CN211785587U - Interface device of test equipment - Google Patents

Abstract

The embodiment of the utility model provides an interface arrangement of test equipment, interface arrangement includes: the device comprises a first mechanical arm, a second mechanical arm and a buffer disc. The first manipulator is arranged between the test track and the buffer disc, one end of the first manipulator is provided with a first grabbing mechanism for grabbing samples, and the first manipulator drives the first grabbing mechanism to move; the buffer disc is axially and rotatably arranged between the first mechanical arm and the second mechanical arm, a plurality of assembling holes for placing samples are formed in the buffer disc, the distance between the center of each assembling hole and the center of the buffer disc is the same, and the distance between the centers of every two adjacent assembling holes is the same; one end of the second manipulator is provided with a second grabbing mechanism for grabbing the sample, and the second manipulator drives the second grabbing mechanism to move. Adopt the embodiment of the utility model provides an interface arrangement realizes the sample and the lower appearance of sample through first manipulator, second manipulator and buffer disc, and then reduces the manpower that consumes, improves the efficiency of software testing of sample.

Description

Interface device of test equipment

Technical Field

The utility model relates to the technical field of medical equipment, especially, relate to an interface arrangement of test equipment.

Background

At present, the application of laboratory automation production lines is more and more extensive, and one production line can control a plurality of same or different test devices. When the sample on the assembly line needs to be sampled and analyzed, the test equipment, such as a full-automatic coagulation analyzer, needs to be installed outside the assembly line. A test apparatus employs off-track sampling. When the testing equipment adopting the off-rail sampling mode is used for testing samples, a worker is required to manually place the samples into the sample rack of the testing equipment, then the worker manually places the sample rack into the sample loading area of the testing equipment, the shifting device of the testing equipment sends the sample rack in the sample loading area into the testing area for testing, the sample rack is sent to the outlet position of the testing equipment after the testing is finished, then the sample rack is manually taken down by the worker, and the tested samples are placed on the production line again.

When the test equipment adopting the off-rail sampling mode is used for testing samples, manual sampling and sample unloading are needed, and great manpower is needed to be consumed, so that the test efficiency of the samples is low.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of the utility model is to provide an interface arrangement of test equipment to reduce the manpower that consumes, improve the efficiency of software testing of sample. The specific technical scheme is as follows:

in order to achieve the above object, an embodiment of the present invention provides an interface device for a testing apparatus, the interface device includes: the device comprises a first mechanical arm, a second mechanical arm and a buffer disc;

the first manipulator is arranged between the test track and the buffer disc, one end of the first manipulator is provided with a first grabbing mechanism for grabbing samples, the first manipulator drives the first grabbing mechanism to move, and the stroke of the first grabbing mechanism is larger than or equal to the distance between the test track and the buffer disc;

the buffer disc is axially and rotatably arranged between the first manipulator and the second manipulator, a plurality of assembling holes for placing the samples are formed in the buffer disc, the distance between the center of each assembling hole and the center of the buffer disc is the same, and the distance between the centers of every two adjacent assembling holes is the same;

and a second grabbing mechanism for grabbing samples is arranged at one end of the second manipulator, the second manipulator drives the second grabbing mechanism to move, and the stroke of the second grabbing mechanism is more than or equal to the distance between the buffer disc and the sample rack loading area.

Optionally, the interface device further comprises a shift lever mechanism; the shifting lever mechanism comprises a track group for transporting the sample rack and a mounting plate;

the track group is fixedly installed on the installation plate, one end of the track group is provided with the sample frame loading area, and the other end of the track group is connected with the test equipment.

Optionally, the shift lever mechanism further comprises a shift lever group;

the shifting lever group is arranged on the mounting plate and can drive the sample rack to move along the track group.

Optionally, the toggle rod group comprises a first toggle rod and a toggle block;

the first shifting lever can drive the sample rack to move from the sample rack loading area to the testing equipment along the track group;

the shifting block can drive the sample rack to move from the testing equipment to the sample rack loading area along the track group.

