CN205289025U - Macroarray resistance strain gauges automatic separation device - Google Patents

Abstract

The utility model discloses a macroarray resistance strain gauges automatic separation device, enlarge the board including frame, position fixing mechanism, absorption sorting mechanism, location sorting mechanism, computer, data -collection card and output, the frame includes roof, lower plate and pillar, position fixing mechanism includes two -dimensional mobile platform, vacuum adsorption table and a vacuum suction circuit, it includes the suction head mounting box and arranges that set up in the suction head mounting box and the lower extreme stretches out a plurality of vacuum suction head of suction head mounting box to adsorb the sorting mechanism to and the 2nd vacuum suction circuit and pneumatic circuit, the location sorting mechanism includes ball slip table, cylinder slip table and the 2nd pneumatic circuit. The utility model discloses compact structure, it is novel in design reasonable, to realize with low costsly, the operational reliability is high, and the practicality is strong, can improve production efficiency, and reduction workman intensity of labour and product manufacturing cost popularize and apply costlyly.

Description

Big array resistors formula foil gauge automatic sorting device

Technical field

This utility model belongs to resistance strain plate production technical field, is specifically related to a kind of big array resistors formula foil gauge automatic sorting device.

Background technology

Resistance strain plate is Analysis of Experimental Stress, test and measuring technology, automatic Test and control and weighs or the key element of force cell, have that size is little, creep is little, good anti-fatigue performance and the good feature such as stability, be widely used in the industries such as water conservancy and hydropower, railway traffic, intelligent building, production automatic control, Aero-Space, military project, petrochemical industry and weighing apparatus. Resistance strain plate is mainly pasted onto the surface of elastomer, the micro-strain (elongating or shortening) that elastomer produces in rear surface loaded, make the foil gauge being pasted onto its surface also in company with being deformed, after resistance strain gage deformation, its resistance will change (increase or reduce), then through corresponding measuring circuit, this resistance variations is converted to the signal of telecommunication (voltage or electric current) output, measure the change of resistance, the strain of surface of elastomer and corresponding stress can be calculated by formula.

As it is shown in figure 9, resistance strain plate is mainly made up of sensitive grid 50, substrate 51, cover layer 52 and lead-in wire 53, sensitive grid 50 binding agent 54 is bonded between substrate 51 and cover layer 52. In foil gauge production process, being first tightly adhered to by foil in substrate 51, substrate 51 material is generally glued membrane (phenol-formaldehyde resin modified, polyimide resin, epoxy resin etc.), and thickness is about 0.02mm��0.04mm; Sensitive grid 50 material is the metal alloy foil that thickness is about 0.0025mm��0.005mm, and foil is generally constantan foil, karma foil material, annealing constantan foil etc.; The molding of sensitive grid 50 is that according to certain circuit requirement, foil is carried out photoetching, corrosion, finally remains in the resistance wire in substrate 51 and is sensitive grid 50. In order to improve sensitive grid 50 job stability in use and service life further, also need to increase cover layer 52 on sensitive grid 50, the material of general cover layer 52 is identical with base material, thickness is about 0.01mm��0.02mm, and the gross thickness of resistance strain plate is about 0.035mm��0.05mm.

Resistance strain plate is to form according to certain queueing discipline Etching on the metal foil plate of a 102mm �� 115mm, and a metal foil plate generally has the figure of multiple product. Need from justifying, separate single foil gauge product in the foil gauge production later stage, and single foil gauge product is detected, sort finally according to testing result, current existing way is, single product is pruned by artificial use shears along the outer rim of product, and manually single product detected, sort, this artificial separation method not only production efficiency is low, labor strength is big, production cost is high, and easily make mistakes, it is unfavorable for that the stability to product quality controls.

Utility model content

Technical problem to be solved in the utility model is in that for above-mentioned deficiency of the prior art, a kind of big array resistors formula foil gauge automatic sorting device is provided, its compact conformation, novel in design reasonable, it is achieved cost is low, functional reliability is high, practical, can improving production efficiency, reduce labor strength and production cost, application value is high.

For solving above-mentioned technical problem, the technical solution adopted in the utility model is: a kind of big array resistors formula foil gauge automatic sorting device, it is characterized in that: include frame, location fixed mechanism, absorption sorting mechanism, location sorting mechanism and computer, being connected to data collecting plate card on described computer, the signal output part of described data collecting plate card is connected to output amplification board;

Described frame includes upper and lower spaced upper plate and lower shoe, and is supported on the pillar between upper plate and lower shoe;

Described location fixed mechanism includes the two-dimensional movement platform being arranged on lower shoe top, it is arranged on the vacuum adsorption table of two-dimensional movement table top and for the first vac sorb loop to vacuum adsorption table evacuation, described two-dimensional movement platform includes X-axis mobile motor, Y-axis mobile motor, X-axis moving grating chi and Y-axis moving grating chi, described vacuum adsorption table includes mutually fastening and fix the absorptive table lower cover and absorptive table upper cover that connect, it is vacuum chamber that described absorptive table lower cover and absorptive table upper cover fasten the space formed, the upper surface of described absorptive table upper cover is provided with the adsorption hole of multiple spread configuration, the first vacuum pump that described first vac sorb loop includes being sequentially connected with by the first vacuum tube, the first vacuum filter, the first vacuum regulate valve and the first vacuum solenoid, described first vacuum tube is connected with described vacuum chamber, and described first vacuum regulates and is connected to the first vacuum meter on valve, described X-axis moving grating chi and Y-axis moving grating chi are all connected with the signal input part of data collecting plate card, and described X-axis mobile motor, Y-axis mobile motor and the first vacuum solenoid are all connected with the outfan of output amplification board,

