CN203241251U - Lever-type dynamic load test bed with adjustable load - Google Patents

Abstract

The utility model discloses a lever-type dynamic load test bed with an adjustable load, which is suitable for performing a loading detection test on products such as hand-pulling blocks of hoisting machinery. According to the lever-type dynamic load test bed with the adjustable load, a complete integrated system with the adjustable load is realized by adopting a special lever with the adjustable load and matched framework and external force source, applying a principle that the product of a force and a force arm is equal to the product of a weight and a weight arm, changing the transfer direction of the force by a fixed pulley, and changing the transfer speed and magnitude of the force via a movable pulley; and test and detection for products with different specifications are realized by meeting the needs of different test loads by adjusting the lengths, distance and positions of the force arm and the weight arm. The lever-type dynamic load test bed with the adjustable load has the advantages of being economic, safe and reliable, simple and convenient to operate, capable of meeting detection standard requirements on a tested element and increasing work efficiency, and the like, and the problem of adjustment during test on series products on the same test bed under different loads with different specifications is solved; and the problems of large original floor area, high cost, many weights, difficult operation, low efficiency, inconformity between the original hydraulic loading condition and an actual working condition, high expense, difficult maintenance, and the like are solved.

Description

Lever is adjustable load dynamic test platform

Technical field

The utility model discloses the adjustable load dynamic test of a kind of lever platform, belong to dynamic load detection technique field, be used for product is loaded test, accurately load-bearing capacity and the Practical Performance of testing product are particularly suitable for hoisting machinery series products (such as chain block and associated class product thereof) is loaded the detection test.

Background technology

The quality security problem of product is the lifeline problem of product, does not have product that safety makes basic guarantee just as not having lived people, and market can not circulate at all.

Product safety is related to too many aspect, how to guarantee that product safety is reliable, is society problem in the urgent need to address, and is significant, and particularly the safety of hoisting machinery series products directly can have influence on people's life security, is must problems of concern.

At present, the quality safety Check and Inspection is carried out to product in the hand operated hoist field, employing be that test product (tested spare) is carried out dynamic test, or type approval test.These two kinds of test methods all are to adopt the method for directly heavily cutting or polish jade with an emery wheel of the actual applying working condition of simulation (also have under a few cases, adopt the hydraulic loaded method) usually.The testing table that the direct heavily method of cutting or polish jade with an emery wheel adopts, structure as shown in Figure 1, girder 5 supports fixing by many supports 21, be mounted with a plurality of upper pendants 22 on the girder 5, each upper pendant 22 corresponding external force source (heavily stone roller) 10 that are placed on lower first floor, the difference of heavily cutting or polish jade with an emery wheel according to the required detection tonnage of different test products quantity is divided into different weight grades, from a little tonnage to tens ton to tons up to a hundred etc., tested spare 15 upper ends are articulated on the upper pendant 22, tested spare 15 lifting force ends are linked up with and are heavily articulated on the stone roller, tested spare 15 force sides 17 are under the acting force of drive unit 16, the heavily stone roller of a certain tonnage is mentioned, finish the repeatedly Work condition analogue experiment that the different tonnages of different number of times are heavily cut or polish jade with an emery wheel, test the other end from an end of two floor plates 23, obtain the difference of tested spare 15 under the different loads effect and detect data.Although directly heavily the method for cutting or polish jade with an emery wheel has the characteristics of Simple visual, exist that floor area is large, cost is high, use heavily stone roller many, transfer the bothersome effort of stone roller, efficient low, check with final assembly packaging that to be connected not smooth etc. one be the class problem; If it is not directly perceived that the hydraulic loaded method testing table under the employing a few cases also exists, loaded condition and actual condition are not inconsistent, and cost and maintenance cost are high, and maintenance difficulty is large, and hydralic pressure gauge is difficult to the problems such as truth that reflection loads.For above-mentioned present actual conditions, in the urgent need to people work out early a kind of more advanced, simplify easy row, easy to operate, strong adaptability and can satisfy again the testing table that test standard etc. requires, finally to satisfy people to the safe and reliable and cheap actual demand of lifting series products.

The purpose of this utility model provides the adjustable load dynamic test of a kind of lever platform, it has wide accommodation, takes up an area less, cost is low, economical and practical, safe and reliable, easy and simple to handle, intuitively laborsaving, not only satisfied the requirement of tested spare examination criteria but also can reach the characteristics that improve work efficiency, are convenient to automation engineering reproduction etc.

