CN214064982U - Pulse igniter testing device - Google Patents

Abstract

The utility model discloses a pulse ignition ware testing arrangement belongs to gas utensil electronic accessories technical field, and the test of having solved traditional pulse ignition ware needs to rely on artifical, the low, the poor problem of product uniformity of production efficiency. The utility model comprises a frame, a conveyor, a preparation station, a test station, a buffer station and a manipulator; the test station comprises a test board embedded with spring test needles, the buffer storage station comprises a defective product temporary storage box, and a support plate is fixedly arranged on the edge of the defective product temporary storage box. The utility model discloses detection efficiency is high, and the product uniformity is high, and implementation cost is low, brings considerable economic benefits for the enterprise, has the significance in impulse ignition ware technical field, has realized impulse ignition ware's intelligent production function, has promoted impulse ignition ware's high quality development.

Description

Pulse igniter testing device

Technical Field

The utility model belongs to the technical field of gas utensil electronic accessories, specifically speaking especially relates to a think about novel, can release the labour, effectively avoid because of the product misjudgement incident that human factor leads to, product uniformity is high, production efficiency is high, pulse igniter testing arrangement who makes the field at pulse igniter significant has.

Background

The pulse igniter, pulse device for short, is an electronic product which utilizes pulse principle to produce continuous instantaneous spark so as to ignite flame of gas appliance. Early pulse generators mostly used dry batteries as power sources, but most products in recent years have been powered by alternating current. With the improvement of industrial technology, the pulse igniter is generally applied to middle and high-end gas appliance products, and the use of customers is greatly facilitated. The patent document discloses a pulse igniter which is widely applied to the market at present, and the Chinese patent with the name of universal pulse igniter is created by the utility model with the publication number of CN202561806U and publication number of 2012.11.28.

The pulse igniter mainly comprises a shell, a cover plate, a PCBA board and a high-voltage coil electrically connected with a terminal, and after the PCBA board is connected with a power supply, the high-voltage coil can output high-voltage pulses through the terminal. According to strike sparks the head and can divide into two-end formula pulse igniter, three-head formula pulse igniter, four-head formula pulse igniter, five-head formula pulse igniter etc. with pulse igniter, two terminals output pulse on a high-voltage coil strike sparks performance parameter unanimous, so only need measure one of them during the measurement, another ground connection can.

The eight-head pulse igniter illustrated in fig. 1 of the drawings in the specification is taken as an example, and the pulse igniter is provided with two power supply terminals and 8 high-voltage output terminals. When power is input at two power ends of the pulse igniter, 8 high-voltage output terminals output high-voltage pulses, wherein the high-voltage parameters output by the terminals with the reference numbers a1 and a2 are the same, the high-voltage parameters output by the terminals with the reference numbers b1 and b2 are the same, the high-voltage parameters output by the terminals with the reference numbers c1 and c2 are the same, and the high-voltage parameters output by the terminals with the reference numbers d1 and d2 are the same. When in measurement, one of the two terminals of the reference mark a1 and the reference mark a2 is used as a first output test terminal, and the other terminal is grounded; two terminals of a reference mark b1 and a reference mark b2, wherein one terminal is used as a second output test terminal, and the other terminal is grounded; and so on.

The traditional pulse igniter test is carried out manually, high-voltage pulse of the igniter is input into an oscilloscope, the oscilloscope displays the waveform, and conventional parameters such as ignition high voltage, discharge frequency, discharge period and the like are read manually according to the waveform. At present, the labor cost is high, the mobility of personnel is high, professional training is needed before the personnel is on duty, a plurality of uncertain factors are brought to the production continuity, and an enterprise often has an event that the production line is forced to be suspended due to the mobility of the personnel; in addition, the condition of misjudgment is inevitable through manual judgment, particularly, the credibility of a company is directly influenced by mixing defective products into qualified products, and the consistency and the stability of the products are poor; in addition, the manual operation has low productivity and low production efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a to the not enough of prior art existence, provide one kind and think about novel, can release the labour, effectively avoid because of the product misjudgement incident that the human factor leads to, product uniformity is high, production efficiency is high, make the pulse igniter testing arrangement that the field has important meaning at the pulse igniter.

