CN201242588Y

CN201242588Y - Switch test structure

Info

Publication number: CN201242588Y
Application number: CNU2008201267202U
Authority: CN
Inventors: 高永良; 邱明辉
Original assignee: LEIXIN DEVELOPMENT TECHNOLOGY Co Ltd
Current assignee: LEIXIN DEVELOPMENT TECHNOLOGY Co Ltd
Priority date: 2008-06-24
Filing date: 2008-06-24
Publication date: 2009-05-20
Anticipated expiration: 2018-06-24

Abstract

The utility model relates to a switch testing structure which comprises an X-axis servo motor set, a Y-axis servo motor set, a Theta-axis servo motor set and a fixed element; wherein the X-axis servo motor set is utilized to perform the lateral shifting movement, the Y-axis servo motor set is used to perform the vertical shifting movement and the rail sliding movement, and the Theta-axis servo motor set is used to drive the fixed element to test the switch, thereby forming a switch testing structure.

Description

The switch testing structure

Technical field

The utility model relates to a kind of device of Test Switchboard, particularly a kind of switch testing structure.

Background technology

Existing switch testing structure, comprise a cylinder, a cam, be to utilize cylinder and cam principle, the action of only doing upper and lower displacement does not have the action of left and right displacement, and precision is not high, can't do rate controlled, the speed, the efficient that can not manifest its setting, and once only test an on-off element, do not meet economic benefits, manufacture also comparatively slowly, do not reach the demand in market.

In a word, prior art has following shortcoming:

1. existing switch testing structure is utilized cylinder or cam principle, and the action of doing upper and lower displacement is formed, and it is comparatively inflexible to move.

2. existing switch testing structure can't be done rate controlled, can not manifest its speed, efficient.

3. existing switch testing structure, the action of only doing upper and lower displacement does not have the action of left and right displacement, and precision is not high.

4. existing switch testing structure is once only tested an on-off element, does not meet economic benefits, manufactures also comparatively slowly, does not reach the demand in market.

5. existing switch testing structure only has single work efficiency fruit.

Every problem and deficiency that the utility model creator is derived in view of above-mentioned existing switch testing structure are improved innovation, and after concentrating on studies through taking great pains to attain one's goal for many years, successfully this switch testing structure is finished in research and development finally.

Summary of the invention

Fundamental purpose of the present utility model provides a kind of switch testing structure, to overcome the deficiency of above-mentioned existing switch testing structure.

In order to achieve the above object, the utility model provides a kind of switch testing structure, comprise an X-axis servo motor group, a Y-axis servo motor group, a θ axle servo motor group, a retaining element, described X-axis servo motor group connects described Y-axis servo motor group, described Y-axis servo motor group connects described θ axle servo motor group, described θ axle servo motor group drives described retaining element, after the mentioned component combination, can become a switch testing structure.

Wherein, X-axis servo motor group is connected the slide block holder and is formed by X-axis servo motor, X-axis servo motor web joint, X-axis shaft joint, X-axis slide rail set, X-axis slide block, X-axis, X-axis servo motor front end is connected X-axis servo motor web joint, X-axis servo motor web joint front end is connected the X-axis shaft joint, X-axis shaft joint front end is connected the X-axis slide rail set, X-axis slide rail set front end is connected the X-axis slide block, and X-axis slide block the right is connected X-axis and is connected the slide block holder;

Y-axis servo motor group is connected the slide block holder and is formed by Y-axis servo motor, Y-axis servo motor web joint, Y-axis shaft joint, Y-axis slide rail set, Y-axis slide block, Y-axis, the Y-axis servo motor is connected Y-axis servo motor web joint downwards, Y-axis servo motor web joint is connected the Y-axis shaft joint downwards, the Y-axis shaft joint is connected the Y-axis slide rail set downwards, the Y-axis slide rail set is connected the Y-axis slide block downwards, and the Y-axis slide block is connected Y-axis downwards and is connected the slide block holder;

θ axle servo motor group by θ axle servo motor, reductor, reductor holder, connect the switch driving lever and formed, θ axle servo motor is connected reductor downwards, reductor is connected the reductor holder downwards, the reductor holder extends downwards and is connected the switch driving lever;

Retaining element is by bracing frame, anchor clamps firm banking, switch stationary fixture, anchor clamps firm banking, standing vice are formed, supporting framing front end is connected the anchor clamps firm banking, and anchor clamps firm banking top is connected the switch stationary fixture, and the anchor clamps firm banking left side is connected standing vice.