Summary of the invention

The purpose of this utility model is achieved in that the adjustable load dynamic test of a kind of lever platform, it has lever, head tree, column, girder, the upper hanger device, the upper hanger hook, lower hanging frame device, coupling components, the flexible connection that intersects vertically of head tree lower end and lever, the head tree upper end intersects vertically with girder and is fixedly connected with, the column that girder is played stable support function is parallel to head tree and installs fixing, lever arm of force side and weighing arm side are installed with lower hanging frame device, on the girder of corresponding lever arm of force side the upper hanger device is installed, be fixed wtih fixed pulley and multiple-grooved fixed pulley on the girder of corresponding gravity arm of lever side, through the coupling components one termination upper hanger hook of fixed pulley and multiple-grooved fixed pulley, another termination external force source;

Wherein, the lower hanging frame device of gravity arm of lever side can be one, two, three or a plurality of;

The quantity of the quantity of upper hanger hook and the lower hanging frame device of position and gravity arm of lever side and position be Corresponding matching one by one;

The lower hanging frame device of lever arm of force side can be one, two, three or a plurality of;

The quantity of the lower hanging frame device of the quantity of upper hanger device and position and lever arm of force side and position be Corresponding matching one by one;

Column has three, supports respectively the both sides that are fixedly mounted on girder;

The external force source can be heavily to cut or polish jade with an emery wheel;

Be the transporting rail that is arranged in parallel by stent support with girder, at the diverse location of transporting rail the adjustable load dynamic test of lever described in the utility model platform can be arranged;

Transporting rail can be loop configuration;

Can be fixedly connected with by crossbeam between head tree and the girder;

Also can be fixedly connected with by crossbeam between column and the girder;

The external force source can be the bottom that is articulated in a travelling block, and link is by fixing behind the travelling block;

Travelling block (multiple-grooved) can form pulley blocks with a multiple-grooved fixed pulley on the girder.

The utility model has the advantages that: because structure described in the utility model has adopted the special lever of adjustable load, in addition supporting framework and external force source, cleverly Integral combined structure; The direction of transfer travelling block that utilization power takes advantage of the arm of force to equal heavily to take advantage of weighing arm and fixed pulley to change power changes the total system of transmission speed and the complete adjustable load that size realizes of power; Realize satisfying the needs of different tests load by the length distance of adjusting the arm of force and weighing arm with the position, thereby realize test and the detection of products of different specifications; So that the utility model is very handy, economical and practical, safe and reliable, easy and simple to handle, not only satisfy the requirement of test specimen examination criteria but also reach the purpose that improves work efficiency.It can be pressed standard-required at same device and detect the whole series of products of test, and is easy to adjust simple, the floor area less; Have the characteristics such as novelty, advanced person, applicable, reliable, directly perceived, easy to operate and easy care; It not only similar directly heavily the stone roller method simulated actual condition, satisfy the test standard requirement, also have the dirigibility of adjustable load, applied widely; Apply in the test of lifting series products, can satisfy the testing requirements of " chain block " and Related product thereof fully; Solved the adjusting problem under the different size different loads in same rig-testing series of products; Solved and originally cut or polish jade with an emery wheel heavily directly that method testing table floor area is large, cost is high, used heavily stone roller many, transfer stone roller bothersomely to require great effort, the problem such as efficient is low; The loaded condition and the actual condition that have solved original hydraulic loaded method testing table existence are not inconsistent yet, and cost and maintenance cost are high, and maintenance difficulty is large, and hydralic pressure gauge is difficult to the problems such as truth that reflection loads;

If it all is continuously adjustable stress point structure that the utility model is designed to both arms with lever and girder, then can realize the test to any rated load product, solved the reality of the bad realization of original technology;

If the utility model adopts the structure that lever arm of force side slide slot, gravity arm of lever side slide slot, girder both sides slide slot can combination in any, the meeting that the one-piece construction assembly is used still less, whole testing table is simpler and clearer, more helps omnidistance industrial automation flowing water to reproduce;

The design of column on diverse location that the utility model adopts, selecting of crossbeam, needle beam all ensured test platform stablizing under various operating condition of test better;

The structure of single heavy stone roller is selected in the utility model external force source, compare with original weight stone roller law technology scheme, not only greatly reduced the use of iron and steel, also greatly reduced floor area, compare with original hydraulic method simple and clear, heavily the stone roller use so that the utility model testing table has more the visual and clear advantage that simply clearly waits;

Testing table described in the utility model is equipped with the structural design of transporting rail, formed a more complete new test platform, so that line production is formed, the test packaging line can conveniently be realized, and can finely turn round, solve the traditional experiment platform and be connected not smooth problem with final assembly packaging check;

