CN217717963U - Testing arrangement based on long-life lithium cell probe production usefulness - Google Patents

Abstract

The utility model provides a test device for producing a probe based on a long-life lithium battery, which relates to the technical field of lithium battery probe test equipment and aims to solve the problem that the probe test is carried out on the original test device by manual placing and taking off, so that the test device is not convenient to use, and the test efficiency is reduced; the second vertical frame is arranged at the top end of the left side of the sliding groove rod; the third vertical frame is arranged on the right side of the first vertical frame; the fourth vertical frame is arranged at the rear ends of the first vertical frame and the sliding chute rod; and the sliding block is slidably arranged in the sliding groove rod. The utility model discloses in make testing arrangement realize that single the dropping of probe is put into and single promotion male test operation because square pole.

Description

Testing arrangement based on long-life lithium cell probe production usefulness

Technical Field

The utility model relates to a lithium cell probe test equipment technical field, more specifically say, in particular to testing arrangement based on long-life lithium cell probe production usefulness.

Background

The probe has played the effect of switching on the circuit, and the lithium cell probe is the probe that the cooperation was used in the lithium cell simultaneously, and when lithium cell probe production, just need use the dedicated testing arrangement of lithium cell probe production to test one by one, is convenient for sieve out unqualified probe.

When a testing arrangement based on long-life lithium cell probe production usefulness was used, because original testing arrangement still need all place and the operating procedure who takes off through the manual probe test that carries on, not only make testing arrangement's use convenient inadequately, single manual placing still greatly reduced testing arrangement's efficiency of software testing simultaneously.

Therefore, in view of the above, research and improvement are made on the existing structure and defects, and a test device for producing a lithium battery probe with a long service life is provided, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problem, the utility model provides a testing arrangement based on long-life lithium cell probe production usefulness to solve still need whole operation steps of placing and taking off through manual at original testing arrangement and carry out the probe test, not only make testing arrangement's use not convenient enough, still reduced efficiency of software testing's problem simultaneously.

The utility model relates to a testing arrangement's purpose and efficiency based on long-life lithium cell probe production usefulness is reached by following concrete technological means:

a testing device for producing a long-life lithium battery probe comprises a first vertical frame and a sliding groove rod, wherein the sliding groove rod is transversely arranged on the outer end face of the left side of the first vertical frame; the second vertical frame is arranged at the top end of the left side of the sliding groove rod; the third vertical frame is arranged on the right side of the first vertical frame; the fourth vertical frame is arranged at the rear ends of the first vertical frame and the sliding chute rod; the sliding block is slidably arranged in the sliding groove rod; the first round rod is installed in the second vertical frame in a penetrating mode; the second round rod is installed in the fourth vertical frame and the first vertical frame in a penetrating mode; the third round rod penetrates through the inner end of the upper side of the third vertical frame; and the fourth round rod penetrates through the inner end of the lower side of the third vertical frame.

Further, the first vertical frame comprises a tester and a limiting cylinder, and the tester is installed on the first vertical frame; the limiting cylinder is fixedly arranged on the lower side of the rear end of the first vertical frame; the sliding chute rod comprises a feed hopper, the feed hopper is arranged at the upper end of the rear side of the sliding chute rod, and the feed hopper is correspondingly arranged at the upper side of the square rod; the second vertical frame comprises a first round hole, the middle inner side of the second vertical frame is provided with a first round hole, and a first round rod is installed in the first round hole in a penetrating mode.