The utility model discloses a realize through following technical scheme:

a testing device for a pulse igniter comprises a rack, a conveyor, a preparation station, a testing station, a buffer station and a manipulator; the conveyor, the testing station, the buffer station and the manipulator are all arranged on the table surface of the rack;

the preparation station is positioned on the conveyor;

the testing station is arranged on one side of the conveyor and comprises a testing plate embedded with spring testing needles, and the testing plate is fixedly supported on the table surface of the rack by a bracket; the spring test needle comprises a power needle, a grounding needle and a test needle, the tail part of the power needle is electrically connected with an input power supply, the tail part of the grounding needle is electrically connected with a ground wire, the tail part of the test needle is electrically connected with a test circuit, the output end of the test circuit is electrically connected with an oscilloscope, the oscilloscope is in communication connection with a PC (personal computer) and the PC is in communication connection with a PLC (programmable logic controller);

the buffer station is arranged at one side of the testing station and comprises a defective product temporary storage box, a supporting plate is fixedly arranged at the side of the defective product temporary storage box, and the defective product temporary storage box is fixedly supported on a piston rod of a temporary storage box power unit;

the manipulator is electrically connected with the PLC and comprises a transverse guide rail fixedly supported on the table surface of the rack, a transverse moving slide block in sliding connection with the transverse guide rail is arranged in the transverse guide rail, a longitudinal guide rail is arranged on the transverse moving slide block, a slide plate in sliding connection with the longitudinal guide rail is arranged on the longitudinal guide rail, and sub-claws for clamping finished products to a preparation station, a test station and a buffer station are arranged on the slide plate at intervals.

Preferably, the test circuit comprises a plurality of attenuation load circuits formed by load probes and load capacitors;

a first output test terminal D1 of the pulse igniter is electrically connected with the oscilloscope through a path of attenuation load circuit, and the path of attenuation load circuit comprises a path of load capacitor C1 and a path of load probe T1; the first output test terminal D1 is electrically connected with one end of a load capacitor C1 through a lead on one hand and one end of a load probe T1 on the other hand, the other end of the load capacitor C1 on the other hand is grounded, and the other end of the load probe T1 on the other hand is electrically connected with an oscilloscope;

a second output test terminal D2 of the pulse igniter is electrically connected with the oscilloscope through a two-way attenuation load circuit, and the two-way attenuation load circuit comprises a two-way load capacitor C2 and a two-way load probe T2; the second output test terminal D2 is electrically connected with one end of the two-way load capacitor C2 on one hand and one end of the two-way load probe T2 on the other hand through a lead, the other end of the two-way load capacitor C2 is grounded, and the other end of the two-way load probe T2 is electrically connected with an oscilloscope;

an nth output test terminal Dn of the pulse igniter is electrically connected with the oscilloscope through n paths of attenuation load circuits, and each n path of attenuation load circuit comprises n paths of load capacitors Cn and n paths of load probes Tn; the nth output test terminal Dn is electrically connected with one end of the n-path load capacitor Cn on one hand and one end of the n-path load probe Tn on the other hand through a lead, the other end of the n-path load capacitor Cn is grounded, and the other end of the n-path load probe Tn is electrically connected with the oscilloscope.

Preferably, the number of the claws is three, namely a first claw, a second claw and a third claw.

Preferably, the transverse moving slide block is driven by a cylinder as a power unit to reciprocate; the sliding plate is also driven to reciprocate by the cylinder serving as a power unit; the power unit of the temporary storage box is an air cylinder; the first claw, the second claw and the third claw are clamping claw cylinders.

