and C5 as well as two resistances R4 and R5, wherein the capacities C4 and C5 are connected between the timer and the filter circuit; the resistances R4 and R5 are connected with each other in series; the capacity C5 is connected with the resistance R4; and the R5 is connected with the timer. In the utility model, the high-frequency AC signal can be converted into the appropriate low-frequency square wave AC signal by the frequency conversion circuit, thereby driving a device to work and widening the application scope of an electronic transformer.

Description

Frequency changer circuit

Technical field

The utility model relates to a kind of frequency changer circuit, relates in particular to a kind of frequency changer circuit that is used for electronics fire ox.

Background technology

In the prior art, along with the rise of copper material price and the proposition of low-power consumption requirement, the power supply of Switching Power Supply, electronics fire ox and so on has the progressively trend of instead of linear power supply.Yet, in some application,, can there be such power supply and the unmatched situation of device if directly use such power source drive device, causing can not drive unit work.For example, because electronics fire ox output signal is more than 20 KHz and the high frequency square wave AC signal of not voltage stabilizing, and the working range of alternating current machine mostly is at the 50-60 hertz in the prior art, therefore directly drives alternating current machine with electronics fire ox, and alternating current machine can't rotate.Thereby need increase extra frequency changer circuit.

The utility model content

The utility model embodiment technical problem to be solved is, a kind of frequency changer circuit is provided, and can drive those after making electronics fire ox by this frequency changer circuit originally can not drive unit.

In order to solve the problems of the technologies described above, the utility model embodiment provides a kind of frequency changer circuit, comprising:

The high frequency ac signal that receives is converted into the rectification circuit of direct current signal;

The filter circuit that is connected with described rectification circuit;

Be connected with described filter circuit, to produce the low-frequency square-wave generator of low-frequency square-wave AC signal, described low-frequency square-wave transmitter comprises timer, two capacitor C 4, C5 and two resistance R 4, R5, wherein, described capacitor C 4, C5 all are connected between described timer and the filter circuit, described resistance R 4 is connected with R5, and described capacitor C 5 links to each other with resistance R 4, and described resistance R 5 links to each other with described timer.

Implement the utility model embodiment, have following beneficial effect:

The signal of electronics fire ox output passes through current rectifying and wave filtering circuit after the low-frequency square-wave generator produces suitable low-frequency square-wave generation signal, thereby can carry out work by drive unit, has widened the range of application of electronics fire ox.

Description of drawings

Fig. 1 is the circuit theory schematic diagram of the frequency changer circuit of the utility model embodiment one;

Fig. 2 is the pin schematic diagram of the timer 556 shown in Fig. 1;

Fig. 3 is the internal structure schematic diagram of timer 556 shown in Figure 2;

Fig. 4 is the circuit theory schematic diagram of the frequency changer circuit of the utility model embodiment two;

Fig. 5 is the circuit structure diagram according to first embodiment shown in Figure 3;

Fig. 6 is the circuit structure diagram according to second embodiment shown in Figure 3.

Embodiment

Below in conjunction with accompanying drawing the utility model is described in further detail.

Fig. 1 is the circuit theory schematic diagram of the frequency changer circuit of the utility model embodiment one.With reference to figure 1, described frequency changer circuit comprises rectification circuit 1, filter circuit 2 and low-frequency square-wave generator 3.

Wherein, rectification circuit 1 high frequency ac signal that is used for receiving is converted into direct current signal.Described rectification circuit 1 is formed full-wave bridge rectifier circuit by 4 diode D1-D4, and the negative pole of the positive pole of diode D1 and diode D3 is connected the positive pole of electronics fire ox output; The negative pole of the positive pole of diode D2 and diode D4 is connected the negative pole (ground connection) of electronics fire ox output; Diode D1 series diode D2, and the negative pole of diode D1 is connected with the negative pole of diode D2; Diode D3 series diode D4, and the positive pole of diode D3 is connected with the positive pole of diode D4.