Optionally, the track group includes a first track and a second track; the poking rod group also comprises a second poking rod;

the first deflector rod can drive the sample rack to move from the sample rack loading area to the testing equipment along the first track;

the shifting block can drive the sample rack to move from the testing equipment to the sample rack loading area along the second track;

the second shifter lever is mounted on the mounting plate and can move the sample rack from the second rail to the first rail.

Optionally, the shift lever mechanism further comprises a first guide rod;

the first guide bar is fixedly mounted on the mounting plate, and the first guide bar is parallel to the first rail such that the sample rack is attached to the first guide bar.

Optionally, the shift lever mechanism further comprises a second guide rod;

the second guide bar is fixedly mounted on the mounting plate, and the second guide bar is parallel to the second rail such that the sample rack is attached to the second guide bar.

Optionally, the assembling hole is a stepped hole;

the stepped holes comprise a first stepped hole and a second stepped hole;

the cross-sectional diameter of the first stepped hole is greater than or equal to that of the sample, and the cross-sectional diameter of the second stepped hole is smaller than that of the sample.

The embodiment of the utility model provides a technical scheme's beneficial effect:

the embodiment of the utility model provides a pair of test equipment's interface arrangement, above-mentioned interface arrangement includes first manipulator, second manipulator and dashpot. One end of the first manipulator is provided with a first grabbing mechanism, the stroke of the first grabbing mechanism is larger than or equal to the distance between the test track and the buffer disc, one end of the second manipulator is provided with a second grabbing mechanism, and the stroke of the second grabbing mechanism is larger than or equal to the distance between the buffer disc and the sample rack loading area. The first grabbing mechanism transports a sample to be tested to an assembly hole in the buffer disc from the test track, the second grabbing mechanism transports the tested sample to the assembly hole in the buffer disc from the sample frame, then the buffer disc rotates, the sample to be tested rotates to the side of the second mechanical arm, the tested sample rotates to the side of the first mechanical arm, the second grabbing mechanism clamps the sample to be tested from the buffer disc and loads the sample to be tested to the sample frame located in the sample frame loading area, and meanwhile the first grabbing mechanism transports the tested sample to the test track from the buffer disc to finish sample loading and sample unloading.

Adopt the embodiment of the utility model provides an interface arrangement of test equipment realizes the sample and the lower appearance of sample through first manipulator, second manipulator and buffer tray, and then reduces the manpower that consumes, improves the efficiency of software testing of sample.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a structural diagram of an interface device of a testing apparatus according to an embodiment of the present invention;

fig. 2 is a partial assembly view of a shifting block according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

For the manpower that reduces and consume, improve the efficiency of software testing of sample, the embodiment of the utility model provides an interface arrangement of test equipment, it is right to combine fig. 1-2 below the embodiment of the utility model provides an interface arrangement of test equipment carries out the detailed description.

As shown in fig. 1, an embodiment of the present invention provides an interface device of a testing apparatus, including: a first manipulator 1, a second manipulator 2 and a buffer tray 3.

The first mechanical arm 1 is installed between the test track and the buffer disc 3, one end of the first mechanical arm 1 is provided with a first grabbing mechanism for grabbing samples, the first mechanical arm 1 drives the first grabbing mechanism to move, and the stroke of the first grabbing mechanism is larger than or equal to the distance between the test track and the buffer disc 3.

But buffer tray 3 axial rotation ground installs between first manipulator 1 and second manipulator 2, and has seted up a plurality of pilot holes that are used for placing the sample on the buffer tray 3, and the distance between the center of each pilot hole and buffer tray 3 center is the same, and the distance between the center of every two adjacent pilot holes is the same.

One end of the second mechanical arm 2 is provided with a second grabbing mechanism for grabbing samples, the second mechanical arm 2 drives the second grabbing mechanism to move, and the stroke of the second grabbing mechanism is larger than or equal to the distance between the buffer disc 3 and the sample rack loading area.