Preferably, a traction track for drawing the finished product to the preparation station is fixedly arranged on the conveyor.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses the detection method is novel in design, has ingeniously realized the intelligent test of pulse igniter, has released the labour, has alleviated enterprise personnel's disappearance pressure energetically;

the utility model has high efficiency, the picking, testing and feeding can be operated simultaneously, and the production efficiency is more than 3 times of the original manual operation;

the utility model discloses detection method makes the product uniformity very high, has effectively stopped the product misjudgment phenomenon because of human error, effectively ensures that each product from the factory is high quality certified products, has established good reputation and image for the enterprise;

the utility model has simple structure and design, easy realization, low implementation cost, flexible action and stable operation, greatly reduces the production cost of enterprises and greatly improves the production efficiency of the pulse igniter;

the utility model discloses test method and testing arrangement bring considerable economic benefits for the enterprise, have the significance in pulse ignition ware technical field, have realized the intelligent production function of pulse ignition ware, have promoted the high quality development of pulse ignition ware.

Drawings

FIG. 1 is a schematic diagram of an eight-head pulse igniter configuration;

FIG. 2 is a schematic view of the front direction structure of the testing device of the present invention;

FIG. 3 is an enlarged view of FIG. 2;

fig. 4 is a schematic view of the three-dimensional structure of the present invention;

FIG. 5 is an enlarged view of a portion of FIG. 4 according to the present invention;

fig. 6 is an enlarged view of fig. 5B according to the present invention;

fig. 7 is a block diagram of the testing principle applied to the testing station of the present invention.

In the figure: 1. obtaining a finished product; 20. a frame; 21. a conveyor; 22. preparing a station; 211. a traction track; 23. a test station; 231. a test board; 232. a power supply pin; 233. a ground pin; 234. a test pin; 24. caching a station; 25. a manipulator; 251. a first claw; 252. a second jaw; 253. a third jaw; 254. a transverse guide rail; 255. a laterally moving slide; 256. a longitudinal guide rail; 257. a slide plate; 26. a defective product temporary storage box; 261. a support plate; 27. a temporary storage tank power unit; 28. next procedure; 3. a test circuit; 4. an oscilloscope; 5, a PC machine; and 6, a PLC controller.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings:

a testing device for a pulse igniter comprises a frame 20, a conveyor 21, a preparation station 22, a testing station 23, a buffer station 24 and a manipulator 25; the conveyor 21, the testing station 23, the buffer station 24 and the manipulator 25 are all arranged on the table top of the rack 20;

the preparation station 22 is located on the conveyor 21;

the testing station 23 is arranged on one side of the conveyor 21, the testing station 23 comprises a testing plate 231 embedded with spring testing needles, and the testing plate 231 is fixedly supported on the table top of the rack 20 by a bracket; the spring test needle comprises a power needle 232, a grounding needle 233 and a test needle 234, the tail of the power needle 232 is electrically connected with an input power supply, the tail of the grounding needle 233 is electrically connected with a ground wire, the tail of the test needle 234 is electrically connected with a test circuit 3, the output end of the test circuit 3 is electrically connected with an oscilloscope 4, the oscilloscope 4 is in communication connection with a PC (personal computer) 5, and the PC 5 is in communication connection with a PLC (programmable logic controller) 6;

the buffer station 24 is arranged at one side of the test station 23 and comprises a defective product temporary storage box 26, a supporting plate 261 is fixedly arranged at the side of the defective product temporary storage box 26, and the defective product temporary storage box 26 is fixedly supported on a piston rod of a temporary storage box power unit 27;

the manipulator 25 is electrically connected with the PLC 6 and comprises a transverse guide rail 254 fixedly supported on the table surface of the rack 20, a transverse moving slide block 255 in sliding connection with the transverse guide rail 254 is arranged in the transverse guide rail 254, a longitudinal guide rail 256 is arranged on the transverse moving slide block 255, a sliding plate 257 in sliding connection with the longitudinal guide rail 256 is arranged on the longitudinal guide rail 256, and sub-claws for clamping finished products to a preparation station, a test station and a buffer station are arranged on the sliding plate at intervals.