The structure of the adjustable load dynamic test of a lever platform described in the utility model is suitable for the product of small-scale small serial production is detected test; Two adjustable load test platforms of lever are along transporting rail symmetric configuration structure, and are reasonable more economically; Many adjustable load test platforms of lever can satisfy the detection test demand of different operating modes and pipelining along the structure of transporting rail layout;

The testing table of new structure described in the utility model not only can be done the test of dispatching from the factory, and also can be used for the continuous performance test, braking ability test of type approval test etc.; Be equipped with suitable drive unit, can also test Related product, result of use is good;

To build testing table described in the utility model and to build the traditional experiment platform as example, both compare, and can find out that more the utility model has advantages of:

Build complete old-fashioned (directly heavily cutting or polish jade with an emery wheel a formula) testing table (referring to Fig. 1), approximately will take up an area about 250 square metres, comprise test site and final assembling, test package place; Need with more than 40 meter of 360 large-scale steel I-beam, more than 90 meter of 160 steel pipe, heavily cut or polish jade with an emery wheel about 55 tons, auxiliary steel more than 1.5 tons, 8 covers of drive unit and a plurality of assembly packaging hanger; Because the framework height also must make up two layer operation platforms; Also to dig simultaneously dark larger Tuo Keng; Carry out because test separates with packing, need to take in addition larger packing place, and will configure more assembly packaging hanger;

And build a testing table described in the utility model (lever) (referring to Fig. 5,7), and approximately to take up an area 100-120 square metre, comprised equally test and final packaging (carrying out at transmission line); Need with about 12 meters in 360 large-scale joist steel, about 25 meters of steel pipes, heavily to cut or polish jade with an emery wheel 10 tons, auxiliary steel and be all 1.5 tons, 2 covers of drive unit.Also need about 50 meters in 200 little joist steel for building transmission ring rail, build head tree and girder and need about 50 meters in 360 channel-section steels; Operate in ground and carry out, need not to build two-layer platform; Under ground portion is digged pit also shallow also little, and earth work is little;

Both compare, and the utility model testing table advantage is better than the old testing table of tradition greatly, take up an area and lack, and cost is low, and only the external force source is heavily cut or polish jade with an emery wheel one and just used less more than 40 ton of iron; Preresearch estimates, the described testing table of a playscript with stage directions utility model (two stations) can satisfy the delivery test needs of producing ten thousand of 20-25 per year; Lifting series products delivery test is occupied very consequence, and very crucial for product examination, quality assurance, the utility model testing table is being brought into play irreplaceable vital role in the production run of whole lifting series products.

Description of drawings

Fig. 1 is that prior art is directly heavily cut or polish jade with an emery wheel method testing table schematic diagram;

Fig. 2 is that the adjustable load dynamic test of lever described in the utility model platform master looks schematic diagram;

Fig. 3 is the adjustable load dynamic test of lever described in the utility model platform schematic top plan view;

Fig. 4 is that the adjustable load dynamic test of lever described in the utility model platform work condition state master looks schematic diagram;

Fig. 5 is that another structure of the adjustable load dynamic test of lever described in the utility model platform master looks schematic diagram;

Fig. 6 is another structure schematic top plan view of the adjustable load dynamic test of lever described in the utility model platform;

Fig. 7 is an again structure schematic top plan view of the adjustable load dynamic test of lever described in the utility model platform;

Fig. 8 is that another structure work condition state master of the adjustable load dynamic test of lever described in the utility model platform looks schematic diagram;

Fig. 9 is lever and lower hanging frame device connection diagram in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 10 is lever construction schematic diagram in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 11 is that the adjustable load dynamic test of lever described in the utility model platform middle girder master looks schematic diagram;

Figure 12 is the adjustable load dynamic test of lever described in the utility model platform middle girder schematic top plan view;

Figure 13 is the adjustable load dynamic test of lever described in the utility model platform middle girder schematic side view;

Figure 14 is that the head tree master looks schematic diagram in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 15 is head tree schematic side view in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 16 is head tree C-C sectional schematic diagram in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 17 is fixed pulley schematic diagram in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 18 is multiple-grooved fixed pulley schematic diagram in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 19 is the schematic diagram that the adjustable load dynamic test of lever described in the utility model platform has travelling block;

Figure 20 is the schematic diagram that the adjustable load dynamic test of lever described in the utility model platform has running block;

Figure 21 is an also structure schematic top plan view of the adjustable load dynamic test of lever described in the utility model platform;

Figure 22 is another structural representation of lever in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 23 is a lever structural representation again in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 24 is a lever structural representation also in the adjustable load dynamic test of the lever described in the utility model platform;