Furthermore, the third vertical frame comprises second round holes, the two second round holes are respectively formed in the upper end and the lower end of the third vertical frame, the third round rod penetrates through the second round hole in the upper position, and the fourth round rod penetrates through the second round hole in the lower position; the sliding block comprises square rods and a connecting rod, the pair of square rods are respectively arranged on the left side and the right side of the rear end of the sliding block, and the square rods are slidably arranged in the sliding groove rods; the top end of the left side of the connecting rod is connected and installed on the sliding block; the first round rod comprises a gear a and an adjusting groove rod, the gear a is fixedly installed at the top end of the rear side of the first round rod, the rear side of the second vertical frame is provided with a double-head motor, the middle front side of the double-head motor is provided with a gear d, and the gear d and the gear a on the front side of the double-head motor are connected through a chain; the adjusting groove rod is fixedly installed at the top end of the front side of the first round rod, the top end of the right side of the connecting rod is connected with and provided with an adjusting block, and the adjusting block is installed in the adjusting groove rod in a sliding mode.

Furthermore, the second round rod comprises a fluted disc, a gauge disc and a bevel gear A, the fluted disc is arranged at the central left end of the second round rod, a shifting block is arranged at the central rear side of the double-head motor, and the shifting block on the double-head motor is meshed with the fluted disc; the gauge disc is arranged on the left side of the second round bar in the middle; the bevel gear A is arranged at the right end in the middle of the second round rod; the third round bar comprises a gear B and a bevel gear B, and the gear B is arranged on the middle front side of the third round bar; the bevel gear B is arranged on the middle rear side of the third round rod and connected with the bevel gear A through a chain; the fourth round rod comprises a gear c, an eccentric block and a push rod, the gear c is installed on the front side of the fourth round rod in the middle, and the gear c is connected with the gear b through a chain; the eccentric block is arranged on the middle rear side of the fourth round rod; the push rod is connected and installed on the eccentric block, and the push rod is installed in the limiting cylinder in a sliding mode.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. the utility model has the advantages that the left end face of the square rod is provided with the groove structure, and the right end face of the square rod is of a plane structure, so that the test device realizes the test operation of dropping and inserting a single probe and pushing and inserting the single probe, and the use of the test device is more convenient;

2. the utility model discloses because the push rod uses the rotatory operation of eccentric block as the removal power, and then makes the push rod promote from the specification dish to the probe that has detected and drop, will place by hand and the whole structure linkage that use of the operating procedure of taking off replaces the completion, improves testing arrangement's efficiency of software testing greatly.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Drawings

Fig. 1 is a schematic view of the top left front axial view structure of the present invention.

Fig. 2 is a schematic view of the upper left rear side of the present invention.

Fig. 3 is a schematic view of the structure of the first standing frame, the chute rod, the second standing frame, the third standing frame and the fourth standing frame.

Fig. 4 is an axial view structure diagram of the feeding hopper of the present invention.

Fig. 5 is a schematic view of the structure of the slider and the first round rod.

Fig. 6 is a schematic view of the structure of the second round bar and the third round bar in partial axial view.

Fig. 7 is a schematic axial view of a fourth round rod of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a first stand; 101. a tester; 102. a limiting cylinder; 2. a chute bar; 201. a feed hopper; 3. a second stand; 301. a first circular hole; 4. a third vertical frame; 401. a second circular hole; 5. a fourth stand; 6. a slider; 601. a square rod; 602. a connecting rod; 7. a first round bar; 701. a gear a; 702. adjusting the groove rod; 8. a second round bar; 801. a fluted disc; 802. a specification disk; 803. a bevel gear A; 9. a third round bar; 901. a gear b; 902. a bevel gear B; 10. a fourth round bar; 1001. a gear c; 1002. an eccentric block; 1003. a push rod.

Detailed Description

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be directly connected or indirectly connected through a central medium. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The embodiment is as follows:

as shown in figures 1 to 7:

the utility model provides a test device for producing a probe based on a long-life lithium battery, which comprises a first vertical frame 1, wherein the first vertical frame 1 is installed to determine the initial structural installation position of the test device, a sliding chute rod 2 is transversely installed on the outer end surface of the left side of the first vertical frame 1, and the sliding chute rod 2 is installed at two ends of the first vertical frame 1 and a second vertical frame 3 for position fixation; the second vertical frame 3 is arranged at the top end of the left side of the sliding chute rod 2; the third vertical frame 4 is arranged on the right side of the first vertical frame 1, and the second vertical frame 3, the third vertical frame 4 and the fourth vertical frame 5 are all frame supporting structures of the testing device; the fourth vertical frame 5 is arranged at the rear ends of the first vertical frame 1 and the sliding chute rod 2, so that the structural operation and the operation of the testing device are more convenient; the sliding block 6 is arranged in the sliding groove rod 2 in a sliding mode, the sliding block 6 can move left and right along a hollow structure formed in the sliding groove rod 2, and the sliding groove rod 2 limits the sliding track of the sliding block 6; the first round rod 7 is arranged in the second vertical frame 3 in a penetrating mode, and the first round rod 7 flexibly rotates on the second vertical frame 3; the second round rod 8 is arranged in the fourth vertical frame 5 and the first vertical frame 1 in a penetrating mode, and the second round rod 8 flexibly rotates on the fourth vertical frame 5 and the first vertical frame 1; the third round rod 9, the third round rod 9 runs through and installs in the upside inner end of the third vertical frame 4; the fourth round rod 10 and the fourth round rod 10 are installed at the inner end of the lower side of the third vertical frame 4 in a penetrating mode, the third round rod 9 and the fourth round rod 10 are all flexibly rotated on the third vertical frame 4, the rotating structure homoenergetic of the testing device can be installed in a limiting mode, the accuracy of structure operation is guaranteed, meanwhile, the displacement phenomenon of the testing device structure when the testing device structure rotates is prevented, and therefore the practicability of the testing device is improved.

The first vertical frame 1 comprises a tester 101 and a limiting cylinder 102, the tester 101 is installed on the first vertical frame 1, the tester 101 is a main device for testing by inserting a probe, the performances of the probe such as a conducting circuit and the like are accurately tested, the probe is ejected after detection, and an alarm is given when an unqualified probe is tested; the limiting cylinder 102 is fixedly arranged at the lower side of the rear end of the first vertical frame 1, and the mounting position of the limiting cylinder 102 is opposite to the position, at the lowest side of the second round bar 8, of the specification plate 802 in a rotating mode, so that the structural operation reasonability of the testing device is guaranteed.

Wherein, spout pole 2 includes feeder hopper 201, and feeder hopper 201 is installed in the rear side upper end of spout pole 2, and feeder hopper 201 corresponds the upside of installing at square pole 601, and some semi-manufactured goods probes of waiting for the test are placed to the inboard of feeder hopper 201, will realize that testing arrangement peer semi-manufactured goods probes that await measuring to be put into in proper order and single detection, strengthen testing arrangement's test detail, improve testing arrangement's test simultaneously.

Wherein, second grudging post 3 includes first round hole 301, and first round hole 301 has been seted up to the inboard placed in the middle of second grudging post 3, and first round bar 7 runs through to be installed in first round hole 301, and first round hole 301 is spacing to first round bar 7, and first round bar 7 can rotate in first round hole 301 in a flexible way for first round bar 7 can be installed on vertical same straight line with the round bar on the double-end motor, makes first round bar 7 also have power.

Wherein, third grudging post 4 includes second round hole 401, two department second round holes 401 are seted up respectively at the upper and lower both ends of third grudging post 4, and third round bar 9 runs through to be installed in the second round hole 401 of upper side position, fourth round bar 10 runs through to be installed in the second round hole 401 of lower side position, two department second round holes 401 all are spacing to third round bar 9 and fourth round bar 10 position for structure mounting position between third round bar 9 and the fourth round bar 10 is in vertical collinear the same straight line, be convenient for the connection of gear b901 and gear c1001 of rear end.