In the embodiment of the utility model, the first manipulator 1 is mainly used for grabbing the sample transported by the carrying frame on the test track through the first grabbing mechanism and placing the sample in the assembling hole on the buffer disc 3; in addition, the sample in the fitting hole on the buffer tray 3 is grasped by the first grasping mechanism, and placed on the carriage on the test rail. That is, the first robot 1 moves between the test track and the buffer tray 3, and thus the stroke of the first grasping mechanism of the first robot 1 is equal to or greater than the distance between the test track and the buffer tray 3. Also, the distance between the test track and the buffer tray 3 may be understood as a distance between the carrier on the test track and the fitting hole of the buffer tray 3 closest to the test track.

The second manipulator 2 is mainly used for grabbing the samples in the assembly holes on the buffer disc 3 through a second grabbing mechanism and loading the samples on the sample racks 10 in the sample rack loading area; in addition, the sample on the sample rack 10 is grasped by the second grasping mechanism, and the sample is placed in the fitting hole on the buffer tray 3. That is, the second robot 2 moves between the buffer tray 3 and the sample rack loading zone, and thus the stroke of the second grasping mechanism on the second robot 2 is equal to or greater than the distance between the buffer tray 3 and the sample rack loading zone. Also, the distance between the buffer tray 3 and the specimen rack loading area may be understood as a distance between the fitting hole of the buffer tray 3 closest to the specimen rack loading area and the specimen rack 10 located at the specimen rack loading area.

The embodiment of the utility model provides an in, but buffer tray 3 is installed between first manipulator 1 and second manipulator 2 axially 360 degrees rotations, and buffer tray 3 drives the examination sample that awaits measuring and has tested the sample and rotate, and then makes the examination sample can be close to one side of first manipulator 1 by buffer tray 3 and remove to one side that buffer tray 3 is close to second manipulator 2 to await measuring the sample, makes the examination sample remove to one side that buffer tray 3 is close to first manipulator 1 by one side that buffer tray 3 is close to second manipulator 2 simultaneously.

For example, as shown in fig. 1, a sample to be tested is loaded on the mounting hole a, a sample that has been tested is loaded on the mounting hole B, and the buffer disc 3 rotates 180 degrees counterclockwise in the direction from left to right in fig. 1, so that the mounting hole a rotates to the position of the mounting hole B, and at the same time, the mounting hole B rotates to the position of the mounting hole a, so that the sample to be tested loaded on the mounting hole a moves from the side of the buffer disc 3 close to the first manipulator 1 to the side of the buffer disc 3 close to the second manipulator 2, and the sample that has been tested and loaded on the mounting hole B moves from the side of the buffer disc 3 close to the second manipulator 2 to the side of the buffer disc 3 close to the first manipulator 1.

In the embodiment of the present invention, the first manipulator 1 and the second manipulator 2 may be collectively referred to as a manipulator. As shown in fig. 1, the plurality of assembling holes are uniformly distributed in a circumferential manner, the distance between the center of each assembling hole and the center of the buffer disc 3 is the same, and the distance between the centers of every two adjacent assembling holes is the same, so that when the manipulator transports a sample to the buffer disc 3 from a test track or transports the sample to the sample rack 10 from the buffer disc 3, the stroke of the manipulator is unchanged, and therefore, when the manipulator works, the manipulator can be uniformly arranged, and the operation is more convenient. The distance between the center of each assembling hole and the center of the buffer disc 3 can be adjusted, and the assembling holes can be arranged at the positions close to the edge of the buffer disc 3 as shown in figure 1, so that the stroke of the manipulator during working is shortened, and the power loss of the manipulator is reduced.

The embodiment of the utility model provides an in, first snatch the mechanism and will await measuring the sample from testing the pilot hole on track transportation to buffer disc 3, and simultaneously, the second snatchs the mechanism and will test the sample and transport to the pilot hole on buffer disc 3 from sample frame 10 in, then buffer disc 3 rotates, make the sample that awaits measuring rotate to 2 sides of second manipulator, and test the sample and rotate to 1 side of first manipulator, and then make the second snatch the mechanism and get the sample from buffer disc 3 upward clamp and load the sample to the sample frame 10 that is located sample frame loading area, first snatch the mechanism and will test the sample and transport to testing the track from buffer disc 3 simultaneously, accomplish the sample and the lower appearance of sample, in the time of using manpower sparingly, the efficiency of software testing of sample has been improved.