Figure 25 is another structural representation of the adjustable load dynamic test of lever described in the utility model platform middle girder;

Figure 26 is an again structural representation of the adjustable load dynamic test of lever described in the utility model platform middle girder;

Figure 27 is an also structural representation of the adjustable load dynamic test of lever described in the utility model platform middle girder;

Among the figure, the 1st, lever, the 2nd, head tree, the 3rd, column, the 4th, crossbeam, the 5th, girder, the 6th, the upper hanger device, the 7th, lower hanging frame device, the 8th, transporting rail, the 9th, coupling components, the 10th, the external force source, the 11st, needle beam, the 12nd, fixed pulley, the 13rd, the multiple-grooved fixed pulley, the 14th, the upper hanger hook, the 15th, tested spare, the 16th, drive unit, the 17th, tested spare force side, the 18th, lever strong point hole, the 19th, arm of force side mounting hole, the 20th, weighing arm side mounting hole, the 21st, support, the 22nd, upper pendant, the 23rd, floor, the 24th, multiple-grooved fixed pulley mounting hole, the 25th, head tree strong point hole, the 26th, upper hanger device mounting hole, the 27th, the fixed pulley mounting hole;

Below by accompanying drawing in conjunction with the embodiments, structure described in the utility model done described in further detail:

Embodiment

Embodiment 1

A kind of lever is adjustable load dynamic test platform, shown in Fig. 2,3,4, it has lever 1, head tree 2, column 3, girder 5, upper hanger device 6, upper hanger hook 14, lower hanging frame device 7, coupling components 9, external force source 10, fixed pulley 12, multiple-grooved fixed pulley 13;

As shown in figure 10, lever 1 one ends are arm of forces, and the other end is weighing arm, have arm of force side mounting hole 19 on the arm of force side, can be out one, two, three or a plurality of, and what the present embodiment was opened is five holes; The weighing arm side has weighing arm side mounting hole 20, can be out one, two, three or a plurality of, and what the present embodiment was opened is four holes; Lever strong point hole 18 is between the arm of force and weighing arm;

As shown in Figure 9, lower hanging frame device 7 is flexibly connected with lever 1 by arm of force side mounting hole 19 and weighing arm side mounting hole 20, hanging frame device 7 is used for connecting with tested spare 15 force sides under the arm of force side, and hanging frame device 7 is linked up with 14 by upper hanger and connected with external force source 10 under the weighing arm side, as shown in Figure 4;

Head tree 2 is important stressed members, and shown in Figure 14,15, head tree 2 lower ends have head tree strong point hole 25; Shown in Fig. 2,4, lever 1 and head tree 2 intersect vertically and lever 1 are loaded on the head tree 2 by the bearing in the supported hole with lever shaft, form to be flexibly connected; Shown in Figure 15,16, main force's post 2 can be relatively to be welded by two channel-section steels;

Head tree 2 bottoms firmly are connected with ground, form well basis, and head tree 2 tops intersect vertically with girder 5 by crossbeam 4 and are fixedly connected with, and in applying the process of external impacts, 4 pairs of girders 5 of crossbeam can play buffering decompression and firm effect; Or main force's post 2 tops directly are fixedly connected with girder 5;

Girder 5 is stressed members, shown in Figure 11,12,13, has upper hanger device mounting hole 26, fixed pulley mounting hole 27, multiple-grooved fixed pulley mounting hole 24 on the girder 5; Upper hanger device mounting hole 26 can be out one, two, three or a plurality of, and what the present embodiment was opened is five holes, and upper hanger device mounting hole 26 and lever arm of force side mounting hole 19 positions are Corresponding matching one by one, and the hole line is parallel to head tree 2 center lines up and down; Fixed pulley mounting hole 27 can be out one, two, three or a plurality of, and what the present embodiment was opened is four holes, and fixed pulley mounting hole 27 and gravity arm of lever side mounting hole 20 positions are Corresponding matching one by one, and the hole line is parallel to head tree 2 center lines up and down; Multiple-grooved fixed pulley mounting hole 24 also can be one, two or a plurality of, and the present embodiment is one;

Upper hanger device 6 is fixed on the girder 5 by upper hanger device mounting hole 26, and fixed pulley 12 is fixed on the girder 5 by fixed pulley mounting hole 27, and multiple-grooved fixed pulley 13 is fixed on the girder 5 by multiple-grooved fixed pulley mounting hole 24;