Preferably, the test circuit 3 comprises a plurality of attenuation load circuits formed by load probes and load capacitors;

a first output test terminal D1 of the pulse igniter is electrically connected with the oscilloscope through a path of attenuation load circuit, and the path of attenuation load circuit comprises a path of load capacitor C1 and a path of load probe T1; the first output test terminal D1 is electrically connected to one end of a load capacitor C1 through a wire, and is electrically connected to one end of a load probe T1 through a wire, the other end of the load capacitor C1 is grounded, and the other end of the load probe T1 is electrically connected to the oscilloscope 4;

a second output test terminal D2 of the pulse igniter is electrically connected with the oscilloscope through a two-way attenuation load circuit, and the two-way attenuation load circuit comprises a two-way load capacitor C2 and a two-way load probe T2; the second output test terminal D2 is electrically connected with one end of the two-way load capacitor C2 on one hand and one end of the two-way load probe T2 on the other hand through a lead, the other end of the two-way load capacitor C2 is grounded, and the other end of the two-way load probe T2 is electrically connected with an oscilloscope;

an nth output test terminal Dn of the pulse igniter is electrically connected with the oscilloscope through n paths of attenuation load circuits, and each n path of attenuation load circuit comprises n paths of load capacitors Cn and n paths of load probes Tn; the nth output test terminal Dn is electrically connected with one end of the n-path load capacitor Cn on one hand and one end of the n-path load probe Tn on the other hand through a lead, the other end of the n-path load capacitor Cn is grounded, and the other end of the n-path load probe Tn is electrically connected with the oscilloscope. The utility model discloses the test circuit commonality is strong, and the circuit is set up with low costs. Those skilled in the art will appreciate that the load probe may be selected in a very small number of specifications, and that customization may be required if the attenuation factor is to be changed by changing the specification of the load probe, which may be costly. The utility model discloses utilize load electric capacity to solve this problem, each way decay load circuit has load electric capacity to carry out the partial pressure, and load electric capacity market specification kind is many, and the low price can change high-pressure decay multiple through the specification that changes load electric capacity, prevents that oscilloscope from damaging because of input voltage is too high.

Preferably, the number of the claws is three, namely a first claw, a second claw and a third claw.

Preferably, the transverse moving block 255 is driven by a cylinder as a power unit to reciprocate; the sliding plate 257 is also driven to reciprocate by a cylinder serving as a power unit; the power unit 27 of the temporary storage box is an air cylinder; the first claw 251, the second claw 252 and the third claw 253 are clamping claw cylinders.

Preferably, a traction track 211 for drawing the finished product 1 to the preparation station 22 is fixedly arranged on the conveyor 21. The design of the traction track is beneficial to the accurate arrival of the finished product at the preparation station.

Example 1:

a testing device for a pulse igniter comprises a frame 20, a conveyor 21, a preparation station 22, a testing station 23, a buffer station 24 and a manipulator 25; the conveyor 21, the testing station 23, the buffer station 24 and the manipulator 25 are all arranged on the table top of the rack 20; a traction rail 211 for drawing the finished product 1 to the preparation station 22 is fixed on the conveyor 21.

The preparation station 22 is located on the conveyor 21; in particular, the preparation station is located at the end position of the traction track. The traction track comprises a long plate, a middle and long plate, an inclined plate, a short plate and an end sealing plate, wherein the long plate, the middle and long plate, the inclined plate, the short plate and the end sealing plate are all fixedly arranged on a shell of the conveyor, the middle and long plate, the inclined plate and the short plate are fixedly connected in sequence to form a jointed plate, the long plate and the jointed plate are arranged oppositely, and the end sealing plate seals the jointed plate and the end of the long plate. The width of the traction track in the direction of traction is narrowed, which is also achieved by means of inclined plates. The design of the traction track is beneficial to the finished product to accurately reach the preparation station, and the traction track is simple in structural design and easy to implement.