Multiple vac sorb heads of adsorption head mounting box are stretched out in described absorption sorting mechanism includes adsorption head mounting box and is arranged in adsorption head mounting box and lower end, and for making multiple vac sorb head produce the second vac sorb loop of negative-pressure adsorption function and for making multiple vac sorb head produce the first pneumatic circuit of blowing function; Distance between adjacent two vac sorb heads is equal with the distance between adjacent two adsorption holes, described vac sorb head includes the vac sorb pipe through adsorption head mounting box diapire, described vac sorb pipe is exposed at bottom the one end bottom adsorption head mounting box to be set with rubber suction nozzle, and one end that described vac sorb pipe is positioned within adsorption head mounting box is connected to connecting tube;Described second vac sorb loop includes the second vacuum pump, the second vacuum filter, the second vacuum adjustment valve, the second vacuum meter and Duo Gen the 3rd vacuum tube that are sequentially connected with by the second vacuum tube, and every described 3rd vacuum tube is respectively connected with the second vacuum solenoid; Described first pneumatic circuit includes the first air pump, the first air filter, the first air relief valve, the first air gauge and Duo Gen the second trachea that are sequentially connected with by the first trachea, and every described second trachea is respectively connected with the first air-operated solenoid valve; The connecting tube of each described vac sorb head is connected with the 3rd vacuum tube and second trachea each through threeway; Multiple second vacuum solenoids and multiple first air-operated solenoid valve are all connected with the outfan of output amplification board;

Described location sorting mechanism includes the ball-screw slide unit being horizontally set on upper plate top and is vertically arranged in the cylinder slide unit below upper plate, and second pneumatic circuit, described ball-screw slide unit includes the motor for driving ball-screw to move, the slide unit of described ball-screw slide unit is connected to cylinder slide unit installing plate, described cylinder slide unit is arranged on cylinder slide unit installing plate, described adsorption head mounting box is connected with the slide unit of cylinder slide unit by connecting plate, described upper plate is disposed with seven proximity switches being positioned at ball-screw slide unit side, described lower shoe is provided with sorting box, five sorting chambers it are provided with in described sorting box, five described sorting chamber respectively A class foil gauge sorting chambers, B class foil gauge sorting chamber, C class foil gauge sorting chamber, D class foil gauge sorting chamber and E class foil gauge sorting chamber, two of which in seven proximity switches lays respectively at original position and the final position of the slide unit motion of ball-screw slide unit, other five one_to_one corresponding in seven proximity switches are positioned at the surface of five sorting chambers, described second pneumatic circuit includes the second air pump, the second air filter, the second air relief valve and the second Pressure gauge that are sequentially connected with by the 3rd trachea, and described cylinder slide unit is connected by the second air-operated solenoid valve and the 3rd trachea, seven described proximity switches are all connected with the signal input part of data collecting plate card, and described motor and the second air-operated solenoid valve are all connected with the outfan of output amplification board.

Above-mentioned big array resistors formula foil gauge automatic sorting device, it is characterized in that: described pillar is made up of the many aluminium section bars connecting into frame structure, described aluminium section bar is connected by triangle connecting rack is fixing with aluminium section bar, described aluminium section bar is connected by screw bolt and nut is fixing with upper plate, and described aluminium section bar is connected by bolt, nut and triangle connecting rack are fixing with lower shoe.

Above-mentioned big array resistors formula foil gauge automatic sorting device, it is characterized in that: between described absorptive table lower cover and absorptive table upper cover, be provided with sealing gasket, described absorptive table lower cover, sealing gasket and absorptive table upper cover connect by absorptive table connecting bolt is fixing, the side of described absorptive table lower cover is provided with screwed hole, and described first vacuum tube is connected with screwed hole by pneumatic joint.

Above-mentioned big array resistors formula foil gauge automatic sorting device, it is characterized in that: the upper surface of described absorptive table upper cover is provided with a plurality of level to groove and a plurality of vertically to groove, a plurality of described level defines multiple projection to groove and a plurality of described vertically intersecting to groove, and multiple described adsorption holes are distributed on multiple projection; On described absorptive table cap upper surface be shaped as rectangle, described absorptive table is all carved with reference location line on four feet of cap upper surface.

Above-mentioned big array resistors formula foil gauge automatic sorting device, it is characterised in that: the model of described data collecting plate card is NIPCI6509, and the model of described output amplification board is HSF16M.

This utility model compared with prior art has the advantage that

1, compact conformation of the present utility model, novel in design reasonable, convenient processing and manufacture.

2, of the present utility model simple to operate, applied widely, it is possible to realize the automatic sorting of the big array resistors formula foil gauge of different model.