Upper hanger device 6 is for hanging tested spare 15, upper hanger hook 14 is to transmit the load that external force source 10 applies for connecting with the lower hanging frame device 7 of gravity arm of lever side, upper hanger hook 14 is connected with a coupling components 9, different coupling components 9 are through (shown in Figure 17,2,4) behind the different fixed pulleys 12, by same multiple-grooved fixed pulley 13 (shown in Figure 18,2,4), connect external force source 10, the external force source can be heavily to cut or polish jade with an emery wheel, in order to imposed load; Coupling components 9 can be wire rope or hoisting chain;

Column 3 is primary structure members, end at girder 5, or two ends, or there is column 3 many places of girder 5, and (the present embodiment is that the side at girder 5 has a root post 3, opposite side has two root posts 3), column 3 is parallel to head tree 2, one end of column 3 fixes on the ground, the other end can be fixedly connected with girder 5 by crossbeam 4, also can directly be fixedly connected with girder 5, the effect of column 3 is that support girder 5 guarantees that it is stable (in the present embodiment, the column 3 of one end is fixedly connected with girder 5 by crossbeam 4, and 3 one of two root posts of the other end directly are fixedly connected with girder 5, and another root also is to be fixedly connected with girder 5 by crossbeam 4), under external impacts, the crossbeam 4 that installs additional can play bumper and absorbing shock and stable effect to girder 5.

The adjustable load dynamic test of a kind of lever described in the utility model platform, operating mode is as follows:

As shown in Figure 4, at first, at the A place, tested spare 15 (as: linking up with on the tested chain block) is hung on the upper hanger device 6, lower hanging frame device 7 is connected with tested spare 15 force sides (tested chain block lower draw-bar), tested spare force side 17 (the manual gimmal of tested chain block) connects drive unit (drive unit can be windlass) 16, at the B place, upper hanger hook 14 and lower hanging frame device 7 are articulated, upper hanger hook 14 by coupling components 9 through C point fixed pulleys 12 and D point multiple-grooved fixed pulley 13 change directions at E place and external force source 10 (heavily cutting or polish jade with an emery wheel) the complete lever load system of formation that is hooked together.

When drive unit 16 starts, the 17 pulling test specimen entrys into service of tested spare force side, the lower hanging frame device 7 of lower hook pulling of test specimen, lever 1 arm of force side can rise thereupon, and lever 1 weighing arm side will move downward, at this moment the lower hanging frame device 7 drive upper hanger hooks 14 of gravity arm of lever side move down, upper hanger hook 14 passes to external force source 10 (heavily stone roller) to power by coupling components 9, and external force source 10 (heavily stone roller) is subjected to the lifting force effect to leave original position thereupon rising and leaves the end, stone roller hole; So just added power being delivered to tested spare 15 has got on, added pulling force during product testing that Here it is, the size of its pulling force depend on that position that tested spare 15 is hung is in the hanging point position at place on the lever arm of force side and external force source 10 (heavily stone roller) and is added in hanging point position on the gravity arm of lever side and the size of external force source power;

Namely, tested spare 15 is hung on the different position of lever 1 arm of force side, and hanging frame device 7 articulates under the upper hanger hook 14 that is in diverse location and the corresponding weighing arm side, forms different gravity levels, thereby can finish the different operating modes detection data to tested spare 15.

Can reach the purpose that realizes different tests load by different array modes and the adjustment in external force source 10 (heavily stone roller) own.

Embodiment 2

A kind of lever is adjustable load dynamic test platform, shown in Fig. 2,21,4, its structure and embodiment 1 structure are basic identical, and different only is that the adjustable load dynamic test of lever platform has two to be arranged in juxtaposition structure, also can be three, four, many and be arranged in juxtaposition structure.

Embodiment 3

A kind of lever is adjustable load dynamic test platform, shown in Fig. 5,6,8, its structure and embodiment 1 structure are basic identical, different only is, it also has transporting rail 8, transporting rail 8 is parallel to girder 5 fixed installations at a certain distance by the adjustable load dynamic test of lever platform, is supported by column 3, through needle beam 11 fixations.

Transporting rail 8 is transmission product and the assembly packaging product usefulness that finally completes, and transporting rail 8 comes transmission product by the hanger dolly on the ring rail, and transporting rail 8 can be annular, also can be other structures.

Embodiment 4

A kind of lever is adjustable load dynamic test platform, shown in Fig. 5,7,8, its structure and embodiment 3 structures are basic identical, and respectively there is the adjustable load dynamic test of a lever platform at two places of transporting rail 8 correspondences that different only is.