In one embodiment, the mounting hole may be a blind hole, and the cross-sectional area of the blind hole is equal to or greater than the cross-sectional area of the sample. Adopt the blind hole to load the sample, effectively prevented that the sample from passing the pilot hole and dropping on by buffer disc 3, can reduce the processing degree of difficulty of pilot hole simultaneously.

In one embodiment, the assembly hole may be a stepped hole, and the stepped hole includes a first stepped hole and a second stepped hole. The cross-sectional diameter of the first stepped hole is greater than or equal to the cross-sectional diameter of the sample, and the cross-sectional diameter of the second stepped hole is smaller than the cross-sectional diameter of the sample.

Because the cross section diameter of the first step hole is more than or equal to the cross section diameter of the sample, and the cross section diameter of the second step hole is less than the cross section diameter of the sample, when the sample can be successfully loaded into the assembly hole, the second step hole blocks the sample, and the sample is prevented from falling off from the buffer disc 3 through the assembly hole. Meanwhile, the second step hole is a through hole, so that the cleaning difficulty of the assembly hole is reduced when dust or garbage exists in the assembly hole.

In one embodiment, the interface device may further include a lever mechanism. The shifter mechanism includes a track set that transports the sample rack 10 and a mounting plate 4. Track group fixed mounting is on mounting panel 4, and the one end of track group is provided with sample frame loading area, and the other end of track group is connected with test equipment.

In the embodiment of the utility model provides an in, the track group mainly used makes the sample frame 10 that has the sample that awaits measuring to load by sample frame loading area along the sample loading area of track group transportation to test equipment for test equipment detects the sample that awaits measuring. At the same time, the track set is also used to transport the sample rack 10 loaded with the tested sample from the exit position of the testing apparatus to the sample rack loading area along the track set. Therefore, one end of the track group is provided with a sample rack loading area, and the other end of the track group is connected with the testing equipment.

In one embodiment, the toggle mechanism may further comprise a toggle lever set. The set of levers is mounted on the mounting plate 4 and can drive the sample rack 10 to move along the track set.

In one embodiment, as shown in fig. 1, the lever assembly may include a first lever 5 and a lever block 6. The first lever 5 can move the sample rack 10 along the track set from the sample rack loading area to the testing equipment. The paddle 6 may move the sample rack 10 along the track set from the testing apparatus to the sample rack loading area.

As shown in fig. 1, the moving direction of the first lever 5 is parallel to the moving direction of the dial 6. The first deflector rod 5 is movably arranged on the track group along the horizontal direction, when a sample to be tested is loaded on the sample rack 10, the sample rack 10 containing the sample to be tested is pushed, the sample rack 10 containing the sample to be tested is enabled to move from the sample rack loading area to the sample loading area of the testing equipment along the track group, and then the first deflector rod 5 returns to the sample rack loading area along the track group. The shifting block 6 is also movably installed on the guide rail set along the horizontal direction, as shown in fig. 2, when the testing device finishes testing the sample, the testing device can transport the sample rack 10 loaded with the tested sample to the outlet position of the testing device, at this time, the shifting block 6 pushes the sample rack 10 loaded with the tested sample, so that the sample rack 10 loaded with the tested sample moves to the sample rack loading area from the outlet position of the testing device along the rail set, and then the shifting block 6 returns to the outlet position of the testing device along the rail set.

The sample frame 10 moves between the sample frame loading area and the test equipment along the track group through the first shifting rod 5 and the shifting block 6, the sample frame 10 filled with the sample to be tested does not need to be manually sent into the test equipment for testing by a worker, and the sample frame 10 filled with the tested sample does not need to be manually sent into the sample frame loading area for sample unloading by the worker, so that the consumed manpower is further reduced, the transportation time of the sample frame 10 is saved, and the test efficiency of the sample is improved.

