CN214845562U

CN214845562U - Automatic electrifying equipment

Info

Publication number: CN214845562U
Application number: CN202022968037.7U
Authority: CN
Inventors: 万善军; 朱翔; 张伟; 许昌; 吴宗喜
Original assignee: LCFC Hefei Electronics Technology Co Ltd
Current assignee: LCFC Hefei Electronics Technology Co Ltd
Priority date: 2020-12-10
Filing date: 2020-12-10
Publication date: 2021-11-23
Anticipated expiration: 2030-12-10

Abstract

The utility model discloses an automatic electrifying device, which comprises a conveying mechanism, wherein the conveying mechanism can convey a tooling plate to an electrifying station along a first direction, the tooling plate is loaded with a product to be detected and is provided with a circuit, the product to be detected is electrically connected with the circuit on the tooling plate, and the first direction is parallel to the upper surface of the tooling plate; the first jacking mechanism is arranged below the conveying mechanism and can reciprocate along a second direction so as to jack the tooling plate to a set position or return the tooling plate to the conveying mechanism, and the second direction is vertical to the upper surface of the tooling plate; and the second jacking mechanism is arranged below the conveying mechanism, and is provided with a conductive probe, and the second jacking mechanism can drive the conductive probe to reciprocate along the second direction so as to enable the conductive probe to be in contact with or separated from a circuit on the tooling plate. The automatic electrifying equipment can be used for carrying out automatic electrifying detection on a product to be detected, so that the safety of electrifying detection is improved, and the efficiency of electrifying detection is improved.

Description

Automatic electrifying equipment

Technical Field

The utility model relates to an electronic product detection area especially relates to an automatic power-on equipment.

Background

After the notebook computer is produced, the notebook computer needs to be electrified and subjected to network connection detection so as to ensure the qualification of products.

At present, an existing processing mode is that an operator takes up a notebook computer from a production line tray and puts the notebook computer on a charging shelf, and a power line and a network cable are inserted into the shelf until the shelf is full, and the shelf is manually pushed to a testing area to perform power-on and network-on testing. Operating personnel need at first push away the goods shelves of test area to front end unloading station at whole in-process, again by artifical material loading, operating personnel's beat is relevant with the proficiency to every notebook computer all needs operating personnel to carry from top to bottom, causes the outward appearance to the computer very easily and damages, and moreover, whole work efficiency is lower.

SUMMERY OF THE UTILITY MODEL

The utility model provides an automatic power-on equipment to improve electronic equipment's circular telegram detection efficiency.

In order to realize the technical purpose, the utility model adopts the following technical scheme:

the utility model provides an automatic power-on equipment, include:

the conveying mechanism can convey a tooling plate to an electrifying station along a first direction, a product to be detected is loaded on the tooling plate, a circuit is arranged on the tooling plate, the product to be detected is in conductive connection with the circuit on the tooling plate, and the first direction is parallel to the upper surface of the tooling plate;

the first jacking mechanism is arranged below the conveying mechanism and can reciprocate along a second direction so as to jack the tooling plate to a set position or lift the tooling plate back to the conveying mechanism, and the second direction is vertical to the upper surface of the tooling plate;

the second jacking mechanism is arranged below the conveying mechanism, a conductive probe is arranged on the power output end of the second jacking mechanism, and the second jacking mechanism can drive the conductive probe to move in a reciprocating mode in the second direction, so that the conductive probe is in contact with or separated from a circuit on the tooling plate.

Preferably, the tool plate further comprises a blocking cylinder, the blocking cylinder is arranged at the electrifying station and located below the conveying mechanism, and the blocking cylinder can reciprocate along the second direction to block or avoid the tool plate.

Preferably, first climbing mechanism includes first jacking cylinder and jacking support plate, first jacking cylinder set up in the transport mechanism below, the jacking support plate sets up on the power take off of first jacking cylinder, first jacking cylinder can drive the jacking support plate is followed second direction reciprocating motion, so that the jacking support plate with the frock board supports top or the separation.

Preferably, the top of jacking support plate is equipped with the frock board reference column, the bottom of frock board with the position department that the frock board reference column corresponds has seted up positioning groove, first jacking cylinder can drive the jacking support plate is followed second direction reciprocating motion, so that the frock board reference column with positioning groove looks block or separation.

Preferably, the top of jacking support plate still is equipped with the balancing piece, the jacking support plate is the rectangle shape, tooling plate reference column is two, just the balancing piece is two, two tooling plate reference columns set up on one of them diagonal of jacking support plate, two balancing pieces set up on another diagonal of jacking support plate.