Embodiment 5

A kind of lever is adjustable load dynamic test platform, its structure and embodiment 1 or embodiment 2 or embodiment 3 or embodiment 4 structures are basic identical, different only is as shown in figure 22, lever 1 arm of force side has a slide slot, hanging frame device 7 only has one under lever 1 arm of force side, lower hanging frame device 7 can move along slide slot at 19 different of arm of force side mounting holes, and is fixed in the arm of force side mounting hole 19 of detection needs.

Embodiment 6

A kind of lever is adjustable load dynamic test platform, its structure and embodiment 1 or embodiment 2 or embodiment 3 or embodiment 4 structures are basic identical, different only is as shown in figure 23, lever 1 weighing arm side has a slide slot, hanging frame device 7 only has one under the lever 1 weighing arm side, lower hanging frame device 7 can move along slide slot at 20 different of weighing arm side mounting holes, and is fixed in the weighing arm side mounting hole 20 of detection needs;

Or, its structure is substantially the same manner as Example 5, different only is as shown in figure 24, lever 1 weighing arm side has a slide slot, hanging frame device 7 only has one under the lever 1 weighing arm side, lower hanging frame device 7 can move along slide slot at 20 different of weighing arm side mounting holes, and is fixed in the weighing arm side mounting hole 20 of detection needs.

Embodiment 7

A kind of lever is adjustable load dynamic test platform, its structure and embodiment 1 or embodiment 2 or embodiment 3 or embodiment 4 or embodiment 5 or embodiment 6 structures are basic identical, different only is as shown in figure 25, have slide slot one on one side of girder 5 corresponding lever arm of force sides, upper hanger device 6 only has one, upper hanger device 6 can move along slide slot 26 of different upper hanger mounting holes, and is fixed in the upper hanger mounting hole 26 of detection needs.

Embodiment 8

A kind of lever is adjustable load dynamic test platform, its structure and embodiment 1 or embodiment 2 or embodiment 3 or embodiment 4 or embodiment 5 or embodiment 6 structures are basic identical, different only is as shown in figure 26, have slide slot one on one side of girder 5 corresponding gravity arm of lever sides, only has a fixed pulley 12, this fixed pulley 12 can move along slide slot 27 of different fixed pulley mounting holes, and is fixed in the fixed pulley mounting hole 27 of detection needs;

Or, its structure and embodiment 7 structures are basic identical, different only is as shown in figure 27, have slide slot one on one side of girder 5 corresponding gravity arm of lever sides, only has a fixed pulley 12, this fixed pulley 12 can move along slide slot 27 of different fixed pulley mounting holes, and is fixed in the fixed pulley mounting hole 27 of detection needs.

Embodiment 9

A kind of lever is adjustable load dynamic test platform, its structure and embodiment 1 or embodiment 2 or embodiment 3 or embodiment 4 or embodiment 5 or embodiment 6 or embodiment 7 or embodiment 8 structures are basic identical, different only is as shown in figure 19, (heavily stone roller) is articulated in the bottom of a travelling block in external force source 10, and link 9 is fixed in D point right (or left) side by the travelling block backspace.

Operating mode and embodiment 1 different be in:

Upper hanger hook 14 changes directions by coupling components 9 through C point fixed pulleys 12 and D point multiple-grooved fixed pulley 13 to be fixed in the D point right side (or left side) side by the travelling block backspace at the E place, and being hooked together by the lower draw-bar of travelling block and external force source 10 (heavily cutting or polish jade with an emery wheel) forms a complete lever load system.

Embodiment 10

A kind of lever is adjustable load dynamic test platform, its structure and embodiment 9 structures are basic identical, different only is as shown in figure 20, between the E point place of multiple-grooved fixed pulley D point place and 10 upper ends, external force source, be equipped with one and overlap fixed, running block, external force source 10 (heavily stone roller) is articulated in the bottom of the sliding group of this cover, and link 9 is fixed in D point right (or left) side by the pulley blocks backspace.

The adjustable load dynamic test of a kind of lever shown in the utility model platform, the slide slot of its lever arm of force side slide slot, gravity arm of lever side slide slot, girder both sides can combination in any be realized.

Other structures described in the utility model connect, and can be conventional connected modes.

The enforcement of scheme described in the utility model greatly promotes the level that the tested product detects, and greatly raises the efficiency, and lays a solid foundation for forming continuous streamline production, and product design is of far-reaching significance, and effect is remarkable, has fabulous practical value.

Above the adjustable load dynamic test of a kind of lever provided by the utility model platform is described in detail.Used specific case herein principle of the present utility model and embodiment are set forth, the explanation of above embodiment just is used for helping to understand method of the present utility model and core concept thereof.Should be understood that; for those skilled in the art; under the prerequisite that does not break away from the utility model principle, can also carry out some improvement and modification to the utility model, these improvement and modification also fall in the protection domain of the utility model claim.