3, this utility model have be quick on the draw, work efficiency is high, it is little to pollute and attaches troops to a unit in periphery, and adnexa is few, realize the plurality of advantages such as cost is low.

4, this utility model achieves the automatic sorting of big array resistors formula foil gauge unit, it is to avoid the anthropic factor impact on product selecting, and separation velocity is fast, and sorting accuracy is high.

5, the absorption of the big array resistors formula foil gauge that vacuum adsorption table of the present utility model is capable of different model is fixed, and the abrasion of big array resistors formula foil gauge is little, and absorption fixed efficiency is high, it is little to pollute.

6, this utility model can improve the efficiency of separation of big array resistors formula foil gauge, and then improves production efficiency, reduces labor strength, stability contorting product quality, the competitiveness of enterprise.

7, this utility model is capable of rapid, accurate, the automatic sorting of big array resistors formula foil gauge, and the quickly sorting solved in resistance strain plate batch production process is had great significance, and practical, result of use is good, and application value is high.

In sum, this utility model compact conformation, novel in design reasonable, it is achieved cost is low, functional reliability is high, practical, it is possible to increase production efficiency, reduces labor strength and production cost, and application value is high.

Below by drawings and Examples, the technical solution of the utility model is described in further detail.

Accompanying drawing explanation

Fig. 1 is part-structure schematic diagram of the present utility model.

Fig. 2 is the structural representation of this utility model vacuum adsorption table.

Fig. 3 is the annexation schematic diagram of this utility model vacuum adsorption table and the first vac sorb loop.

Fig. 4 is the annexation schematic diagram of this utility model adsorption head mounting box and vac sorb head.

Fig. 5 is the left view of Fig. 4.

Fig. 6 is this utility model vac sorb head and the annexation schematic diagram of the second vac sorb loop and the first pneumatic circuit.

Fig. 7 is the annexation schematic diagram of this utility model cylinder slide unit and the second pneumatic circuit.

Fig. 8 is the annexation schematic diagram of this utility model computer and other each parts.

Fig. 9 is the structural representation of existing resistance strain plate.

Description of reference numerals:

1 upper plate; 2 adsorption head mounting boxs; 3 connecting plates;

4 cylinder slide units; 5 proximity switches; 6 cylinder slide unit installing plates;

7 ball-screw slide units; 8 lower shoes; 9 sorting boxes;

9-1 A class foil gauge sorting box; 9-2 B class foil gauge sorting box;

9-3 C class foil gauge sorting box; 9-4 D class foil gauge sorting box;

9-5 E class foil gauge sorting box; 10 Y-axis moving grating chis; 11 two-dimensional movement platforms;

12 X-axis moving grating chis; 13 vac sorb heads; 13-1 vac sorb pipe;

13-2 rubber suction nozzle; 13-3 connecting tube; 14 vacuum adsorption table;

14-1 absorptive table lower cover; 14-2 absorptive table upper cover; 14-3 adsorption hole;

14-4 sealing gasket; 14-5 absorptive table connecting bolt; 14-6 screwed hole;

14-7 projection; 14-8 reference location line; 15 big array resistors formula foil gauge diaphragms;

16 y-axis stepper motors; 17 X-axis motors;18 triangle connecting racks;

19 aluminium section bars; 20 first air pumps; 21 first air filters;

22 first air relief valve; 23 first air gauges; 24 first tracheas;

25 second vacuum pumps; 26 second vacuum filters; 27 second vacuums regulate valve;

28 second vacuum meters; 29 first air-operated solenoid valves; 30 second vacuum solenoids;

31 first vacuum tubes; 32 first vacuum pumps; 33 first vacuum filters;

34 first vacuums regulate valve; 35 first vacuum solenoids; 36 first vacuum meters;

37 computers; 38 data collecting plate cards; 39 output amplification boards;

40 second tracheas; 41 the 3rd vacuum tubes; 42 the 3rd tracheas;

43 second air pumps; 44 second air filters; 45 second air relief valve;

46 second Pressure gauges; 47 second air-operated solenoid valves; 48 motors;

49 pneumatic joints; 50 sensitive grids; 51 substrates;

52 cover layers; 53 lead-in wires; 54 binding agents;

55 second vacuum tubes.

Detailed description of the invention

As illustrated in figures 1 and 8, big array resistors formula foil gauge automatic sorting device of the present utility model, including frame, location fixed mechanism, absorption sorting mechanism, location sorting mechanism and computer 37, being connected to data collecting plate card 38 on described computer 37, the signal output part of described data collecting plate card 38 is connected to output amplification board 39;

Described frame includes upper and lower spaced upper plate 1 and lower shoe 8, and is supported on the pillar between upper plate 1 and lower shoe 8;