Voltage behind over commutation remains the direct current of " pulsation ", in order to reduce fluctuation, thereby needs to increase filter circuit after rectification.Described filter circuit 2 is connected with described rectification circuit, is used for described direct current signal is carried out filtering.The filter circuit 2 of the utility model embodiment is made up of two capacitor C 1, C2 and a resistance R 2, wherein, capacitor C 2 is connected with resistance R 2, capacitor C 1 is parallel on the circuit of capacitor C 2 and resistance R 1 series connection, one end of capacitor C 1 is connected to an end of capacitor C 2, and the other end of capacitor C 1 is connected to an end of resistance R 2.The input of filter circuit 2 is connected with the output of rectification circuit 1, is specially: the tie point that capacitor C 1 is connected with capacitor C 2 is connected to the tie point that the diode D1 in the described rectification circuit 1 is connected with diode D2; The tie point that capacitor C 1 is connected with resistance R 2 is connected to the tie point that the diode D3 in the described rectification circuit 1 is connected with diode D4.

The low-frequency square-wave generator 3 of the utility model embodiment is connected with described filter circuit 2, is used to produce the low-frequency square-wave AC signal.Described low-frequency square-wave generator 3 is made up of timer 556, two electric capacity (C4-C5) and two resistance (R4-R5).Fig. 2 is the pin schematic diagram of the timer 556 shown in Fig. 1.With reference to figure 2, timer 556 has 16 pins, wherein, pin 2 is a threshold value end 1 (Threshold) 1, and pin 3 is control voltage end 1 (Control Voltage), and pin 4 is a reset terminal (Reset) 1, pin 5 is output 1 (Outputl), pin 6 is trigger end 1 (Trigger), and pin 7 is earth terminal (GND), and pin 8 is a trigger end 2, pin 9 is output 2 (Output), pin 10 is a reset terminal 2, and pin 12 is a threshold value end 2, and pin 14 is power end (VCC).

One end of described capacitor C 4 connects the pin 3 of described timer 556, the pin 7 of the other end of described capacitor C 4 and described timer 556 is connected ground jointly, the pin 4 of described timer 556, pin 10 and pin 14 are connected to the positive pole of the output of described filter circuit jointly, the pin 5 order series resistance R5 and the resistance R 4 of described timer 556, one end of described capacitor C 5 is connected respectively to resistance R 4, the pin 2 of described timer 556 and pin 6, the other end of described capacitor C 5 connects ground, the pin 5 of described timer 556, pin 8 is connected with pin 12, its tie point is first output of described low-frequency square-wave generator 3, and the pin 9 of described timer 556 is second output of described low-frequency square-wave generator 3.

Fig. 3 is the internal structure schematic diagram of timer 556 shown in Figure 2.With reference to figure 1, Fig. 2 and Fig. 3, the voltage of energising moment capacitor C 5 is close to 0V, and the R end of the inside rest-set flip-flop of timer 556 is 0, and the S end is 1, and the Q end is output as 1, gives capacitor C 5 chargings by resistance R 5 and R4.When capacitor C 5 both end voltage were greater than 1/3 VCC after the short time, the R end was 0, and the S end is 0, and the constant continuation of Q end output gives capacitor C 5 chargings.When capacitor C 5 both end voltage during greater than 2/3 VCC, the R end is 1, and the S end is 0, and the Q end is output as 0, and by R5, R4 discharges to C5.C5 discharges, and the R end was 0 when both end voltage was less than 1/3 VCC after a short time, and the S end is 1, the rest-set flip-flop upset, and Q end output high potential begins that charging begins following one-period to C5.The pin 5 output square waves of timer are input to pin 6, and pin 8 is through another trigger paraphase, the square wave that pin 9 outputs and pin 5 are anti-phase.

The utility model embodiment is used for the situation of low-power load, therefore can directly drive by timer 556.

Fig. 4 is the circuit theory schematic diagram of the frequency changer circuit of the utility model embodiment two.With reference to figure 4, described frequency changer circuit comprises rectification circuit 1, filter circuit 2, low-frequency square-wave generator 3 and bridge inverter main circuit 4.

Described rectification circuit 1 is formed bridge rectifier by 4 diode D1-D4, and the high frequency ac signal that is used for receiving is converted into direct current signal.Described filter circuit 2 is made up of two capacitor C 1, C2 and resistance R 2, is connected with described rectification circuit 1, is used for described direct current signal is carried out filtering.Voltage behind over commutation remains the direct current of " pulsation ", in order to reduce fluctuation, thereby needs to increase filter circuit after rectification.