The beneficial effects of the utility model are:

1. the utility model switch testing structure by automatic control test, can be tested single-point, multiple spot loop.

2. the utility model switch testing structure is controlled automatic switchover series and parallel loop by Programmable Logic Controller (PLC).

3. the utility model switch testing structure, series loop mainly are the control temperature-rise effects.

4. the utility model switch testing structure, the shunt circuit is to want the gauge tap life-span.

5. the utility model switch testing structure, the action of not only doing upper and lower displacement also has the action of left and right displacement, the precision height, rate controlled shows its speed, efficient.

6. the utility model switch testing structure is once tested a plurality of on-off elements, meets economic benefits, manufactures rapidly, can reach the demand in market.

7. the utility model switch testing structure reaches multiplex's effect.

Description of drawings

Fig. 1 is the textural association synoptic diagram of the utility model switch testing structure;

Fig. 2 is the action synoptic diagram of the utility model switch testing structure;

Fig. 3 is that the structure of the utility model retaining element is formed synoptic diagram;

Fig. 4 is the textural association synoptic diagram of the utility model Y-axis servo motor group;

Fig. 5 is the textural association synoptic diagram of the utility model θ axle servo motor group;

Fig. 6 is the enforcement action synoptic diagram of the utility model switch testing structure;

Fig. 7 cuts for practicing of the utility model switch testing structure is single and closes synoptic diagram;

Fig. 8 practices the push switch synoptic diagram for the utility model switch testing structure;

Fig. 9 practices the toggle switch synoptic diagram for the utility model switch testing structure;

Figure 10 shows the rotary switch intention for practicing of the utility model switch testing structure.

Description of reference numerals: 1-X axle servo motor group; 11-X axle servo motor; 12-X axle shaft joint; 13-X axle slide rail set; 14-X axle slide block; The 15-X axle is connected the slide block holder; 16-X axle servo motor web joint; 2-Y axle servo motor group; 21-Y axle servo motor; 22-Y axle shaft joint; 23-Y axle slide rail set; 24-Y axle slide block; The 25-Y axle is connected the slide block holder; 26-Y axle servo motor web joint; 27-Y axle slide block base plate; 3-θ axle servo motor group; 31-θ axle servo motor; The 32-reductor; 321-reductor holder; 322-switch driving lever; 323-driving lever head; The 4-retaining element; The 41-bracing frame; 42-switch stationary fixture; The 43-standing vice; 44-anchor clamps firm banking; The 5-on-off element; 100-switch testing structure.

Embodiment

Below in conjunction with accompanying drawing, be described in more detail with other technical characterictic and advantage the utility model is above-mentioned.

See also Fig. 1, Fig. 2, be the textural association synoptic diagram of switch testing structure and the action synoptic diagram of switch testing structure, by among the figure as can be known, switch testing structure 100 is made up of X-axis servo motor group 1, Y-axis servo motor group 2, θ axle servo motor group 3, a retaining element 4, X-axis servo motor group 1 left side is connected Y-axis servo motor group 2, Y-axis servo motor group 2 left sides are connected θ axle servo motor group 3, θ axle servo motor group 3 is connected retaining element 4 downwards, after above-mentioned combination, can become a switch testing structure;

Wherein, X-axis servo motor group 1 is connected slide block holder 15 and is formed by X-axis servo motor 11, X-axis servo motor web joint 16, X-axis shaft joint 12, X-axis slide rail set 13, X-axis slide block 14, X-axis, X-axis servo motor 11 front ends are connected X-axis servo motor web joint 16, X-axis servo motor web joint 16 front ends are connected X-axis shaft joint 12, X-axis shaft joint 12 front ends are connected X-axis slide rail set 13, X-axis slide rail set 13 front ends are connected X-axis slide block 14, and X-axis slide block 14 the right are connected X-axis and are connected slide block holder 15;