Claims (39)

1. the adjustable load dynamic test of lever platform, it is characterized in that: it has lever (1), head tree (2), column (3), girder (5), upper hanger device (6), upper hanger hook (14), lower hanging frame device (7), coupling components (9), the flexible connection that intersects vertically of head tree (2) lower end and lever (1), head tree (2) upper end intersects vertically with girder (5) and is fixedly connected with, the column (3) that girder (5) is played stable fixation is parallel to head tree (2) and installs fixing, lever (1) arm of force side and weighing arm side are installed with lower hanging frame device (7), on the girder (5) of corresponding lever (1) arm of force side upper hanger device (6) is installed, be fixed wtih fixed pulley (12) and multiple-grooved fixed pulley (13) on the girder (5) of corresponding lever (1) gravity side, through coupling components (9) the one termination upper hangers hooks (14) of fixed pulley (12) and multiple-grooved fixed pulley (13), another termination external force source (10).

2. the adjustable load dynamic test of a kind of lever as claimed in claim 1 platform, it is characterized in that: the lower hanging frame device (7) of lever (1) weighing arm side is one, two, three or a plurality of.

3. the adjustable load dynamic test of a kind of lever as claimed in claim 2 platform is characterized in that: the quantity of the quantity of upper hanger hook (14) and the lower hanging frame device (7) of position and lever (1) weighing arm side and position be Corresponding matching one by one.

4. such as claim 1 or the adjustable load dynamic test of 2 or 3 described a kind of levers platform, it is characterized in that: the lower hanging frame device (7) of lever (1) arm of force side is one, two, three or a plurality of.

5. the adjustable load dynamic test of a kind of lever as claimed in claim 4 platform, it is characterized in that: the quantity of the lower hanging frame device (7) of the quantity of upper hanger device (6) and position and lever (1) arm of force side and position be Corresponding matching one by one.

6. such as claim 1 or the adjustable load dynamic test of 2 or 3 or 5 described a kind of levers platform, it is characterized in that: column (3) has three, supports respectively the both sides that are fixedly mounted on girder (5).

7. the adjustable load dynamic test of a kind of lever as claimed in claim 4 platform, it is characterized in that: column (3) has three, supports respectively the both sides that are fixedly mounted on girder (5).

8. such as claim 1 or 2 or 3 or the 5 or 7 adjustable load dynamic test of described a kind of lever platforms, it is characterized in that: external force source (10) are heavily to cut or polish jade with an emery wheel.

9. the adjustable load dynamic test of a kind of lever as claimed in claim 4 platform, it is characterized in that: external force source (10) are heavily to cut or polish jade with an emery wheel.

10. the adjustable load dynamic test of a kind of lever as claimed in claim 6 platform, it is characterized in that: external force source (10) are heavily to cut or polish jade with an emery wheel.

11. such as claim 1 or 2 or 3 or 5 or 7 or the 9 or 10 adjustable load dynamic test of described a kind of lever platforms, it is characterized in that: be the transporting rail (8) that is arranged in parallel with girder (5) and supported by column (3), at the diverse location of transporting rail (8) the adjustable load dynamic test of lever of the present invention platform is arranged.

12. the adjustable load dynamic test of a kind of lever as claimed in claim 11 platform, it is characterized in that: transporting rail (8) is loop configuration.

13. the adjustable load dynamic test of a kind of lever as claimed in claim 4 platform, it is characterized in that: be the transporting rail (8) that is arranged in parallel with girder (5) and supported by column (3), at the diverse location of transporting rail (8) the adjustable load dynamic test of lever of the present invention platform is arranged.

14. the adjustable load dynamic test of a kind of lever as claimed in claim 6 platform, it is characterized in that: be the transporting rail (8) that is arranged in parallel with girder (5) and supported by column (3), at the diverse location of transporting rail (8) the adjustable load dynamic test of lever of the present invention platform is arranged.

15. the adjustable load dynamic test of a kind of lever as claimed in claim 8 platform, it is characterized in that: be the transporting rail (8) that is arranged in parallel with girder (5) and supported by column (3), at the diverse location of transporting rail (8) the adjustable load dynamic test of lever of the present invention platform is arranged.

16. such as claim 13 or the adjustable load dynamic test of 14 or 15 described a kind of levers platform, it is characterized in that: transporting rail (8) is loop configuration.