Described location fixed mechanism includes the two-dimensional movement platform 11 being arranged on lower shoe 8 top, it is arranged on the vacuum adsorption table 14 at two-dimensional movement platform 11 top and for the first vac sorb loop to vacuum adsorption table 14 evacuation, described two-dimensional movement platform 11 includes X-axis mobile motor 17, Y-axis mobile motor 16, X-axis moving grating chi 12 and Y-axis moving grating chi 10, in conjunction with Fig. 2, described vacuum adsorption table 14 includes mutually fastening and the fixing absorptive table lower cover 14-1 connected and absorptive table upper cover 14-2, it is vacuum chamber that described absorptive table lower cover 14-1 and absorptive table upper cover 14-2 fastens the space formed, the upper surface of described absorptive table upper cover 14-2 is provided with the adsorption hole 14-3 of multiple spread configuration, in conjunction with Fig. 3, first vacuum pump the 32, first vacuum filter the 33, first vacuum that described first vac sorb loop includes by the first vacuum tube 31 is sequentially connected with regulates valve 34 and the first vacuum solenoid 35, described first vacuum tube 31 is connected with described vacuum chamber, and described first vacuum regulates and is connected to the first vacuum meter 36 on valve 34, described X-axis moving grating chi 12 and Y-axis moving grating chi 10 are all connected with the signal input part of data collecting plate card 38, and described X-axis mobile motor 17, Y-axis mobile motor 16 and the first vacuum solenoid 35 are all connected with the outfan of output amplification board 39,

In conjunction with Fig. 4 and Fig. 5, described absorption sorting mechanism includes adsorption head mounting box 2 and is arranged in adsorption head mounting box 2 and multiple vac sorb heads 13 of adsorption head mounting box 2 are stretched out in lower end, and for making multiple vac sorb head 13 produce the second vac sorb loop of negative-pressure adsorption function and for making multiple vac sorb head 13 produce the first pneumatic circuit of blowing function; Distance between adjacent two vac sorb heads 13 is equal with the distance between adjacent two adsorption hole 14-3, described vac sorb head 13 includes the vac sorb pipe 13-1 through adsorption head mounting box 2 diapire, described vac sorb pipe 13-1 is exposed at bottom the one end bottom adsorption head mounting box 2 to be set with rubber suction nozzle 13-2, and one end that described vac sorb pipe 13-1 is positioned within adsorption head mounting box 2 is connected to connecting tube 13-3;In conjunction with Fig. 6, second vacuum pump the 25, second vacuum filter the 26, second vacuum that described second vac sorb loop includes by the second vacuum tube 55 is sequentially connected with regulates valve the 27, second vacuum meter 28 and Duo Gen the 3rd vacuum tube 41, and every described 3rd vacuum tube 41 is respectively connected with the second vacuum solenoid 30; Described first pneumatic circuit includes the first air pump the 20, first air filter the 21, first air relief valve the 22, first air gauge 23 and Duo Gen the second trachea 40 being sequentially connected with by the first trachea 24, and every described second trachea 40 is respectively connected with the first air-operated solenoid valve 29; The connecting tube 13-3 of each described vac sorb head 13 is connected with the 3rd vacuum tube 41 and second trachea 40 each through threeway; Multiple second vacuum solenoids 30 and multiple first air-operated solenoid valve 29 are all connected with the outfan of output amplification board 39; Described second vac sorb loop is used for making vac sorb head 13 produce negative-pressure adsorption function, picks up resistance strain plate, and described first pneumatic circuit is used for making vac sorb head 13 produce blowing function, and blow off resistance strain plate.

Described location sorting mechanism includes the ball-screw slide unit 7 being horizontally set on upper plate 1 top and is vertically arranged in the cylinder slide unit 4 below upper plate 1, and second pneumatic circuit, described ball-screw slide unit 7 includes the motor 48 for driving ball-screw to move, the slide unit of described ball-screw slide unit 7 is connected to cylinder slide unit installing plate 6, described cylinder slide unit 4 is arranged on cylinder slide unit installing plate 6, described adsorption head mounting box 2 is connected with the slide unit of cylinder slide unit 4 by connecting plate 3, described upper plate 1 is disposed with seven proximity switches 5 being positioned at ball-screw slide unit 7 side, described lower shoe 8 is provided with sorting box 9, five sorting chambers it are provided with in described sorting box 9, five described sorting chamber respectively A class foil gauge sorting chamber 9-1, B class foil gauge sorting chamber 9-2, C class foil gauge sorting chamber 9-3, D class foil gauge sorting chamber 9-4 and E class foil gauge sorting chamber 9-5, two of which in seven proximity switches 5 lays respectively at original position and the final position of the slide unit motion of ball-screw slide unit 7, other five one_to_one corresponding in seven proximity switches 5 are positioned at the surface of five sorting chambers, in conjunction with Fig. 7, described second pneumatic circuit includes the second air pump the 43, second air filter the 44, second air relief valve 45 and the second Pressure gauge 46 being sequentially connected with by the 3rd trachea 42, and described cylinder slide unit 4 is connected with the 3rd trachea 42 by the second air-operated solenoid valve 47, seven described proximity switches 5 are all connected with the signal input part of data collecting plate card 38, and described motor 48 and the second air-operated solenoid valve 47 are all connected with the outfan of output amplification board 39. when being embodied as, described ball-screw slide unit 7 is bolted to connection at upper plate 1 top, cylinder slide unit installing plate 6 is connected by bolt is fixing with the slide unit of ball-screw slide unit 7, connecting plate 3 is connected by bolt is fixing with the slide unit of cylinder slide unit 4, and described adsorption head mounting box 2 is connected by bolt is fixing with connecting plate 3.