Described low-frequency square-wave generator 3, be connected with described filter circuit 2, be used to produce the low-frequency square-wave AC signal, described low-frequency square-wave generator is by timer 556, two electric capacity (C4-C5) and two resistance (R4-R5) are formed, one end of described capacitor C 4 connects the pin 3 of described timer 556, the pin 7 of the other end of described capacitor C 4 and described timer 556 is connected ground jointly, the pin 4 of described timer 556, pin 10 and pin 14 are connected to the positive pole of the output of described filter circuit jointly, the pin 5 order series resistance R5 and the resistance R 4 of described timer 556, one end of described capacitor C 5 is connected respectively to resistance R 4, the pin 2 of described timer 556 and pin 6, the other end of described capacitor C 5 connects ground, the pin 5 of described timer 556, pin 8 is connected with pin 12, its tie point is first output of described low-frequency square-wave generator, and the pin 9 of described timer 556 is second output of described low-frequency square-wave generator.

Described bridge inverter main circuit 4 is connected with described low-frequency square-wave generator 3 with described filter circuit 2 respectively, is used for described low-frequency square-wave AC signal is carried out power amplification,

Described bridge inverter main circuit is made up of 4 alternating-current switchs (K1-K4), described alternating-current switch K1, K2, K3 and K4 connect into the quadrangle bridge, the a pair of summit of bridge is connected with described filter circuit, another of bridge is used for being connected with load to the summit, described alternating-current switch K2 is connected with K4, its tie point is connected with first output of described low-frequency square-wave generator, and described alternating-current switch K1 is connected with K3, and its tie point is connected with second output of described low-frequency square-wave generator.

The circuit of the utility model embodiment frequency changer circuit is simple, and cost is low, has solved the application bottleneck of electronics fire ox, has widened range of application.

Fig. 5 is the electrical block diagram according to first embodiment shown in Figure 4.With reference to figure 3, described frequency changer circuit comprises rectification circuit 1, filter circuit 2, low-frequency square-wave generator 3 and bridge inverter main circuit 4.When implementing electronics fire ox by the described frequency changer circuit drive unit of the utility model embodiment, in order to obtain duty ratio is 50% low-frequency square-wave AC signal, also increased a diode D5 in the described low-frequency square-wave generator 3, described diode D5 is in parallel with resistance R 4, is used to obtain duty ratio and reaches 50% for the low-frequency square-wave AC signal.Electric current when described capacitor C 5 chargings and discharge is inconsistent, the AC signal duty ratio that causes exporting can not guarantee to be 50%, described diode D5 can shunt the electric current on the R4 when charging, makes charging current increase thereby the time shortening, redeeming.

Described bridge inverter main circuit 4 is made up of 2 positive-negative-positive triodes (Q1-Q2), 4 NPN type triodes (Q3-Q6) and 12 resistance (R6-R17);

Described triode Q1, Q3 and described resistance (R6-R9) are formed described alternating-current switch K1, wherein said triode Q3 is used to drive described triode Q1, the emitter of described triode Q1 connects the positive pole of the output of described filter, described resistance R 6 is connected in parallel between the base stage and emitter of described triode Q1, one end of described resistance R 7 is connected with the collector electrode of described triode Q3, the other end of described resistance R 7 is connected with the base stage of described triode Q1, one end of described resistance R 8 connects the base stage of described triode Q1, the other end of described resistance R 8 connects second output of described low-frequency square-wave generator, described resistance R 9 is connected in parallel between the base stage and emitter of described triode Q3, and the emitter of described triode Q3 connects ground;

Described triode Q2, Q6 and described resistance (R12-R15) are formed described alternating-current switch K2, wherein said triode Q6 is used to drive described triode Q2, the emitter of described triode Q2 connects the positive pole of the output of described filter, described resistance R 12 is connected in parallel between the base stage and emitter of described triode Q2, one end of described resistance R 13 is connected with the base stage of described triode Q2, the other end of described resistance R 13 is connected with the collector electrode of described triode Q2, one end of described resistance R 14 connects the base stage of described triode Q6, the other end of described resistance R 14 connects first output of described low-frequency square-wave generator, described resistance R 15 is connected in parallel between the base stage and emitter of described triode Q6, and the emitter of described triode Q6 connects ground;

