A kind of high capacity wire harness winding inserter system based on Linear Driving
Technical field
The utility model relates to a kind of wire harness winding inserter drive system, specifically refers to a kind of high capacity wire harness winding inserter system based on Linear Driving.
Background technology
Current electronics categories, function constantly increase, and the use of wire harness increases thereupon.In wire harness production process, workload is very large, and present people widely use wire harness winding inserter and carry out wire harness production thus substantially increase operating efficiency.
But the load capacity of current wire harness winding inserter drive system is inadequate, is easy to burn out drive system when its load is excessive.
Utility model content
The purpose of this utility model is to overcome the inadequate defect of current wire harness winding inserter driving system loads ability, provides a kind of high capacity wire harness winding inserter system based on Linear Driving.
The purpose of this utility model is achieved through the following technical solutions: a kind of high capacity wire harness winding inserter system based on Linear Driving, comprise front-end sampling circuit, with the linear drive circuit that front-end sampling circuit output end is connected, the circuits for triggering be connected with linear drive circuit, with the voltage stabilizing circuit that circuits for triggering output is connected, the boostrap circuit be connected with voltage stabilizing circuit, and the output circuit be connected with boostrap circuit, described linear drive circuit is by driving chip U1, triode VT3, triode VT4, triode VT5, triode VT6, positive pole is connected with front-end sampling circuit, the polar capacitor C8 that negative pole is connected with the IN1 pin of driving chip U1 after resistance R12, one end is connected with the collector electrode of triode VT6, the resistance R13 that the other end is connected with the base stage of triode VT3 after resistance R14, positive pole is connected with the base stage of triode VT6, the polar capacitor C10 that negative pole is connected with the IN1 pin of driving chip U1, positive pole is connected with the IN2 pin of driving chip U1, the polar capacitor C9 of minus earth, one end is connected with the emitter of triode VT6, the resistance R16 that the other end is connected with the base stage of triode VT5, one end is connected with the base stage of triode VT5, the resistance R15 that the other end is connected with the base stage of triode VT3, N pole is connected with the collector electrode of triode VT6, the diode D5 that P pole is connected with the collector electrode of triode VT5, positive terminal is connected with the collector electrode of triode VT6, the not gate K that end of oppisite phase is connected with triode VT4 collector electrode, one end is connected with triode VT4 emitter, the resistance R18 that the other end is connected with the emitter of triode VT3 after resistance R17, the end of oppisite phase of P pole NAND gate K is connected, the diode D6 that N pole is connected with the tie point of resistance R18 with resistance R17 forms, the VCC pin of described driving chip U1 is connected with the base stage of triode VT6, END pin ground connection, OUT pin are connected with the collector electrode of triode VT5, the collector electrode of triode VT5 is also connected with the base stage of triode VT4, its emitter is connected with the base stage of triode man VT3, the grounded collector of triode VT3, the N pole of diode D6 is connected with circuits for triggering.
Described front-end sampling circuit comprises diode D1, diode D2, polar capacitor C1, resistance R1; The N pole of diode D2 is extremely connected with the P of diode D1 after polar capacitor C1, P pole is then extremely connected with the N of diode D1 after resistance R1; The P pole of described diode D2 is also connected with the positive pole of circuits for triggering and electric capacity C8 simultaneously.
Described circuits for triggering by triode VT1, polar capacitor C2, inductance L 1 forms; The base stage of triode VT1 is extremely connected with the N of diode D6, and its collector electrode is then connected with voltage stabilizing circuit, and emitter is connected with output circuit with the P pole of diode D2 after polar capacitor C2 simultaneously; One end of inductance L 1 is connected with the collector electrode of triode VT1, and the other end is then extremely connected with the P of diode D2.