In one embodiment, the track set may include a first track and a second track. The shift lever group can also comprise a second shift lever 7. The first lever 5 can move the sample rack 10 along the first rail from the sample rack loading area to the testing apparatus. The paddle 6 may move the sample rack 10 along the second track from the testing apparatus to the sample rack loading area. The second lever 7 is mounted on the mounting plate 4 and can move the sample rack 10 from the second rail to the first rail.

The embodiment of the utility model provides an in, second driving lever 7 mainly used will load the sample frame 10 that has the sample that awaits measuring and move to first track by the second track to make first driving lever 5 can promote this sample frame 10 and move to test equipment's sample loading district by sample frame loading district along first track. The sample rack 10 is prevented from being manually moved to the first rail from the second rail by workers, the consumed manpower is further reduced, the transportation time of the sample rack 10 is saved, and the sample testing efficiency is improved.

As shown in fig. 1, the sample rack 10 has a plurality of positions for placing samples, when the second manipulator 2 grips a sample on the position to be processed, in order to minimize the stroke of the second manipulator 2, the second shift lever 7 can push the sample rack 10 so that the position to be processed is located at the working position where the sample rack 10 is closest to the buffer tray 3, and when the second manipulator 2 completes a set of actions of loading and unloading samples on the position to be processed, the second shift lever 7 continues to push the sample rack 10 until the next position to be processed is located at the working position, so that the moving route of the second manipulator 2 is fixed and the stroke is short, thereby shortening the time for the second manipulator 2 to complete a set of actions of loading and unloading samples. One set of actions of loading and unloading the samples is that the second manipulator 2 transports the tested samples on the sample rack 10 to the buffer tray 3, and then transports the samples to be tested on the buffer tray 3 to the sample rack 10.

In one embodiment, as shown in fig. 1, the toggle mechanism may further include a first guide bar 8. The first guide bar 8 is fixedly mounted on the mounting plate 4, and the first guide bar 8 is parallel to the first rail such that the sample rack 10 is attached to the first guide bar 8.

In the embodiment of the present invention, as shown in fig. 1, the first guiding rod 8 is fixedly installed on the mounting plate 4, and the first guiding rod 8 is parallel to the first track. The sample rack 10 is provided with a groove matched with the first guide rod 8 at one end connected with the first guide rod 8, the sample rack 10 is attached to the first guide rod 8 through the groove, when the first deflector rod 5 pushes the sample rack 10 to move from the sample rack loading area to the sample loading position of the testing equipment along the first track, the groove on the sample rack 10 is clamped on the first guide rod 8, the sample rack 10 is prevented from displacing in the direction perpendicular to the first guide rod 8, and because the sample rack 10 is clamped on the first guide rod 8 through the groove, when the first deflector rod 5 pushes the sample rack 10 to move too fast, the first guide rod 8 prevents the sample rack 10 from toppling.

In one embodiment, the toggle mechanism may further comprise a second guide rod 9. The second guide bar 9 is fixedly mounted on the mounting plate 4, and the second guide bar 9 is parallel to the second track, so that the sample rack 10 is attached to the second guide bar 9.

In the embodiment of the present invention, as shown in fig. 1, the second guiding rod 9 is fixedly installed on the mounting plate 4, and the second guiding rod 9 is parallel to the second track. In order to make the sample rack 10 fit with both the first guide bar 8 and the second guide bar 9, the width and thickness of the first guide bar 8 and the second guide bar 9 are equal. The sample rack 10 is attached to the second guide bar 9 by the above-mentioned groove, and when the paddle 6 pushes the sample rack 10 to move along the second track from the exit position of the testing apparatus to the sample rack loading area, the groove on the sample rack 10 is caught on the second guide bar 9, preventing the sample rack 10 from being displaced in a direction perpendicular to the second guide bar 9, and since the sample rack 10 is caught on the second guide bar 9 by the groove, the second guide bar 9 prevents the sample rack 10 from being toppled when the paddle 6 pushes the sample rack 10 to move too fast.