Wherein, slider 6 includes square pole 601 and connecting rod 602, the left and right sides at slider 6 rear end is installed respectively to a pair of square pole 601, and square pole 601 slidable mounting is in spout pole 2, square pole 601 has two rectangle massive structures to constitute, and left structural up end set up with the unanimous recess of probe size, the up end of right side structure then is the plane, only need to carry out a set of probe that needs the test and all pour into feeder hopper 201 in, just realized that single the falling of probe is in the recess of square pole 601 through the groove structure of square pole 601, and fix the probe that needs the test through the structure buckle of recess, slider 6 drives square pole 601 and removes about simultaneously, accomplish the insert operation of probe, make testing arrangement's use more convenient, and improve efficiency of software testing.

The first round rod 7 comprises a gear a701 and an adjusting groove rod 702, the gear a701 is fixedly installed at the top end of the rear side of the first round rod 7, the rear side of the second vertical frame 3 is provided with a double-head motor, the middle front side of the double-head motor is provided with a gear d, the gear d on the front side of the double-head motor is connected with the gear a701 through a chain, the gear a701 and the gear d are driven by the double-head motor to synchronously rotate, the first round rod 7 and the adjusting groove rod 702 are both rotated, and equipment for providing main power is additionally arranged on the testing device; adjusting groove rod 702 is fixedly installed at the front side top end of first round bar 7, the right side top end of connecting rod 602 is connected with and installed the regulating block, and regulating block slidable mounting is in adjusting groove rod 702, connecting rod 602 can slide adjustment in adjusting groove rod 702 from top to bottom through the regulating block, the left side top end of connecting rod 602 is connected and installed on slider 6, connecting rod 602 is the structure that carries out interconnect with slider 6 and adjusting groove rod 702, and the regulating block on connecting rod 602 is more to the central point of adjusting groove rod 702 and is adjusted, adjusting groove rod 702 is rotatory and drive the pulling range of connecting rod 602 the littleer, otherwise, adjusting groove rod 702 is rotatory and drive the pulling range of connecting rod 602 the bigger, can adjust the structure operation range at will with adjusting groove rod 702 and connecting rod 602 according to the probe length that needs to test, finally realize square pole 601 and stretch into the test structure with the probe, make testing arrangement can adapt to the probe use of any size, improve testing arrangement's practicality.

The second round rod 8 comprises a fluted disc 801, a gauge disc 802 and a bevel gear A803, the fluted disc 801 is arranged at the central left end of the second round rod 8, a shifting block is arranged at the central rear side of the double-head motor, the shifting block on the double-head motor is meshed with the fluted disc 801, and the fluted disc 801 realizes indirect rotation of the second round rod 8, the gauge disc 802 and the bevel gear A803 through meshing shifting operation of the shifting blocks; the left side placed in the middle at second round bar 8 is installed to specification dish 802, the circular port has been seted up at the structure center of specification dish 802, the diameter size of circular port is unanimous with the probe diameter size that needs the test, and whether the diameter size that the circular port both can detect probe on the specification dish 802 is qualified, the circular port on the specification dish 802 can also carry out interim fixed position to the probe simultaneously, the qualified probe of diameter will run through and install in the circular port of specification dish 802, specification dish 802 drives the probe and carries out the rotation downwards and transport, make testing arrangement's test more convenient.

The third round bar 9 comprises a gear B901 and a bevel gear B902, and the gear B901 is installed on the middle front side of the third round bar 9; a bevel gear B902 is arranged on the middle rear side of the third round rod 9; the bevel gear A803 is installed at the right middle end of the second round rod 8, and the installed bevel gear A803 conveys the power on the second round rod 8 downwards onto the third round rod 9; bevel gear B902 and bevel gear A803 pass through the chain connection, and third round bar 9, gear B901 and bevel gear B902 are the middle and link up and transmit the major structure of power, realize providing three structures that have the power demand respectively with a double-end motor on the testing arrangement, have practiced thrift electric energy consumption greatly with testing arrangement.