As shown in Figure 1, in the present embodiment, described pillar is made up of the many aluminium section bars 19 connecting into frame structure, described aluminium section bar 19 is connected by triangle connecting rack 18 is fixing with aluminium section bar 19, described aluminium section bar 19 is connected by screw bolt and nut is fixing with upper plate 1, and described aluminium section bar 19 is fixed with lower shoe 8 be connected by bolt, nut and triangle connecting rack 18.

As shown in Figure 2, in the present embodiment, it is provided with sealing gasket 14-4 between described absorptive table lower cover 14-1 and absorptive table upper cover 14-2, described absorptive table lower cover 14-1, sealing gasket 14-4 and absorptive table upper cover 14-2 connect by absorptive table connecting bolt 14-5 is fixing, the side of described absorptive table lower cover 14-1 is provided with screwed hole 14-6, and described first vacuum tube 31 is connected with screwed hole 14-6 by pneumatic joint 49. The upper surface of described absorptive table upper cover 14-2 is provided with a plurality of level to groove and a plurality of vertically to groove, a plurality of described level defines multiple projection 14-7 to groove and a plurality of described vertically intersecting to groove, and multiple described adsorption hole 14-3 are distributed on multiple projection 14-7; Described absorptive table upper cover 14-2 upper surface be shaped as rectangle, four feet of described absorptive table upper cover 14-2 upper surface are all carved with reference location line 14-8. By arranging sealing gasket 14-4, it is possible to avoid the gap air leak between absorptive table lower cover 14-1 and absorptive table upper cover 14-2, needed for affecting described vacuum chamber, vacuum is quickly formed and keeps; By arranging reference location line 14-8, facilitate and big array resistors formula foil gauge diaphragm is accurately positioned.

In the present embodiment, the model of described data collecting plate card 38 is NIPCI6509, and the model of described output amplification board 39 is HSF16M.

Work process of the present utility model is:

Step one, detected to be placed to the big array resistors formula foil gauge diaphragm 15 in vacuum adsorption table 14 after, proceed by sorting, when being embodied as, the testing result of big array resistors formula foil gauge diaphragm 15 is stored in computer 37, the table 3 that examination criteria is based in GB/T13992-92 " strain ga(u)ge " standard in the 5th chapters and sections 5.1 trifle is formulated, sensitivity coefficient regulation according to the resistance that sequence number is 5.1.1 and 5.1.2, resistance strain plate is divided into A quasi-resistance foil gauge (representing by storage data 0001), B quasi-resistance foil gauge (represents by storage data 0010), C quasi-resistance foil gauge (represents by storage data 0011), D quasi-resistance foil gauge (represents by storage data 0100) and defective resistance strain gage (representing by storage data 0000), and defective resistance strain gage is defined as E quasi-resistance foil gauge.

Step 2, sorting location, detailed process is:

Step 201, data collecting plate card 38 export signal drive stepping motor 48 by output amplification board 39 and rotate, ball-screw slide unit 7 is by cylinder slide unit installing plate 6 band dynamic air cylinder slide unit 4 and described absorption sorting mechanism horizontal movement, until the proximity switch 5 being positioned at the final position of the slide unit motion of ball-screw slide unit 7 detects stop motion after signal;

Step 202, data collecting plate card 38 export signal by output amplification board 39 and drive the second air-operated solenoid valve 47 to open, cylinder slide unit 4 drives described absorption sorting mechanism to move downward by connecting plate 3, makes multiple vac sorb head 13 arrive the first group of resistance-strain blade unit place to sort;

Step 3, sorting absorption, detailed process is:

Step 301, data collecting plate card 38 export signal by output amplification board 39 and drive the second vacuum solenoid 30 to open, and the second vacuum pump 25 evacuation makes multiple vac sorb head 13 produce first group of resistance-strain blade unit of negative-pressure adsorption;

Step 302, data collecting plate card 38 export signal by output amplification board 39 and drive the second air-operated solenoid valve 47 to commutate, and cylinder slide unit 4 drives described absorption sorting mechanism to move upward by connecting plate 3, until the cylinder piston rod of cylinder slide unit 4 is fully retracted;

Step 4, A quasi-resistance foil gauge sort, and detailed process is:

Step 401, data collecting plate card 38 export signal drive stepping motor 48 by output amplification board 39 and rotate, ball-screw slide unit 7 by cylinder slide unit installing plate 6 band dynamic air cylinder slide unit 4 and described absorption sorting mechanism to step 201 opposite direction horizontal movement, until being positioned at the proximity switch 5 directly over A class foil gauge sorting chamber 9-1 stop motion after signal to be detected;

Step 402, data collecting plate card 38 export signal by output amplification board 39 and drive the second air-operated solenoid valve 47 to open, cylinder slide unit 4 drives described absorption sorting mechanism to move downward by connecting plate 3, makes multiple vac sorb head 13 arrive the position that distance is 3mm��5mm with sorting box 9;