Y-axis servo motor group 2 is connected slide block holder 25 and is formed by Y-axis servo motor 21, Y-axis servo motor web joint 26, Y-axis shaft joint 22, Y-axis slide rail set 23, Y-axis slide block 24, Y-axis, Y-axis servo motor 21 is connected Y-axis servo motor web joint 26 downwards, Y-axis servo motor web joint 26 is connected Y-axis shaft joint 22 downwards, Y-axis shaft joint 22 is connected Y-axis slide rail set 23 downwards, Y-axis slide rail set 23 is connected Y-axis slide block 24 downwards, and Y-axis slide block 24 is connected Y-axis downwards and is connected slide block holder 25;

θ axle servo motor group 3 by θ axle servo motor 31, reductor 32, reductor holder 321, connect switch driving lever 322 and formed, θ axle servo motor 31 is connected reductor 32 downwards, reductor 32 is connected reductor holder 321 downwards, and reductor holder 321 extends linking switch driving lever 322 downwards;

Retaining element 4 is by bracing frame 41, anchor clamps firm banking 44, switch stationary fixture 42, anchor clamps firm banking 44, standing vice 43 are formed, bracing frame 41 front ends are connected anchor clamps firm banking 44, anchor clamps firm banking 44 tops are connected switch stationary fixture 42, anchor clamps firm banking 44 left sides are connected standing vice 43, more than form a switch testing structure.

See also Fig. 2, action synoptic diagram for the utility model switch testing structure, the switch testing structure does switch testing structure left and right displacement by the X-axis slide block 14 drive Y-axis linking slide block holders 25 that X-axis is connected slide block holder 15 linking X-axis servo motor groups 1, the Y-axis slide block 24 of its Y-axis servo motor group 2 drives reductor holder 321 upper and lower displacements of θ axle servo motor group 3 and does, drive retaining element 4 actions at last, wherein Y-axis slide rail set 23 is connected Y-axis slide block base plate 27 left by Y-axis slide block 24 and is formed, after the mentioned component combination, can become a switch testing structure.

See also Fig. 3, for the structure of the utility model retaining element is formed synoptic diagram, as seen from the figure, bracing frame 41 front ends of retaining element 4 are connected anchor clamps firm banking 44, anchor clamps firm banking 44 tops are connected switch stationary fixture 42, anchor clamps firm banking 44 left sides are connected standing vice 43, and the on-off element 5 that will test is again at last inserted, and can become a retaining element 4.

See also Fig. 4, textural association synoptic diagram for the utility model Y-axis servo motor group, as seen from the figure, the Y-axis servo motor 21 of Y-axis servo motor group 2 is connected Y-axis servo motor web joint 26 downwards, Y-axis servo motor web joint 26 is connected Y-axis shaft joint 22 downwards, Y-axis shaft joint 22 is connected Y-axis slide rail set 23 downwards, and wherein Y-axis slide rail set 23 is to be connected Y-axis slide block base plate 27 left by Y-axis slide block 24.

See also Fig. 5, textural association synoptic diagram for the utility model θ axle servo motor group, as seen from the figure, the θ axle servo motor 31 of θ axle servo motor group 3 is connected reductor 32 downwards, reductor 32 is connected reductor holder 321 downwards, reductor holder 321 extends linking switch driving lever 322 downwards, and wherein driving lever head 323 is to change, and is convenient to test various multi-form on-off elements.

See also Fig. 6, enforcement action synoptic diagram for the utility model switch testing structure, as seen from the figure, switch testing structure 100, wherein X-axis servo motor group 1 drives switch testing structure 100 move left and right, Y-axis servo motor group 2 drives switch testing structure 100 and moves up and down, and θ axle servo motor group 3 drives the 322 same direction rotations of switch driving lever and moves.

See also Fig. 7, cut the pass synoptic diagram for practicing of the utility model switch testing structure is single, as seen from the figure, switch testing structure 100, different on-off element 5 its switch testing structure 100 actions are different, wherein on-off element 5 is that single the incision closed, it utilizes the Y-axis servo motor group 2 of switch testing structure 100 to drive switch testing structure 100 and moves up and down, drive θ axle servo motor group 3 switch driving levers 322 and move up and down Test Switchboard, it utilizes X-axis servo motor group 1 to drive switch testing structure 100 move left and right, drives the switch driving lever 322 move left and right Test Switchboards of θ axle servo motor group 3.