The fourth round bar 10 comprises a gear c1001, an eccentric block 1002 and a push rod 1003, the gear c1001 is installed on the front side of the fourth round bar 10 in the middle, the gear c1001 is connected with a gear b901 through a chain, and the gear b901 and the gear c1001 are in a structure which realizes linkage rotation through meshing; the eccentric block 1002 is installed on the central rear side of the fourth round bar 10; the push rod 1003 is connected with and mounted on the eccentric block 1002, the push rod 1003 is slidably mounted in the limiting cylinder 102, the push rod 1003 limits the position through the limiting cylinder 102, the push rod 1003 can only move left and right through an inner side structure of the limiting cylinder 102, the push rod 1003 uses rotation operation of the eccentric block 1002 as moving power, it is further guaranteed that the push rod 1003 faces the specification disc 802 on the lowest side and pushes the probes on the specification disc 802 to move to the left side, falling of the detected probes on the specification disc 802 is completed, all operation steps of manual placement and taking down are replaced by structural linkage, and the test efficiency of the test device is improved once again.

The specific use mode and function of the embodiment are as follows:

in the using process, two material receiving boxes are placed at the lower end of the rear side of the first vertical frame 1, then a group of probes to be tested are poured into the material feeding hopper 201, the positions of the adjusting blocks of the connecting rod 602 on the adjusting groove rod 702 are adjusted according to the lengths of the group of probes, then a double-head motor is started, the double-head motor drives a gear d at the front side and a shifting block at the rear side to rotate, the gear d drives a gear a701, a first round rod 7 and the adjusting groove rod 702 to rotate in a first round hole 301 of the second vertical frame 3 through chains, the adjusting groove rod 702 rotates and drives a sliding block 6 and a square rod 601 to repeatedly move in a sliding groove rod 2 through the connecting rod 602, when a structure with grooves in the left side of the square rod 601 moves right end of the material feeding hopper 201, the probes are buckled and installed in the grooves of the rod 601 one by one, the square rod 601 moves forwards to enable the left side groove of the square rod 601 to push the probes to move and simultaneously insert the scale 802 and the tester 101, and the right side plane of the rod 601 abuts against the lower side of the feeding hopper 201 to prevent the probes from falling, the qualified gauge 101 and the probes pass through the sliding rod 601 and the sliding rod 601 repeatedly before the sliding operation of the sliding rod 601;

meanwhile, the detected probe is automatically ejected through the tester 101, the probe positions the specification disc 802 in a ring manner, meanwhile, a dial block on the motor synchronously dials the fluted disc 801 to rotate, the second round rod 8 is driven by the fluted disc 801 to rotate on the fourth vertical frame 5, the specification disc 802 rotates along with the rotation of the second round rod 8, the specification disc 802 rotates and conveys the tested probe, when the specification disc 802 moves on the limiting cylinder 102 on the lower side, the bevel gear A803 rotates to be meshed with the bevel gear B902, the third round rod 9 and the fourth round rod 10 are connected through a chain between the gear B901 and the gear c1001, the third round rod 9 and the fourth round rod 10 rotate in the second round hole 401 on the third vertical frame 4, the fourth round rod 10 drives the eccentric block 1002 to rotate, the eccentric block 1002 rotates repeatedly and pulls the push rod 1003 to move in the limiting cylinder 102, and the use process of the testing device is completed.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (10)

1. The testing device for producing the long-life lithium battery probe is characterized by comprising a first vertical frame (1) and a sliding groove rod (2), wherein the sliding groove rod (2) is transversely arranged on the outer end face of the left side of the first vertical frame (1); the second vertical frame (3), the second vertical frame (3) is installed at the top end of the left side of the sliding groove rod (2); the third vertical frame (4), the said third vertical frame (4) is installed on the right side of the first vertical frame (1); the fourth vertical frame (5), the said fourth vertical frame (5) is installed in the first vertical frame (1) and rear end of the sliding chute pole (2); the sliding block (6), the sliding block (6) is installed in the sliding groove rod (2) in a sliding mode; the first round rod (7), the first round rod (7) is installed in the second vertical frame (3) in a penetrating mode; the second round rod (8), the second round rod (8) is installed in the fourth vertical frame (5) and the first vertical frame (1) in a penetrating mode; the third round rod (9), the third round rod (9) is installed at the inner end of the upper side of the third vertical frame (4) in a penetrating way; and the fourth round rod (10), and the fourth round rod (10) is installed at the inner end of the lower side of the third stand (4) in a penetrating manner.