Described voltage stabilizing circuit by voltage stabilizing chip U, the resistance R2 that one end is connected with the collector electrode of triode VT1, the other end is connected with the IN pin of voltage stabilizing chip U, and one end is connected with the ENG pin of voltage stabilizing chip U, the resistance R3 of other end ground connection forms; The OUT pin of described voltage stabilizing chip U is then connected with boostrap circuit.
Described bootstrapping control circuit is by triode VT2, field effect transistor Q, one end is connected with the collector electrode of triode VT2, the resistance R8 that the other end is then connected with output circuit, positive pole is connected with the emitter of triode VT2, the polar capacitor C6 that negative pole is then connected with output circuit, positive pole is connected with the source electrode of field effect transistor Q, the polar capacitor C5 that negative pole is connected with the negative pole of polar capacitor C6, one end is connected with the base stage of triode VT2, the resistance R6 of other end ground connection after resistance R4, positive pole is connected with the tie point of resistance R4 with resistance R6, the polar capacitor C4 of negative pole ground connection after resistance R7, positive pole is connected with the OUT pin of voltage stabilizing chip U, the polar capacitor C3 that negative pole is then connected with the grid of field effect transistor Q, and one end is connected with the negative pole of polar capacitor C3, the other end be then connected with the positive pole of polar capacitor C4 resistance R5 form, the drain electrode of described field effect transistor Q is connected with the base stage of triode VT1, and source electrode is connected with the negative pole of polar capacitor C4.
Described output circuit comprises diode D3, diode D4, polar capacitor C7, resistance R9, resistance R10, resistance R11; The positive pole of polar capacitor C7 is connected with the N pole of diode D3, its negative pole is connected with the negative pole of polar capacitor C6 after resistance R9 through resistance R10, resistance R11 and resistance R10 is in parallel, the N pole of diode D3 is connected with resistance R8, its P pole is connected with the P pole of diode D4, and the N pole of diode D4 is connected with the negative pole of polar capacitor C5, P pole is then connected with the P pole of diode D2.
The utility model comparatively prior art is compared, and has the following advantages and beneficial effect:
(1) the utility model is provided with linear drive circuit, and it effectively can promote the load capacity of wire harness winding inserter drive system, avoids drive system to burn out because load is excessive.
(2) the utility model structure is simple, and cost of manufacture is low, is applicable to extensively promoting.
Accompanying drawing explanation
Fig. 1 is integrated circuit figure of the present utility model.
Fig. 2 is the circuit diagram of the utility model linear drive circuit.
Embodiment
Below in conjunction with embodiment, the utility model is described in further detail, but execution mode of the present utility model is not limited thereto.
Embodiment
As shown in Figure 1, high capacity wire harness winding inserter system based on Linear Driving of the present utility model, comprise front-end sampling circuit, with the linear drive circuit that front-end sampling circuit output end is connected, the circuits for triggering be connected with linear drive circuit, with the voltage stabilizing circuit that circuits for triggering output is connected, the boostrap circuit be connected with voltage stabilizing circuit, and the output circuit be connected with boostrap circuit.