The testing result of each resistance strain gage in its first group of resistance-strain blade unit prestored transferred by step 403, computer 37, select resistance strain gage that testing result is A class and output signal to data collecting plate card 38, data collecting plate card 38 exports the second vacuum solenoid 30 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is A class and closes by exporting amplification board 39, makes the negative pressure of the vac sorb head 13 of the A quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption eliminate; When being embodied as, select the resistance strain gage that testing result is A class, be the resistance strain gage that testing result is 0001 selecting storage;

Step 404, data collecting plate card 38 export the first air-operated solenoid valve 29 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is A class and open by exporting amplification board 39, the vac sorb head 13 making the A quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption is blown, and is blown into by the A quasi-resistance foil gauge in first group of resistance-strain blade unit in A class foil gauge sorting chamber 9-1;

Step 5, B quasi-resistance foil gauge sort, and detailed process is:

Step 501, data collecting plate card 38 export signal drive stepping motor 48 by output amplification board 39 and rotate, ball-screw slide unit 7 by cylinder slide unit installing plate 6 band dynamic air cylinder slide unit 4 and described absorption sorting mechanism to step 201 opposite direction horizontal movement, until being positioned at the proximity switch 5 directly over B class foil gauge sorting chamber 9-2 stop motion after signal to be detected;

The testing result of each resistance strain gage in its first group of resistance-strain blade unit prestored transferred by step 502, computer 37, select resistance strain gage that testing result is B class and output signal to data collecting plate card 38, data collecting plate card 38 exports the second vacuum solenoid 30 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is B class and closes by exporting amplification board 39, makes the negative pressure of the vac sorb head 13 of the B quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption eliminate; When being embodied as, select the resistance strain gage that testing result is B class, be the resistance strain gage that testing result is 0010 selecting storage;

Step 503, data collecting plate card 38 export the first air-operated solenoid valve 29 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is B class and open by exporting amplification board 39, the vac sorb head 13 making the B quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption is blown, and is blown into by the B quasi-resistance foil gauge in first group of resistance-strain blade unit in B class foil gauge sorting chamber 9-2;

Step 6, C quasi-resistance foil gauge sort, and detailed process is:

Step 601, data collecting plate card 38 export signal drive stepping motor 48 by output amplification board 39 and rotate, ball-screw slide unit 7 by cylinder slide unit installing plate 6 band dynamic air cylinder slide unit 4 and described absorption sorting mechanism to step 201 opposite direction horizontal movement, until being positioned at the proximity switch 5 directly over C class foil gauge sorting chamber 9-3 stop motion after signal to be detected;

The testing result of each resistance strain gage in its first group of resistance-strain blade unit prestored transferred by step 602, computer 37, select resistance strain gage that testing result is C class and output signal to data collecting plate card 38, data collecting plate card 38 exports the second vacuum solenoid 30 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is C class and closes by exporting amplification board 39, makes the negative pressure of the vac sorb head 13 of the C quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption eliminate; When being embodied as, select the resistance strain gage that testing result is C class, be the resistance strain gage that testing result is 0011 selecting storage;

Step 603, data collecting plate card 38 export the first air-operated solenoid valve 29 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is C class and open by exporting amplification board 39, the vac sorb head 13 making the C quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption is blown, and is blown into by the C quasi-resistance foil gauge in first group of resistance-strain blade unit in C class foil gauge sorting chamber 9-3;

Step 7, D quasi-resistance foil gauge sort, and detailed process is:

Step 701, data collecting plate card 38 export signal drive stepping motor 48 by output amplification board 39 and rotate, ball-screw slide unit 7 by cylinder slide unit installing plate 6 band dynamic air cylinder slide unit 4 and described absorption sorting mechanism to step 201 opposite direction horizontal movement, until being positioned at the proximity switch 5 directly over D class foil gauge sorting chamber 9-4 stop motion after signal to be detected;

The testing result of each resistance strain gage in its first group of resistance-strain blade unit prestored transferred by step 702, computer 37, select resistance strain gage that testing result is D class and output signal to data collecting plate card 38, data collecting plate card 38 exports the second vacuum solenoid 30 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is D class and closes by exporting amplification board 39, makes the negative pressure of the vac sorb head 13 of the D quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption eliminate; When being embodied as, select the resistance strain gage that testing result is D class, be the resistance strain gage that testing result is 0100 selecting storage;

Step 703, data collecting plate card 38 export the first air-operated solenoid valve 29 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is D class and open by exporting amplification board 39, the vac sorb head 13 making the D quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption is blown, and is blown into by the D quasi-resistance foil gauge in first group of resistance-strain blade unit in D class foil gauge sorting chamber 9-4;

Step 8, E quasi-resistance foil gauge sort, and detailed process is:

Step 801, data collecting plate card 38 export signal drive stepping motor 48 by output amplification board 39 and rotate, ball-screw slide unit 7 by cylinder slide unit installing plate 6 band dynamic air cylinder slide unit 4 and described absorption sorting mechanism to step 201 opposite direction horizontal movement, until being positioned at the proximity switch 5 directly over E class foil gauge sorting chamber 9-5 stop motion after signal to be detected;