2. The test device for producing the long-life lithium battery probe is characterized in that the first vertical frame (1) comprises a tester (101) and a limiting cylinder (102), wherein the tester (101) is installed on the first vertical frame (1); the limiting cylinder (102) is fixedly mounted on the lower side of the rear end of the first vertical frame (1).

3. The test device for producing the long-life lithium battery probe is characterized in that the chute rod (2) comprises a feed hopper (201), and the feed hopper (201) is arranged at the upper end of the rear side of the chute rod (2).

4. The test device for producing the long-life lithium battery probe is characterized in that the second vertical frame (3) comprises a first round hole (301), the middle inner side of the second vertical frame (3) is provided with the first round hole (301), and the first round rod (7) is installed in the first round hole (301) in a penetrating mode.

5. The testing device for the production of the long-life lithium battery probe as recited in claim 1, wherein the third vertical frame (4) comprises a second circular hole (401), two second circular holes (401) are respectively formed at the upper end and the lower end of the third vertical frame (4), the third circular rod (9) is installed in the second circular hole (401) at the upper side position in a penetrating manner, and the fourth circular rod (10) is installed in the second circular hole (401) at the lower side position in a penetrating manner.

6. The test device for producing the long-life lithium battery probe is characterized in that the sliding block (6) comprises a square rod (601) and a connecting rod (602), the square rods (601) are respectively arranged at the left side and the right side of the rear end of the sliding block (6), and the square rods (601) are slidably arranged in the chute rod (2); the top end of the left side of the connecting rod (602) is connected and installed on the sliding block (6).

7. The test device for producing the long-life lithium battery probe is characterized in that the first round rod (7) comprises a gear a (701) and an adjusting groove rod (702), the gear a (701) is fixedly installed at the top end of the rear side of the first round rod (7), the rear side of the second vertical frame (3) is provided with a double-head motor, the middle front side of the double-head motor is provided with a gear d, and the gear d and the gear a (701) on the front side of the double-head motor are connected through a chain; the adjusting groove rod (702) is fixedly installed at the top end of the front side of the first round rod (7), the adjusting block is installed at the top end of the right side of the connecting rod (602) in a connected mode, and the adjusting block is installed in the adjusting groove rod (702) in a sliding mode.

8. The test device for producing the long-life lithium battery probe is characterized in that the second round rod (8) comprises a fluted disc (801), a specification disc (802) and a bevel gear A (803), the fluted disc (801) is arranged at the central left end of the second round rod (8), a shifting block is arranged at the central rear side of the double-head motor, and the shifting block on the double-head motor is meshed with the fluted disc (801); the gauge disc (802) is mounted on the centered left side of the second round bar (8); the bevel gear A (803) is installed at the right middle end of the second round rod (8).

9. The testing device for the production of the long-life lithium battery-based probe is characterized in that the third round bar (9) comprises a gear B (901) and a bevel gear B (902), wherein the gear B (901) is arranged on the central front side of the third round bar (9); the bevel gear B (902) is arranged on the middle rear side of the third round rod (9), and the bevel gear B (902) is connected with the bevel gear A (803) through a chain.

10. The testing device for producing the long-life lithium battery probe is characterized in that the fourth round rod (10) comprises a gear c (1001), an eccentric block (1002) and a push rod (1003), wherein the gear c (1001) is installed on the central front side of the fourth round rod (10), and the gear c (1001) is connected with the gear b (901) through a chain; the eccentric block (1002) is arranged on the middle rear side of the fourth round rod (10); the push rod (1003) is connected and installed on the eccentric block (1002), and the push rod (1003) is installed in the limiting cylinder (102) in a sliding mode.

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