The testing station 23 is arranged on one side of the conveyor 21, the testing station 23 comprises a testing plate 231 embedded with spring testing needles, and the testing plate 231 is fixedly supported on the table top of the rack 20 by a bracket; the spring test needle comprises a power needle 232, a grounding needle 233 and a test needle 234, the tail of the power needle 232 is electrically connected with an input power supply, the tail of the grounding needle 233 is electrically connected with a ground wire, the tail of the test needle 234 is electrically connected with a test circuit 3, the output end of the test circuit 3 is electrically connected with an oscilloscope, the oscilloscope is in communication connection with a PC (personal computer) 5, and the PC 5 is in communication connection with a PLC (programmable logic controller) 6;

the buffer storage station 24 is arranged at one side of the test station 23 and comprises a defective product temporary storage box 26, a supporting plate 261 is fixedly arranged at the side of the defective product temporary storage box 26, and the defective product temporary storage box 26 is fixedly supported on a piston rod of a temporary storage box power unit 27;

the manipulator 25 is electrically connected with the PLC 6 and comprises a transverse guide rail 254 fixedly supported on the table top of the frame 20, a transverse moving slide block 255 connected with the transverse guide rail 254 in a sliding manner is arranged in the transverse guide rail 254, a longitudinal guide rail 256 is arranged on the transverse moving slide block 255, a sliding plate 257 connected with the longitudinal guide rail 256 in a sliding manner is arranged on the longitudinal guide rail 256, and sub-claws for clamping are arranged on the sliding plate 257 at intervals. The partial claw of the present embodiment includes a first claw 251, a second claw 252, and a third claw 253.

The transverse moving slide block 255 of the embodiment is driven by a cylinder as a power unit to reciprocate; the sliding plate 257 is also driven to reciprocate by a cylinder as a power unit; the temporary storage box power unit 27 is a cylinder; the first claw 251, the second claw 252 and the third claw 253 are claw clamping cylinders.

The test method of the embodiment comprises the following steps:

a. the finished product 1 of the pulse igniter is inverted on a conveyor 21, the conveyor 21 conveys the finished product 1 to a preparation station 22, and a testing station 23 and a buffering station 24 are sequentially arranged on one side of the preparation station 22; the manipulator 25 is provided with three sub-claws, namely a first claw 251, a second claw 252 and a third claw 253, and the three sub-claws of the manipulator 25 synchronously act; the conveyor 21 conveys the finished product 1 to the preparation station 22 through the traction track 211. The conveyor is of course driven by a motor, which is prior art. Towards the preparation station, the drawing rail is narrowed, and the drawing rail at the preparation station can only accommodate one finished product;

b. the manipulator 25 is located at an initial position, the manipulator 25 moves downwards, and a first claw 251 of the manipulator 25 clamps the current nth finished product 1; for example, a vision sensor is used for sensing whether a finished product exists, the vision sensor is electrically connected with a PLC (programmable logic controller), when the vision sensor senses that the finished product exists at a preparation station, the vision sensor transmits a signal to the PLC, and the PLC controls a manipulator to move downwards, which is the prior art and is not described any more;

meanwhile, the manipulator 25 grips the n-1 th finished product 1 by the second claw 252 and presses the finished product on the test station 23;

meanwhile, the third claw 253 of the manipulator 25 clamps and holds the n-2 finished product 1 on the buffer storage station 24;

on a test station 23, an n-1 th finished product 1 is powered on, the output end of the finished product 1 is electrically connected with a test circuit 3, the test circuit 3 attenuates output high voltage output by the finished product 1 and transmits the output high voltage to an oscilloscope 4, the oscilloscope 4 measures ignition performance parameters of high voltage pulses, then the oscilloscope 4 inputs the ignition performance parameters to a PC (personal computer) 5, the PC 5 transmits the input ignition performance parameters to a PLC (programmable logic controller) 6, and the PLC 6 compares the ignition performance parameters with preset qualified parameters;