Preferably, the lifting device further comprises a fixed plate and a plurality of guide columns, the fixed plate is arranged below the conveying mechanism, and the first lifting cylinder is installed on the fixed plate;

the plurality of guide posts penetrate through the fixed plate in the second direction, the jacking support plate is arranged at the tops of the plurality of guide posts, and the first jacking cylinder can drive the jacking support plate to move in the second direction in a reciprocating mode so as to drive the plurality of guide posts to move in the second direction in a reciprocating mode relative to the fixed plate.

Preferably, the fixing plate is provided with guide holes at positions corresponding to the guide posts, each guide hole is provided with a shaft sleeve in a penetrating manner, and each guide post is arranged in each shaft sleeve in a penetrating manner along the second direction.

Preferably, the second jacking mechanism comprises a second jacking cylinder and a conductive probe mounting plate, the second jacking cylinder is arranged below the conveying mechanism, the conductive probe mounting plate is arranged at the power output end of the second jacking cylinder, and the conductive probe penetrates through the conductive probe mounting plate;

the second jacking cylinder can drive the conductive probe mounting plate to follow the second direction reciprocating motion so as to drive the conductive probe to contact or separate with a circuit on the tooling plate.

Preferably, the conveying mechanism comprises a normal area and an abnormal area, and the conveying mechanism can convey the detected products to the normal area or the abnormal area according to the detection result.

Preferably, the conveying mechanism comprises two mutually parallel conveying chains, and the first jacking mechanism and the second jacking mechanism are both located below the conveying mechanism and located between the two mutually parallel conveying chains.

Compared with the prior art, the utility model, beneficial effect as follows:

when the automatic electrifying equipment provided by the technical scheme of the utility model is used, firstly, the tooling plate bearing the product to be detected is conveyed to the electrifying station through the conveying mechanism; then, jacking the tooling plate to a set position through the first jacking mechanism, so that the tooling plate is separated from the conveying mechanism, and the stability of the tooling plate is ensured; then, the conductive probe is contacted with a circuit on the tooling plate through a second jacking mechanism, so that the product to be detected can be subjected to power-on and network-on detection; and finally, after the product to be detected is detected, the second jacking mechanism separates the conductive probe from the circuit on the tooling plate, and meanwhile, the first jacking mechanism descends the tooling plate back to the conveying mechanism to convey the tooling plate to the next station. Therefore, the automatic power-on equipment can be used for carrying out automatic power-on detection on the product to be detected, so that the process of manual carrying detection is avoided, the safety of power-on detection is improved, and the efficiency of power-on detection is improved.

Drawings

Fig. 1 is a schematic structural diagram of an automatic power-on device according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of another angle of the automatic power-on device according to the embodiment of the present invention;

fig. 3 is a schematic structural diagram of the automatic power-on device according to the embodiment of the present invention after the tooling plate is removed;

fig. 4 is a schematic structural diagram of the conductive probe mounting plate and the conductive probe.

In the drawings, each reference numeral denotes:

1. a first jacking mechanism; 11. a first jacking cylinder; 12. jacking the support plate; 121. tooling plate positioning columns; 122. a counterbalance; 2. a second jacking mechanism; 21. a second jacking cylinder; 22. a conductive probe mounting plate; 3. assembling a plate; 4. a conductive probe; 5. a fixing plate; 6. a guide post; 7. a shaft sleeve; 10. and (5) detecting the product to be detected.

Detailed Description

To make the objects, features and advantages of the present invention more obvious and understandable, the embodiments of the present invention are described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and obviously, 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 the skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, fig. 2 and fig. 4, an automatic power-on device according to an embodiment of the present invention includes: a conveying mechanism (not shown in the figure), a first jacking mechanism 1, a second jacking mechanism 2, a tooling plate 3 and a conductive probe 4. The tooling plate 3 is used for bearing a product 10 to be detected, meanwhile, a circuit is arranged on the tooling plate 3, after the product 10 to be detected is placed on the tooling plate 3, the product 10 to be detected is in conductive connection with the circuit of the tooling plate 3 through a wire, and the conductive connection comprises power connection and network connection.

The conveying mechanism can convey the tooling plate 3 to the electrifying station along a first direction, and the first direction is parallel to the upper surface of the tooling plate 3; the first jacking mechanism 1 is arranged below the conveying mechanism and can reciprocate along a second direction so as to jack the tooling plate 3 to a set position or lift the tooling plate 3 back to the conveying mechanism, and the second direction is vertical to the upper surface of the tooling plate 3; the second jacking mechanism 2 is arranged below the conveying mechanism, a conductive probe 4 is arranged on the power output end of the second jacking mechanism 2, and the second jacking mechanism 2 can drive the conductive probe 4 to reciprocate along the second direction, so that the conductive probe 4 is in contact with or separated from a circuit on the tooling plate 3.