The testing result of each resistance strain gage in its first group of resistance-strain blade unit prestored transferred by step 802, computer 37, select resistance strain gage that testing result is E class and output signal to data collecting plate card 38, data collecting plate card 38 exports the second vacuum solenoid 30 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is E class and closes by exporting amplification board 39, makes the negative pressure of the vac sorb head 13 of the E quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption eliminate; When being embodied as, select the resistance strain gage that testing result is E class, be the resistance strain gage that testing result is 0000 selecting storage;

Step 803, data collecting plate card 38 export the first air-operated solenoid valve 29 of signal driving vac sorb head 13 connection corresponding with the resistance strain gage that testing result is E class and open by exporting amplification board 39, the vac sorb head 13 making the E quasi-resistance foil gauge in first group of resistance-strain blade unit of absorption is blown, and is blown into by the E quasi-resistance foil gauge in first group of resistance-strain blade unit in E class foil gauge sorting chamber 9-5;

Step 9, sorting location, detailed process is next time:

Step 901, data collecting plate card 38 export signal by output amplification board 39 and drive the second air-operated solenoid valve 47 to commutate, and cylinder slide unit 4 drives described absorption sorting mechanism to move upward by connecting plate 3, until the cylinder piston rod of cylinder slide unit 4 is fully retracted;

Step 902, data collecting plate card 38 export signal drive stepping motor 48 by output amplification board 39 and rotate, ball-screw slide unit 7 is by cylinder slide unit installing plate 6 band dynamic air cylinder slide unit 4 and described absorption sorting mechanism horizontal movement, until the proximity switch 5 being positioned at the final position of the slide unit motion of ball-screw slide unit 7 detects stop motion after signal;

Step 903, data collecting plate card 38 export signal driving Y-axis mobile motor 16 by exporting amplification board 39, Y-axis mobile motor 16 drives vacuum adsorption table 14 to move, displacement is fed back to computer 37 by data collecting plate card 38 by Y-axis moving grating chi 10, until stopping after moving the width distance of one group of resistance-strain blade unit;

Step 904, data collecting plate card 38 export signal by output amplification board 39 and drive the second air-operated solenoid valve 47 to open, cylinder slide unit 4 drives described absorption sorting mechanism to move downward by connecting plate 3, makes multiple vac sorb head 13 arrive next the group resistance-strain blade unit place to sort;

Repeat step 3 to step 9, until all of resistance-strain blade unit has sorted.

When being embodied as, after having sorted, data collecting plate card 38 exports signal drive stepping motor 48 by output amplification board 39 and rotates, ball-screw slide unit 7 is by cylinder slide unit installing plate 6 band dynamic air cylinder slide unit 4 and described absorption sorting mechanism horizontal movement, until the proximity switch 5 being positioned at the original position of the slide unit motion of ball-screw slide unit 7 detects stop motion after signal.

The above; it it is only preferred embodiment of the present utility model; not this utility model is imposed any restrictions; every any simple modification, change and equivalent structure change above example made according to this utility model technical spirit, all still falls within the protection domain of technical solutions of the utility model.

Claims (5)

1. a big array resistors formula foil gauge automatic sorting device, it is characterized in that: include frame, location fixed mechanism, absorption sorting mechanism, location sorting mechanism and computer (37), being connected to data collecting plate card (38) on described computer (37), the signal output part of described data collecting plate card (38) is connected to output amplification board (39);

Described frame includes upper and lower spaced upper plate (1) and lower shoe (8), and is supported on the pillar between upper plate (1) and lower shoe (8);

Described location fixed mechanism includes the two-dimensional movement platform (11) being arranged on lower shoe (8) top, it is arranged on the vacuum adsorption table (14) at two-dimensional movement platform (11) top and for the first vac sorb loop to vacuum adsorption table (14) evacuation, described two-dimensional movement platform (11) includes X-axis mobile motor (17), Y-axis mobile motor (16), X-axis moving grating chi (12) and Y-axis moving grating chi (10), described vacuum adsorption table (14) includes mutually fastening and fix the absorptive table lower cover (14-1) and absorptive table upper cover (14-2) that connect, it is vacuum chamber that described absorptive table lower cover (14-1) and absorptive table upper cover (14-2) fasten the space formed, the upper surface of described absorptive table upper cover (14-2) is provided with the adsorption hole (14-3) of multiple spread configuration, the first vacuum pump (32) that described first vac sorb loop includes being sequentially connected with by the first vacuum tube (31), the first vacuum filter (33), the first vacuum regulate valve (34) and the first vacuum solenoid (35), described first vacuum tube (31) is connected with described vacuum chamber, and described first vacuum regulates and is connected to the first vacuum meter (36) on valve (34), described X-axis moving grating chi (12) and Y-axis moving grating chi (10) are all connected with the signal input part of data collecting plate card (38), and described X-axis mobile motor (17), Y-axis mobile motor (16) and the first vacuum solenoid (35) are all connected with the outfan of output amplification board (39),