c. after the manipulator 25 is reset upwards, the manipulator moves a step distance towards the right end and then moves downwards; at this time, the first claw 251 places the nth product 1 on the testing station 23, the second claw 252 places the nth-1 product 1 on the buffer station 24, and the third claw 253 transfers the nth-2 product 1 to the next process 28;

during the exercise, the defective product temporary storage box 26 will have corresponding actions according to the parameter comparison result in the step b; if the finished product 1 is qualified after the parameter comparison in the step b, in the movement process, the defective product temporary storage tank 26 is kept still, the supporting plate 261 arranged on the defective product temporary storage tank 26 is positioned on the buffer storage station 24, and the n-1 th finished product 1 falls on the supporting plate 261; if the finished product 1 is unqualified after the parameter comparison in the step b, in the motion process, the defective product temporary storage box 26 moves, the box port of the defective product temporary storage box 26 is positioned on the cache station 24, and the n-1 th finished product 1 falls in the defective product temporary storage box 26;

d. after the finished product is put down, the mechanical arm 25 moves a step distance to the left end after being reset upwards, and returns to the initial position, and the steps are repeated in this way, and the operation is repeated in a circulating way.

The working process of the embodiment is as follows: the finished product is pulled to the preparation station under the guide of the pulling track. The vision sensor arranged at the preparation station senses that a finished product is arranged on the preparation station, the vision sensor transmits a signal to the PLC, the PLC controls the manipulator to move downwards, the first claw of the manipulator clamps and holds the current nth finished product (meanwhile, the second claw of the manipulator presses the nth-1 finished product on the test station for testing, and the third claw of the manipulator clamps and holds the nth-2 finished product on the cache station). After several seconds, the PLC controls the manipulator to reset upwards, move a step distance towards the right end and then move downwards, at the moment, the first claw places the nth finished product on the testing station (meanwhile, the second claw places the nth-1 finished product on the caching station, and the third claw transfers the nth-2 finished product to the next working procedure 28). After the product is put down, the mechanical arm is reset upwards, moves a step distance towards the left end direction, returns to the initial position, and then moves downwards, at the moment, on a test station, the nth finished product is held and pressed by the second claw clamp (meanwhile, the first claw holds the (n + 1) th finished product, and the third claw clamp holds the (n-1) th finished product), the power input terminal of the nth finished product is electrically connected with the power needle, one half of the output terminal of the nth finished product is used as the output test terminal to be electrically connected with the test needle, the other half of the output terminal is used as the ground terminal to be electrically connected with the ground needle, the test needle attenuates the output high voltage of the nth finished product by the test circuit and inputs the output high voltage into the oscilloscope, the ignition performance parameter of the high voltage pulse of the oscilloscope is measured, then the oscilloscope inputs the ignition performance parameter to the PC, the PC transmits the input ignition performance parameter to the PLC controller, and the PLC controller compares the ignition performance parameter with the preset qualified parameter, after comparison, the PLC controls the mechanical arm to hold the current finished product to reset upwards by each sub-claw, moves one step distance towards the right end direction and moves downwards, and at the moment, the nth finished product is placed on the caching station by the second claw. In the action process, the defective product temporary storage box has corresponding action according to the test result of the nth finished product; if the number n finished products are qualified through testing, in the movement process, the defective product temporary storage box is kept still, the supporting plate arranged on the defective product temporary storage box is positioned on the caching station, and when the number n finished products reach the caching station, the number n finished products fall on the supporting plate; if the number n finished products are unqualified through testing, the defective product temporary storage box moves in the movement process, the box opening of the defective product temporary storage box is located on the caching station, and when the number n finished products reach the caching station, the number n finished products fall in the defective product temporary storage box. After the nth finished product is placed on the buffer storage station by the second claw, the manipulator resets upwards, moves a step distance towards the left end, returns to the initial position, and then moves downwards, at this time, the third claw can hold the nth finished product of the buffer storage station and transfer the nth finished product to the next working procedure 28 under the next action of the manipulator. Of course, if the product n is acceptable, the product n is transferred to the next step 28, but if the product n is not acceptable, the third claw performs the same operation, except that the product is not gripped. The reciprocating action is circulated in this way.