17. such as claim 1 or 2 or 3 or 5 or 7 or 9 or 10 or 12 or 13 or the 14 or 15 adjustable load dynamic test of described a kind of lever platforms, it is characterized in that: be fixedly connected with by crossbeam (4) between head tree (2) and the girder (5).

18. the adjustable load dynamic test of a kind of lever as claimed in claim 4 platform is characterized in that: be fixedly connected with by crossbeam (4) between head tree (2) and the girder (5).

19. the adjustable load dynamic test of a kind of lever as claimed in claim 6 platform is characterized in that: be fixedly connected with by crossbeam (4) between head tree (2) and the girder (5).

20. the adjustable load dynamic test of a kind of lever as claimed in claim 8 platform is characterized in that: be fixedly connected with by crossbeam (4) between head tree (2) and the girder (5).

21. the adjustable load dynamic test of a kind of lever as claimed in claim 11 platform is characterized in that: be fixedly connected with by crossbeam (4) between head tree (2) and the girder (5).

22. the adjustable load dynamic test of a kind of lever as claimed in claim 16 platform is characterized in that: be fixedly connected with by crossbeam (4) between head tree (2) and the girder (5).

23. such as claim 1 or 2 or 3 or 5 or 7 or 9 or 10 or 12 or 13 or 14 or 15 or 18 or 19 or 20 or the 21 or 22 adjustable load dynamic test of described a kind of lever platforms, it is characterized in that: be fixedly connected with by crossbeam (4) between column (3) and the girder (5).

24. the adjustable load dynamic test of a kind of lever as claimed in claim 4 platform is characterized in that: be fixedly connected with by crossbeam (4) between column (3) and the girder (5).

25. the adjustable load dynamic test of a kind of lever as claimed in claim 6 platform is characterized in that: be fixedly connected with by crossbeam (4) between column (3) and the girder (5).

26. the adjustable load dynamic test of a kind of lever as claimed in claim 8 platform is characterized in that: be fixedly connected with by crossbeam (4) between head tree (3) and the girder (5).

27. the adjustable load dynamic test of a kind of lever as claimed in claim 11 platform is characterized in that: be fixedly connected with by crossbeam (4) between column (3) and the girder (5).

28. the adjustable load dynamic test of a kind of lever as claimed in claim 16 platform is characterized in that: be fixedly connected with by crossbeam (4) between column (3) and the girder (5).

29. the adjustable load dynamic test of a kind of lever as claimed in claim 17 platform is characterized in that: be fixedly connected with by crossbeam (4) between column (3) and the girder (5).

30. such as claim 1 or 2 or 3 or 5 or 7 or 9 or 10 or 12 or 13 or 14 or 15 or 1 or 19 or 20 or 21 or 22 or 24 or 25 or 26 or 27 or the 28 or 29 adjustable load dynamic test of described a kind of lever platforms, it is characterized in that: external force source (10) are articulated in the bottom of a travelling block, and link (9) is by fixing behind the travelling block.

31. the adjustable load dynamic test of a kind of lever as claimed in claim 30 platform, it is characterized in that: travelling block is running block.

32. the adjustable load dynamic test of a kind of lever as claimed in claim 4 platform, it is characterized in that: external force source (10) are articulated in the bottom of a travelling block, and link (9) is by fixing behind the travelling block.

33. the adjustable load dynamic test of a kind of lever as claimed in claim 6 platform, it is characterized in that: external force source (10) are articulated in the bottom of a travelling block, and link (9) is by fixing behind the travelling block.

34. the adjustable load dynamic test of a kind of lever as claimed in claim 8 platform, it is characterized in that: external force source (10) are articulated in the bottom of a travelling block, and link (9) is by fixing behind the travelling block.

35. the adjustable load dynamic test of a kind of lever as claimed in claim 11 platform, it is characterized in that: external force source (10) are articulated in the bottom of a travelling block, and link (9) is by fixing behind the travelling block.

36. the adjustable load dynamic test of a kind of lever as claimed in claim 16 platform, it is characterized in that: external force source (10) are articulated in the bottom of a travelling block, and link (9) is by fixing behind the travelling block.

37. the adjustable load dynamic test of a kind of lever as claimed in claim 17 platform, it is characterized in that: external force source (10) are articulated in the bottom of a travelling block, and link (9) is by fixing behind the travelling block.

38. the adjustable load dynamic test of a kind of lever as claimed in claim 23 platform, it is characterized in that: external force source (10) are articulated in the bottom of a travelling block, and link (9) is by fixing behind the travelling block.

39. such as claim 32 or 33 or 34 or 35 or 36 or the 37 or 38 adjustable load dynamic test of described a kind of lever platforms, it is characterized in that: travelling block is running block.

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