Multiple vac sorb heads (13) of adsorption head mounting box (2) are stretched out in described absorption sorting mechanism includes adsorption head mounting box (2) and is arranged in adsorption head mounting box (2) and lower end, and are used for making multiple vac sorb head (13) produce the second vac sorb loop of negative-pressure adsorption function and be used for the first pneumatic circuit making multiple vac sorb head (13) produce blowing function; Distance between adjacent two vac sorb heads (13) is equal with the distance between adjacent two adsorption holes (14-3), described vac sorb head (13) includes the vac sorb pipe (13-1) through adsorption head mounting box (2) diapire, described vac sorb pipe (13-1) is exposed at bottom one end of adsorption head mounting box (2) bottom and is set with rubber suction nozzle (13-2), and one end that described vac sorb pipe (13-1) is positioned at adsorption head mounting box (2) internal is connected to connecting tube (13-3); Described second vac sorb loop includes the second vacuum pump (25), the second vacuum filter (26), the second vacuum adjustment valve (27), the second vacuum meter (28) and many 3rd vacuum tubes (41) that are sequentially connected with by the second vacuum tube (55), and every described 3rd vacuum tube (41) is respectively connected with the second vacuum solenoid (30); Described first pneumatic circuit includes the first air pump (20), the first air filter (21), the first air relief valve (22), the first air gauge (23) and many second tracheas (40) that are sequentially connected with by the first trachea (24), and every described second trachea (40) is respectively connected with the first air-operated solenoid valve (29); The connecting tube (13-3) of each described vac sorb head (13) is connected with the 3rd vacuum tube (41) and second trachea (40) each through threeway; Multiple second vacuum solenoids (30) and multiple first air-operated solenoid valve (29) are all connected with the outfan of output amplification board (39);

Described location sorting mechanism includes the ball-screw slide unit (7) being horizontally set on upper plate (1) top and the cylinder slide unit (4) being vertically arranged in upper plate (1) lower section, and second pneumatic circuit, described ball-screw slide unit (7) includes the motor (48) for driving ball-screw to move, the slide unit of described ball-screw slide unit (7) is connected to cylinder slide unit installing plate (6), described cylinder slide unit (4) is arranged on cylinder slide unit installing plate (6), described adsorption head mounting box (2) is connected by the slide unit of connecting plate (3) with cylinder slide unit (4), described upper plate (1) is disposed with seven proximity switches (5) being positioned at ball-screw slide unit (7) side, described lower shoe (8) is provided with sorting box (9), five sorting chambers it are provided with in described sorting box (9), five described sorting chamber respectively A class foil gauge sorting chambers (9-1), B class foil gauge sorting chamber (9-2), C class foil gauge sorting chamber (9-3), D class foil gauge sorting chamber (9-4) and E class foil gauge sorting chamber (9-5), two of which in seven proximity switches (5) lays respectively at original position and the final position of the slide unit motion of ball-screw slide unit (7), other five one_to_one corresponding in seven proximity switches (5) are positioned at the surface of five sorting chambers,Described second pneumatic circuit includes the second air pump (43), the second air filter (44), the second air relief valve (45) and the second Pressure gauge (46) that are sequentially connected with by the 3rd trachea (42), and described cylinder slide unit (4) is connected with the 3rd trachea (42) by the second air-operated solenoid valve (47); Seven described proximity switches (5) are all connected with the signal input part of data collecting plate card (38), and described motor (48) and the second air-operated solenoid valve (47) are all connected with the outfan of output amplification board (39).

2. the big array resistors formula foil gauge automatic sorting device described in claim 1, it is characterized in that: described pillar is made up of the many aluminium section bars (19) connecting into frame structure, described aluminium section bar (19) is connected by triangle connecting rack (18) is fixing with aluminium section bar (19), described aluminium section bar (19) is connected by screw bolt and nut is fixing with upper plate (1), and described aluminium section bar (19) is connected by bolt, nut and triangle connecting rack (18) are fixing with lower shoe (8).

3. the big array resistors formula foil gauge automatic sorting device described in claim 1, it is characterized in that: between described absorptive table lower cover (14-1) and absorptive table upper cover (14-2), be provided with sealing gasket (14-4), described absorptive table lower cover (14-1), sealing gasket (14-4) and absorptive table upper cover (14-2) connect by absorptive table connecting bolt (14-5) is fixing, the side of described absorptive table lower cover (14-1) is provided with screwed hole (14-6), described first vacuum tube (31) is connected with screwed hole (14-6) by pneumatic joint (49).

4. the big array resistors formula foil gauge automatic sorting device described in claim 1, it is characterized in that: the upper surface of described absorptive table upper cover (14-2) is provided with a plurality of level to groove and a plurality of vertically to groove, a plurality of described level defines multiple projection (14-7) to groove and a plurality of described vertically intersecting to groove, and multiple described adsorption holes (14-3) are distributed on multiple projection (14-7); Described absorptive table upper cover (14-2) upper surface be shaped as rectangle, four feet of described absorptive table upper cover (14-2) upper surface are all carved with reference location line (14-8).

5. the big array resistors formula foil gauge automatic sorting device described in claim 1, it is characterised in that: the model of described data collecting plate card (38) is NIPCI6509, and the model of described output amplification board (39) is HSF16M.