As shown in Figure 2, described linear drive circuit is by driving chip U1, triode VT3, triode VT4, triode VT5, triode VT6, positive pole is connected with front-end sampling circuit, the polar capacitor C8 that negative pole is connected with the IN1 pin of driving chip U1 after resistance R12, one end is connected with the collector electrode of triode VT6, the resistance R13 that the other end is connected with the base stage of triode VT3 after resistance R14, positive pole is connected with the base stage of triode VT6, the polar capacitor C10 that negative pole is connected with the IN1 pin of driving chip U1, positive pole is connected with the IN2 pin of driving chip U1, the polar capacitor C9 of minus earth, one end is connected with the emitter of triode VT6, the resistance R16 that the other end is connected with the base stage of triode VT5, one end is connected with the base stage of triode VT5, the resistance R15 that the other end is connected with the base stage of triode VT3, N pole is connected with the collector electrode of triode VT6, the diode D5 that P pole is connected with the collector electrode of triode VT5, positive terminal is connected with the collector electrode of triode VT6, the not gate K that end of oppisite phase is connected with triode VT4 collector electrode, one end is connected with triode VT4 emitter, the resistance R18 that the other end is connected with the emitter of triode VT3 after resistance R17, the end of oppisite phase of P pole NAND gate K is connected, the diode D6 that N pole is connected with the tie point of resistance R18 with resistance R17 forms, the VCC pin of described driving chip U1 is connected with the base stage of triode VT6, END pin ground connection, OUT pin are connected with the collector electrode of triode VT5, the collector electrode of triode VT5 is also connected with the base stage of triode VT4, its emitter is connected with the base stage of triode man VT3, the grounded collector of triode VT3, the N pole of diode D6 is connected with circuits for triggering.Linear drive circuit, it effectively can promote the load capacity of wire harness winding inserter drive system, avoids drive system to burn out because load is excessive.In order to ensure implementation result, described driving chip U is preferably LM387 integrated chip, its highly sensitive and low price.
Described front-end sampling circuit comprises diode D1, diode D2, polar capacitor C1, resistance R1; The N pole of diode D2 is extremely connected with the P of diode D1 after polar capacitor C1, P pole is then extremely connected with the N of diode D1 after resistance R1; The P pole of described diode D2 is also connected with the positive pole of circuits for triggering and electric capacity C8 simultaneously.
Described circuits for triggering by triode VT1, polar capacitor C2, inductance L 1 forms; The base stage of triode VT1 is extremely connected with the N of diode D6, and its collector electrode is then connected with voltage stabilizing circuit, and emitter is connected with output circuit with the P pole of diode D2 after polar capacitor C2 simultaneously; One end of inductance L 1 is connected with the collector electrode of triode VT1, and the other end is then extremely connected with the P of diode D2.
Described voltage stabilizing circuit by voltage stabilizing chip U, the resistance R2 that one end is connected with the collector electrode of triode VT1, the other end is connected with the IN pin of voltage stabilizing chip U, and one end is connected with the ENG pin of voltage stabilizing chip U, the resistance R 3 of other end ground connection forms; The OUT pin of described voltage stabilizing chip U is then connected with boostrap circuit.
Described bootstrapping control circuit is by triode VT2, field effect transistor Q, one end is connected with the collector electrode of triode VT2, the resistance R8 that the other end is then connected with output circuit, positive pole is connected with the emitter of triode VT2, the polar capacitor C6 that negative pole is then connected with output circuit, positive pole is connected with the source electrode of field effect transistor Q, the polar capacitor C5 that negative pole is connected with the negative pole of polar capacitor C6, one end is connected with the base stage of triode VT2, the resistance R6 of other end ground connection after resistance R4, positive pole is connected with the tie point of resistance R4 with resistance R6, the polar capacitor C4 of negative pole ground connection after resistance R7, positive pole is connected with the OUT pin of voltage stabilizing chip U, the polar capacitor C3 that negative pole is then connected with the grid of field effect transistor Q, and one end is connected with the negative pole of polar capacitor C3, the other end be then connected with the positive pole of polar capacitor C4 resistance R5 form, the drain electrode of described field effect transistor Q is connected with the base stage of triode VT1, and source electrode is connected with the negative pole of polar capacitor C4.
Described output circuit comprises diode D3, diode D4, polar capacitor C7, resistance R9, resistance R10, resistance R11; The positive pole of polar capacitor C7 is connected with the N pole of diode D3, its negative pole is connected with the negative pole of polar capacitor C6 after resistance R9 through resistance R10, resistance R11 and resistance R10 is in parallel, the N pole of diode D3 is connected with resistance R8, its P pole is connected with the P pole of diode D4, and the N pole of diode D4 is connected with the negative pole of polar capacitor C5, P pole is then connected with the P pole of diode D2.
As mentioned above, just the utility model can well be realized.