See also Fig. 8, practice the push switch synoptic diagram for the utility model switch testing structure, as seen from the figure, switch testing structure 100, different on-off element 5 its switch testing structure 100 actions are different, wherein on-off element 5 is a push switch, and it utilizes the Y-axis servo motor group 2 of switch testing structure 100 to drive 100 upper and lower displacements of switch testing structure and does, and the switch driving lever 322 that drives θ axle servo motor group 3 moves up and down Test Switchboard.

Consult Fig. 9, practice the toggle switch synoptic diagram for the utility model switch testing structure, as seen from the figure, switch testing structure 100, different on-off element 5 its switch testing structure 100 actions are different, wherein on-off element 5 is a toggle switch, and it utilizes X-axis servo motor group 1 to drive switch testing structure 100 move left and right, drives the switch driving lever 322 move left and right Test Switchboards of θ axle servo motor group 3.

See also Figure 10, practice the rotary switch synoptic diagram for the utility model switch testing structure, as seen from the figure, switch testing structure 100, different on-off element 5 its switch testing structure 100 actions are different, wherein on-off element 5 is a rotary switch, and it utilizes θ axle servo motor group 3 to drive switch driving lever 322 rotation mobile test switches.

In sum, the utility model not only really belongs to innovation on technological thought, and can promote multinomial effect than existing article, fully meets the legal utility model patent condition of novelty and progressive, files an application in accordance with the law.

The above only is preferred embodiment of the present utility model, only is illustrative for the utility model, and nonrestrictive.Those skilled in the art is understood, and can carry out many changes to it in the spirit and scope that the utility model claim is limited, revise, even equivalence, but all will fall in the protection domain of the present utility model.

Claims

1. switch testing structure, it is characterized in that, comprise an X-axis servo motor group, a Y-axis servo motor group, a θ axle servo motor group, a retaining element, described X-axis servo motor group connects described Y-axis servo motor group, described Y-axis servo motor group connects described θ axle servo motor group, and described θ axle servo motor group drives described retaining element.

2. switch testing structure according to claim 1, it is characterized in that, described X-axis servo motor group, described Y-axis servo motor group, three combined test on-off elements of described θ axle servo motor group, described on-off element is pushbutton switch, rotary switch or linear switch.

3. switch testing structure according to claim 1, it is characterized in that, described retaining element is made up of bracing frame, anchor clamps firm banking, switch stationary fixture, standing vice, described retaining element is connected described anchor clamps firm banking by bracing frame, described anchor clamps firm banking is connected described switch stationary fixture, and described anchor clamps firm banking is connected described standing vice.

4. switch testing structure according to claim 1, it is characterized in that, described θ axle servo motor group is made up of θ axle servo motor, reductor, reductor holder, switch driving lever, described θ axle servo motor is connected described reductor, described reductor is connected described reductor holder, and described reductor holder is connected described switch driving lever.

5. switch testing structure according to claim 1, it is characterized in that, described X-axis servo motor group is by the X-axis servo motor, X-axis servo motor web joint, the X-axis shaft joint, the X-axis slide rail set, X-axis slide block and X-axis are connected the slide block holder and form, described X-axis servo motor is connected described X-axis servo motor web joint, described X-axis servo motor web joint is connected described X-axis shaft joint, described X-axis shaft joint is connected described X-axis slide rail set, described X-axis slide rail set is connected described X-axis slide block, and described X-axis slide block is connected described X-axis and is connected the slide block holder.

6. switch testing structure according to claim 1, it is characterized in that, described Y-axis servo motor group is by the Y-axis servo motor, Y-axis servo motor web joint, the Y-axis shaft joint, the Y-axis slide rail set, the Y-axis slide block, Y-axis is connected the slide block holder and forms, described Y-axis servo motor is connected described Y-axis servo motor web joint, described Y-axis servo motor web joint is connected described Y-axis shaft joint, described Y-axis shaft joint is connected described Y-axis slide rail set, described Y-axis slide rail set is connected described Y-axis slide block, and described Y-axis slide block is connected described Y-axis and is connected the slide block holder.