The intelligent testing device is novel in concept, intelligently tests the pulse igniter, releases labor force and greatly relieves the missing pressure of enterprise personnel;

the automatic workpiece taking and feeding device is high in efficiency, the workpiece taking, testing and feeding can be operated simultaneously, and the production efficiency is more than 3 times of that of the original manual operation;

the embodiment has the advantages that the product consistency is high, the product misjudgment phenomenon caused by human errors is effectively avoided, each outgoing product is effectively guaranteed to be a high-quality qualified product, and good credit and image are established for enterprises;

the pulse igniter has the advantages of simple structural design, easiness in implementation, low implementation cost, flexibility in action and stability in operation, greatly reduces the production cost of enterprises, and greatly improves the production efficiency of the pulse igniter;

the embodiment brings considerable economic benefits to enterprises, has important significance in the technical field of pulse igniters, realizes intelligent production operation of the pulse igniters, and promotes high-quality development of the pulse igniters.

Example 2:

this embodiment is a further improvement of the test circuit based on embodiment 1.

The test circuit 3 of the present embodiment includes a plurality of attenuated load circuits formed by load probes and load capacitors.

As shown in fig. 7 of the accompanying drawings in the specification, a first output test terminal D1 of the pulse igniter is electrically connected to the oscilloscope 4 through an attenuation load circuit, where the attenuation load circuit includes a load capacitor C1 and a load probe T1, the first output test terminal D1 is electrically connected to one end of the load capacitor C1 through a wire, and is electrically connected to one end of the load probe T1 through a wire, the other end of the load capacitor C1 is grounded, and the other end of the load probe T1 is electrically connected to the oscilloscope 4;

a second output test terminal D2 of the pulse igniter is electrically connected with the oscilloscope 4 through a two-way attenuation load circuit, the two-way attenuation load circuit comprises a two-way load capacitor C2 and a two-way load probe T2, the second output test terminal D2 is electrically connected with one end of the two-way load capacitor C2 on one hand and one end of the two-way load probe T2 on the other hand through a lead, the other end of the two-way load capacitor C2 is grounded, and the other end of the two-way load probe T2 is electrically connected with the oscilloscope 4;

an nth output test terminal Dn of the pulse igniter is electrically connected with the oscilloscope 4 through an n-path attenuation load circuit, the n-path attenuation load circuit comprises an n-path load capacitor Cn and an n-path load probe Tn, the nth output test terminal Dn is electrically connected with one end of the n-path load capacitor Cn on one hand and one end of the n-path load probe Tn on the other hand through a lead, the other end of the n-path load capacitor Cn is grounded, and the other end of the n-path load probe Tn is electrically connected with the oscilloscope 4. The test circuit of the embodiment has strong universality and low circuit construction cost. Those skilled in the art will appreciate that the load probe may be selected in a very small number of specifications, and that customization may be required if the attenuation factor is to be changed by changing the specification of the load probe, which may be costly. The utility model discloses utilize load electric capacity to solve this problem, each way decay load circuit has load electric capacity to carry out the partial pressure, and load electric capacity market specification kind is many, and the low price can change high-pressure decay multiple through the specification that changes load electric capacity, prevents that oscilloscope from damaging because of input voltage is too high.

In summary, the present invention is only a preferred embodiment, and is not intended to limit the scope of the present invention, and all equivalent changes and modifications in the shape, structure, characteristics and spirit of the claims of the present invention should be included in the scope of the claims of the present invention.