In this embodiment, in a specific use, the tooling plate 3 carrying the product 10 to be detected is first conveyed to the electrifying station by the conveying mechanism; then, the tooling plate 3 is jacked to a set position through the first jacking mechanism 1, so that the tooling plate 3 is separated from the conveying mechanism, and the stability of the tooling plate 3 is ensured; then, the conductive probe 4 is contacted with a circuit on the tooling plate 3 through the second jacking mechanism 2 so that the product 10 to be detected is in a power-on state, and therefore power-on and power-on network detection can be carried out on the product 10 to be detected; finally, after the product 10 to be detected is detected, the second jacking mechanism 2 separates the conductive probe 4 from the circuit on the tooling plate 3, so that the product 10 to be detected is in a power-off state, and meanwhile, the first jacking mechanism 1 descends the tooling plate 3 back to the conveying mechanism to be conveyed to the next station. Therefore, the automatic power-on equipment can be used for automatically carrying out power-on detection on the product 10 to be detected, so that the process of manual carrying detection is avoided, the safety of power-on detection is improved, and the efficiency of power-on detection is improved.

In the above embodiment, preferably, the conveying mechanism includes two mutually parallel conveying chains, and the first jacking mechanism 1 and the second jacking mechanism 2 are both located below the conveying mechanism and between the two mutually parallel conveying chains. Specifically, frock board 3 bears on two conveying chains to make the middle zone of frock board 3 bottom just to first climbing mechanism 1 and second climbing mechanism 2, from this, can very conveniently carry out the jacking to frock board 3 through first climbing mechanism 1, and contact or separate the circuit on electrically conductive probe 4 and the frock board 3 through second climbing mechanism 2. It should be noted that the specific structural form of the transmission mechanism in this embodiment is only one of the preferred embodiments, but is not limited to the specific structural type of the transmission mechanism, and in other embodiments, other suitable structures with transmission function may be selected according to the need.

In the above embodiment, it is preferable that a blocking cylinder (not shown) is further included, the blocking cylinder is disposed at the power-on station and located below the conveying mechanism, and the blocking cylinder is capable of reciprocating in the second direction to block or avoid the tooling plate 3. Specifically, before the conveying mechanism conveys the tooling plate 3 to the electrifying station, the power shaft of the blocking cylinder extends in advance, and along with the continuous conveying of the conveying mechanism, the edge of the tooling plate 3 can touch the power shaft of the blocking cylinder, so that the tooling plate 3 is blocked by the power shaft of the blocking cylinder to limit the tooling plate 3 at the electrifying station, and the tooling plate 3 can be jacked to a set position by the first jacking mechanism 1; after the tooling plate 3 is separated from the conveying mechanism, the power shaft of the blocking cylinder contracts to the initial position to avoid the tooling plate 3, so that the tooling plate 3 which is detected and completed can be smoothly conveyed to the next station, and meanwhile, the blocking cylinder prepares for blocking the tooling plate 3 for the next time. Therefore, the blocking cylinder can avoid the position of the tooling plate 3 from deviating, and the position precision of the tooling plate 3 is improved. In addition, it is easily understood that the blocking cylinder in this embodiment is only one embodiment, and other blocking mechanisms may be adopted in other embodiments, for example: the motor adds the baffle, sets up the motor in the transport mechanism below, simultaneously, with the baffle installation on the motor, it is rotatory to drive the baffle through the motor to make the baffle block or dodge frock board 3.

Referring to fig. 3, in the above embodiment, preferably, the first jacking mechanism 1 includes a first jacking cylinder 11 and a jacking support plate 12, the first jacking cylinder 11 is disposed below the conveying mechanism, the jacking support plate 12 is disposed on the power output end of the first jacking cylinder 11, and the first jacking cylinder 11 can drive the jacking support plate 12 to reciprocate along the second direction, so that the jacking support plate 12 abuts against or separates from the tooling plate 3. Specifically, in this embodiment, by jacking up the carrier plate 12 as a carrying platform for the tooling plate 3, meanwhile, the jacking carrier plate 12 is positioned below the tooling plate 3, and after the tooling plate 3 is conveyed to the electrifying station, the first jacking cylinder 11 will drive the jacking support plate 12 to ascend along the second direction until the jacking support plate 12 contacts with the bottom of the tooling plate 3, and with the continuous jacking of the first jacking cylinder 11, the tooling plate 3 is separated from the conveying mechanism and is jacked up at a set position, at the moment, the product 10 to be detected on the tooling plate 3 can be detected through the communication network, after the detection is finished, the first jacking cylinder 11 drives the jacking support plate 12 to descend along the second direction until the bottom of the tooling plate 3 is contacted with the conveying mechanism, and with the continuous descending of the first jacking cylinder 11, the tooling plate 3 is separated from the jacking carrier plate 12, and the conveying mechanism conveys the detected product to the next station.