Described triode Q4 and described resistance (R10-R11) are formed described alternating-current switch K4, wherein said resistance R 11 is connected in parallel between the base stage and emitter of described triode Q4, one end of described resistance R 10 connects the base stage of described triode Q4, the other end of described resistance R 10 connects first output of described low-frequency square-wave generator, and the emitter of described triode Q4 connects ground;

Described triode Q5 and described resistance (R16-R17) are formed described alternating-current switch K3, wherein said resistance R 17 is connected in parallel between the base stage and emitter of described triode Q5, one end of described resistance R 16 connects the base stage of described triode Q5, the other end of described resistance R 16 connects second output of described low-frequency square-wave generator, and the emitter of described triode Q5 connects ground;

The collector electrode of described triode Q1 connects the collector electrode of described triode Q4, its tie point is used to connect an input of described load, the collector electrode of described triode Q2 connects the collector electrode of described triode Q5, and its tie point is used to connect another input of described load.

Because the pin 5 of timer 556 is opposite with pin 9 output phases, therefore when pin 5 output high potentials, pin 9 output electronegative potentials, triode Q2 and triode Q4 conducting, triode Q1 and triode Q5 end, electric current by capacitor C 2 positive poles through triode Q2, alternating current machine (MOTO1), triode Q4 gets back to the negative pole of capacitor C 2.When pin 5 output electronegative potentials, pin 9 output high potentials, triode Q2 and triode Q4 end, triode Q1 and triode Q5 conducting, electric current by the C2 positive pole through triode Q1, MOTO1, triode Q5 gets back to the negative pole of capacitor C 2, and the MOTO1 two ends can obtain the alternating voltage of peak-to-peak value twice supply voltage.

The bridge inverter main circuit of present embodiment has the power amplification effect, and can drive needs powerful device.

Fig. 6 is the electrical block diagram according to second embodiment shown in Figure 4.With reference to figure 6, described frequency changer circuit comprises rectification circuit 1, filter circuit 2, low-frequency square-wave generator 3 and bridge inverter main circuit 4.The bridge inverter main circuit 4 of this enforcement is made up of 2 positive-negative-positive triodes (Q7-Q8), 2 NPN type triodes (Q9-Q10);

The collector electrode of described triode Q9 is connected with the collector electrode of described triode Q10, its tie point is connected with the positive pole of the output of described filter circuit, the collector electrode of described triode Q7 is connected with the collector electrode of described triode Q8, its tie point be connected with the negative pole of the output of described filter circuit (being connected ground);

The emitter of described triode Q9 is connected with the emitter of described triode Q7, its tie point is used to connect an input of described load, the emitter of described triode Q8 is connected with the emitter of described triode Q10, and its tie point is used to connect another input of described load;

The base stage of described triode Q7 is connected with the base stage of described triode Q9, its tie point is connected with first output of described low-frequency square-wave generator, the base stage of described triode Q8 is connected with the base stage of described triode Q10, and its tie point is connected with second output of described low-frequency square-wave generator.

When the pin 5 output high potentials of timer 556, pin 9 output electronegative potentials, triode Q10 and Q7 conducting, triode Q9 and Q8 end, electric current by the positive pole of capacitor C 2 through triode Q10, MOTO1, triode Q7 gets back to the negative pole of capacitor C 2.When described pin 5 output electronegative potentials, pin 9 output high potentials, triode Q10 and Q7 end, triode Q9 and Q8 conducting, electric current by the positive pole of capacitor C 2 through triode Q9, MOTO1, triode Q8 gets back to the negative pole of capacitor C 2.The MOTO1 two ends can obtain the alternating voltage of peak-to-peak value twice supply voltage.

In the utility model embodiment, alternating-current switch K1, K2, K3 and the K4 of described bridge inverter main circuit 4 can also be made up of MOSFET pipe or other electronic switch switches.

Above disclosed only is the utility model preferred embodiment, can not limit the interest field of the utility model certainly with this, and therefore the equivalent variations of being done according to the utility model claim still belongs to the scope that the utility model is contained.