Claims (5)

1. A pulse igniter testing device is characterized in that: the testing device comprises a rack, a conveyor, a preparation station, a testing station, a buffer station and a manipulator; the conveyor, the testing station, the buffer station and the manipulator are all arranged on the table surface of the rack;

the preparation station is positioned on the conveyor;

the testing station is arranged on one side of the conveyor and comprises a testing plate embedded with spring testing needles, and the testing plate is fixedly supported on the table surface of the rack by a bracket; the spring test needle comprises a power needle, a grounding needle and a test needle, the tail part of the power needle is electrically connected with an input power supply, the tail part of the grounding needle is electrically connected with a ground wire, the tail part of the test needle is electrically connected with a test circuit, the output end of the test circuit is electrically connected with an oscilloscope, the oscilloscope is in communication connection with a PC (personal computer) and the PC is in communication connection with a PLC (programmable logic controller);

the buffer station is arranged at one side of the testing station and comprises a defective product temporary storage box, a supporting plate is fixedly arranged at the side of the defective product temporary storage box, and the defective product temporary storage box is fixedly supported on a piston rod of a temporary storage box power unit;

the manipulator is electrically connected with the PLC and comprises a transverse guide rail fixedly supported on the table surface of the rack, a transverse moving slide block in sliding connection with the transverse guide rail is arranged in the transverse guide rail, a longitudinal guide rail is arranged on the transverse moving slide block, a slide plate in sliding connection with the longitudinal guide rail is arranged on the longitudinal guide rail, and sub-claws for clamping finished products to a preparation station, a test station and a buffer station are arranged on the slide plate at intervals.

2. The pulse igniter testing device according to claim 1, wherein: the test circuit comprises a plurality of paths of attenuation load circuits formed by load probes and load capacitors;

a first output test terminal D1 of the pulse igniter is electrically connected with the oscilloscope through a path of attenuation load circuit, and the path of attenuation load circuit comprises a path of load capacitor C1 and a path of load probe T1; the first output test terminal D1 is electrically connected with one end of a load capacitor C1 through a lead on one hand and one end of a load probe T1 on the other hand, the other end of the load capacitor C1 on the other hand is grounded, and the other end of the load probe T1 on the other hand is electrically connected with an oscilloscope;

a second output test terminal D2 of the pulse igniter is electrically connected with the oscilloscope through a two-way attenuation load circuit, and the two-way attenuation load circuit comprises a two-way load capacitor C2 and a two-way load probe T2; the second output test terminal D2 is electrically connected with one end of the two-way load capacitor C2 on one hand and one end of the two-way load probe T2 on the other hand through a lead, the other end of the two-way load capacitor C2 is grounded, and the other end of the two-way load probe T2 is electrically connected with an oscilloscope;

an nth output test terminal Dn of the pulse igniter is electrically connected with the oscilloscope through n paths of attenuation load circuits, and each n path of attenuation load circuit comprises n paths of load capacitors Cn and n paths of load probes Tn; the nth output test terminal Dn is electrically connected with one end of the n-path load capacitor Cn on one hand and one end of the n-path load probe Tn on the other hand through a lead, the other end of the n-path load capacitor Cn is grounded, and the other end of the n-path load probe Tn is electrically connected with the oscilloscope.

3. A pulse igniter testing device according to claim 1 or 2, wherein: the number of the branch claws is three, namely a first claw, a second claw and a third claw.

4. A pulse igniter testing device according to claim 3, wherein: the transverse moving slide block is driven by a cylinder as a power unit to reciprocate; the sliding plate is also driven to reciprocate by the cylinder serving as a power unit; the power unit of the temporary storage box is an air cylinder; the first claw, the second claw and the third claw are clamping claw cylinders.

5. A pulse igniter testing device according to claim 3, wherein: and a traction track for drawing the finished product to a preparation station is fixedly arranged on the conveyor.

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