As shown in fig. 3, in the above embodiment, preferably, the top of the jacking support plate 12 is provided with a tooling plate positioning column 121, a positioning groove (not shown) is formed at a position corresponding to the tooling plate positioning column 121 at the bottom of the tooling plate 3, and the first jacking cylinder 11 can drive the jacking support plate 12 to reciprocate along the second direction, so that the tooling plate positioning column 121 is engaged with or disengaged from the positioning groove. Specifically, as the first jacking cylinder 11 drives the jacking support plate 12 to continuously rise along the second direction, the tooling plate positioning column 121 gradually approaches the positioning groove, and when the jacking support plate 12 contacts with the bottom of the tooling plate 3, the tooling plate positioning column 121 is clamped with the positioning groove, so that the relative movement of the tooling plate 3 and the jacking support plate 12 can be limited; after the detection is completed, the jacking support plate 12 is driven by the first jacking cylinder 11 to continuously descend along the second direction, and when the tooling plate 3 is separated from the jacking support plate 12, the tooling plate positioning column 121 is separated from the positioning groove. From this, utilize this frock board reference column 121 and positioning groove can improve frock board 3's stability to be favorable to treating to detect product 10 and carry out the circular telegram and lead to the net and detect.

As shown in fig. 3, in the above embodiment, preferably, a balance weight 122 is further disposed on the top of the jacking carrier plate 12, the jacking carrier plate 12 is rectangular, two tooling plate positioning columns 121 are provided, and two balance weights 122 are provided, two tooling plate positioning columns 121 are disposed on one diagonal of the jacking carrier plate 12, and two balance weights 122 are disposed on the other diagonal of the jacking carrier plate 12. Specifically, in this embodiment, through the diagonal setting with two frock board reference columns 121 along rectangle jacking support plate 12, can restrict the relative movement of jacking support plate 12 and frock board 3 on the one hand, and on the other hand can restrict the relative rotation of jacking support plate 12 and frock board 3 to guarantee the location effect. In addition, this balancing piece 122 can play the effect of balanced frock board 3, avoids another diagonal of frock board 3 on the two angles department in unsettled state to guarantee the supporting effect to frock board 3.

In the above embodiment, preferably, the automatic energization apparatus further includes a fixed plate 5 and a plurality of guide posts 6, the fixed plate 5 is disposed below the conveying mechanism, and the first jacking cylinder 11 is mounted on the fixed plate 5; the guide posts 6 penetrate through the fixing plate 5 along the second direction, the jacking support plate 12 is arranged at the tops of the guide posts 6, and the first jacking cylinder 11 can drive the jacking support plate 12 to move in a reciprocating mode along the second direction so as to drive the guide posts 6 to move in a reciprocating mode along the second direction relative to the fixing plate 5. Specifically, in this embodiment, guide post 6 is four, and four guide posts 6 wear to establish the four corners of fixed plate 5 respectively to can provide sufficient installation space for first jacking cylinder 11, drive jacking support plate 12 at first jacking cylinder 11 and follow second direction reciprocating motion's in-process, utilize a plurality of guide posts 6 to lead to the removal of jacking support plate 12, take place the skew in order to avoid jacking support plate 12 when removing, thereby influence the position precision of frock board 3.

In the above embodiment, preferably, the fixing plate 5 has guide holes at positions corresponding to the plurality of guide posts 6, each guide hole has a shaft sleeve 7, and each guide post 6 is inserted in each shaft sleeve 7 along the second direction. Specifically, in this embodiment, by providing the shaft sleeve 7 in the guide hole, the guide post 6 can be prevented from directly contacting the fixing plate 5, and generally, a material with lower hardness and better wear resistance can be selected as the shaft sleeve 7, so that wear to the guide post 6 and the fixing plate 5 can be reduced, and after the shaft sleeve 7 is worn to a certain extent, the shaft sleeve 7 can be replaced, which can reduce the production cost compared with the direct replacement of the guide post 6 and the fixing plate 5.