Wherein, the connected mode of first guide bar 8 and second guide bar 9 and mounting panel 4 has the multiple, and in an example, for reducing the processing degree of difficulty, can directly weld first guide bar 8 and second guide bar 9 on mounting panel 4. In another example, in order to facilitate the detachment and replacement of the first guide plate 8 and the second guide plate 9, the first guide bar 8 and the second guide bar 9 may be connected to the mounting plate 4 by screws. The length of first guide bar 8 and second guide bar 9 can be adjusted according to actual conditions, like different test equipment, the embodiment of the utility model provides a do not limit to this.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention shall fall within the protection scope of the present invention.

Claims (8)

1. An interface apparatus for a test device, the interface apparatus comprising: the device comprises a first mechanical arm (1), a second mechanical arm (2) and a buffer disc (3);

the first manipulator (1) is installed between the test track and the buffer disc (3), one end of the first manipulator (1) is provided with a first grabbing mechanism for grabbing samples, the first manipulator (1) drives the first grabbing mechanism to move, and the stroke of the first grabbing mechanism is larger than or equal to the distance between the test track and the buffer disc (3);

the buffer disc (3) is axially and rotatably arranged between the first mechanical arm (1) and the second mechanical arm (2), a plurality of assembly holes for placing the samples are formed in the buffer disc (3), the distance between the center of each assembly hole and the center of the buffer disc (3) is the same, and the distance between the centers of every two adjacent assembly holes is the same;

one end of the second mechanical arm (2) is provided with a second grabbing mechanism for grabbing samples, the second mechanical arm (2) drives the second grabbing mechanism to move, and the stroke of the second grabbing mechanism is larger than or equal to the distance between the buffer disc (3) and the sample rack loading area.

2. The interface apparatus of the test equipment of claim 1, further comprising a toggle mechanism; the shifting lever mechanism comprises a track group for transporting the sample rack and a mounting plate (4);

the track group is fixedly installed on the installation plate (4), one end of the track group is provided with the sample rack loading area, and the other end of the track group is connected with the test equipment.

3. The interface device of claim 2, wherein said toggle mechanism further comprises a toggle lever set;

the poking rod group is arranged on the mounting plate (4) and can drive the sample rack to move along the track group.

4. Interface device according to claim 3, characterized in that said set of levers comprises a first lever (5) and a dial block (6);

the first deflector rod (5) can drive the sample rack to move from the sample rack loading area to the testing equipment along the track group;

the shifting block (6) can drive the sample rack to move from the testing equipment to the sample rack loading area along the track group.

5. The interface device of claim 4, wherein the track set includes a first track and a second track; the poking rod group also comprises a second poking rod (7);

the first deflector rod (5) can drive the sample rack to move from the sample rack loading area to the testing equipment along the first track;

the shifting block (6) can drive the sample rack to move from the testing equipment to the sample rack loading area along the second track;

the second deflector rod (7) is mounted on the mounting plate (4) and can move the sample holder from the second rail to the first rail.

6. Interface device according to claim 5, characterized in that said toggle mechanism further comprises a first guide rod (8);

the first guide bar (8) is fixedly mounted on the mounting plate (4), and the first guide bar (8) is parallel to the first track, such that the sample holder is attached to the first guide bar (8).

7. Interface device according to claim 5, characterized in that said toggle mechanism further comprises a second guide rod (9);

the second guide bar (9) is fixedly mounted on the mounting plate (4), and the second guide bar (9) is parallel to the second track, such that the sample holder is attached to the second guide bar (9).

8. The interface device of claim 1, wherein the mounting hole is a stepped hole;

the stepped holes comprise a first stepped hole and a second stepped hole;

the cross-sectional diameter of the first stepped hole is greater than or equal to that of the sample, and the cross-sectional diameter of the second stepped hole is smaller than that of the sample.

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