Claims (5)

1, a kind of frequency changer circuit comprises:

The high frequency ac signal that receives is converted into the rectification circuit of direct current signal;

The filter circuit that is connected with described rectification circuit;

Be connected with described filter circuit, to produce the low-frequency square-wave generator of low-frequency square-wave AC signal, described low-frequency square-wave transmitter comprises timer, two capacitor C 4, C5 and two resistance R 4, R5, wherein, described capacitor C 4, C5 all are connected between described timer and the filter circuit, described resistance R 4 is connected with R5, and described capacitor C 5 links to each other with resistance R 4, and described resistance R 5 links to each other with described timer.

2, frequency changer circuit according to claim 1 is characterized in that, described frequency changer circuit also comprises:

Be connected with described low-frequency square-wave generator with described filter circuit respectively, be used for bridge inverter main circuit that described low-frequency square-wave AC signal is carried out power amplification,

Described bridge inverter main circuit comprises 4 alternating-current switch K1-K4, described alternating-current switch K1, K2, K3 and K4 connect into the quadrangle bridge, the tie point that described alternating-current switch K1 is connected with K2 links to each other with described filter circuit, the tie point that described alternating-current switch K3 is connected with K4 is connected ground, the tie point that described alternating-current switch K1 is connected with K4 is connected load with the tie point of described alternating-current switch K2 and K3, described alternating-current switch K2 is connected with K4, its tie point links to each other with described low-frequency square-wave generator, described alternating-current switch K1 is connected with K3, and its tie point links to each other with described low-frequency square-wave generator.

3, frequency changer circuit according to claim 2 is characterized in that, described bridge inverter main circuit comprises 4 alternating-current switch K1-K4, is specially:

Described bridge inverter main circuit comprises 2 positive-negative-positive triode Q1-Q2,4 NPN type triode Q3-Q6 and 12 resistance R 6-R17;

Described triode Q1, Q3 and described resistance R 6-R9 form described alternating-current switch K1, described triode Q1 connects described filter, described resistance R 6 links to each other with described triode Q1, described resistance R 7 links to each other with described triode Q3, Q1 respectively, described resistance R 8 connects described triode Q1 and described low-frequency square-wave generator respectively, described resistance R 9 links to each other with described triode Q3, described triode Q3 ground connection;

Described triode Q2, Q6 and described resistance R 12-R15 form described alternating-current switch K2, described triode Q2 connects described filter, described resistance R 12 links to each other with described triode Q2, described resistance R 13 links to each other with described triode Q2, described resistance R 14 links to each other with described low-frequency square-wave generator with described triode Q6 respectively, the described resistance R 15 described triode Q6 ground connection that links to each other with described triode Q6;

Described triode Q4 and described resistance R 10-R11 form described alternating-current switch K4, and wherein said resistance R 11 links to each other with described triode Q4, and described resistance R 10 links to each other with described triode Q4, described low-frequency square-wave generator respectively, described triode Q4 ground connection;

Described triode Q5 and described resistance R 16-R17 form described alternating-current switch K3, and wherein said resistance R 17 links to each other with described triode Q5, and described resistance R 16 is connected ground with described triode Q5, the continuous described triode Q5 of described low-frequency square-wave generator respectively;

Described triode Q1 links to each other with Q4, and described triode Q2 links to each other with Q5.

4, frequency changer circuit according to claim 2 is characterized in that, described bridge inverter main circuit comprises 4 alternating-current switch K1-K4, is specially:

Described bridge inverter main circuit comprises 2 positive-negative-positive triode Q7-Q8,2 NPN type triode Q9-Q10;

Described triode Q9 links to each other with Q10, and described triode Q7 links to each other with Q8, and the tie point that described triode Q9 links to each other with Q10 links to each other with described filter circuit with the tie point that described triode Q7 links to each other with Q8;

Described triode Q9 links to each other with Q7, and described triode Q8 links to each other with Q10, and the tie point that described triode Q9 links to each other with Q10 links to each other with described low-frequency square-wave generator with the tie point that described triode Q7 links to each other with Q8.

5, frequency changer circuit according to claim 1 is characterized in that, described low-frequency square-wave generator comprises that also being used to obtain described low-frequency square-wave AC signal duty ratio is 50% diode, and described diode is in parallel with resistance R 4.

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