Referring to fig. 3 and 4, in the above embodiment, preferably, the second jacking mechanism 2 includes a second jacking cylinder 21 and a conductive probe mounting plate 22, the second jacking cylinder 21 is disposed below the conveying mechanism, the conductive probe mounting plate 22 is disposed on the power output end of the second jacking cylinder 21, and the conductive probe 4 is disposed on the conductive probe mounting plate 22 in a penetrating manner; the second jacking cylinder 21 can drive the conductive probe mounting plate 22 to reciprocate along the second direction so as to drive the conductive probe 4 to contact or separate with the circuit on the tooling plate 3. Wherein, conductive probe mounting panel 22 is used for providing the installation basis for conductive probe 4, after first jacking cylinder 11 with the jacking of frock board 3 to the set position, second jacking cylinder 21 drives conductive probe mounting panel 22 and rises along the second direction, thereby it contacts with the circuit on frock board 3 to drive conductive probe 4, in order to realize the effect of circular telegram, after the detection is accomplished, second jacking cylinder 21 drives conductive probe mounting panel 22 and descends along the second direction, thereby drive the circuit phase separation on conductive probe 4 and the frock board 3, in order to realize the effect of outage.

In the above embodiment, preferably, the conveying mechanism includes a normal area (not shown in the figure) and an abnormal area (not shown in the figure), and the conveying mechanism can convey the detected product to the normal area or the abnormal area according to the detection result. Specifically, after the product detection is completed, if the detected product belongs to a normal product, the conveying mechanism conveys the product to the normal area for the next operation, and if the detected product belongs to a defective product, the conveying mechanism conveys the defective product to the abnormal area, and the defective product in the abnormal area is collected for the subsequent treatment. From this, utilize this transport mechanism can classify the product that has detected to distinguish which product belongs to normal product, which product belongs to bad product, and then avoided bad product to flow into the production line, cause the unnecessary loss.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

The above description is only the specific embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art can easily think of the changes or replacements within the technical scope of the present invention, and all should include the shell within the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims

1. An automatic power-on device, comprising:

2. The automatic energization apparatus according to claim 1, further comprising a blocking cylinder provided at the energization station and located below the conveyance mechanism, the blocking cylinder being capable of reciprocating in the second direction to block or avoid the tooling plate.

3. The automatic power-on equipment of claim 1, wherein the first jacking mechanism comprises a first jacking cylinder and a jacking support plate, the first jacking cylinder is arranged below the conveying mechanism, the jacking support plate is arranged on a power output end of the first jacking cylinder, and the first jacking cylinder can drive the jacking support plate to reciprocate along the second direction, so that the jacking support plate is abutted against or separated from the tooling plate.

4. The automatic power-on equipment as claimed in claim 3, wherein a tooling plate positioning column is disposed on a top of the jacking support plate, a positioning groove is disposed at a position corresponding to the tooling plate positioning column on a bottom of the tooling plate, and the first jacking cylinder can drive the jacking support plate to reciprocate along the second direction, so that the tooling plate positioning column is engaged with or disengaged from the positioning groove.

5. The automatic power-on device according to claim 4, wherein a balance block is further disposed on a top of the jacking carrier plate, the jacking carrier plate is rectangular, the number of the tooling plate positioning columns is two, and the number of the balance block is two, the two tooling plate positioning columns are disposed on one diagonal of the jacking carrier plate, and the two balance blocks are disposed on the other diagonal of the jacking carrier plate.

6. The automatic energization apparatus according to claim 3, further comprising a fixed plate disposed below the conveyance mechanism, and a plurality of guide posts, the first jacking cylinder being mounted on the fixed plate;

7. The automatic power-on equipment according to claim 6, wherein guide holes are formed in the fixing plate at positions corresponding to the plurality of guide posts, a shaft sleeve is inserted into each guide hole, and each guide post is inserted into each shaft sleeve along the second direction.

8. The automatic power-on equipment of claim 1, wherein the second jacking mechanism comprises a second jacking cylinder and a conductive probe mounting plate, the second jacking cylinder is arranged below the conveying mechanism, the conductive probe mounting plate is arranged on a power output end of the second jacking cylinder, and the conductive probe penetrates through the conductive probe mounting plate;

9. The automatic energization apparatus according to any one of claims 1 to 8, wherein said conveying mechanism includes a normal zone and an abnormal zone, said conveying mechanism being capable of conveying the detected product to said normal zone or said abnormal zone according to the detection result.

10. The automatic energization apparatus according to any one of claims 1 to 8, wherein said conveying mechanism includes two mutually parallel conveying chains, said first and second jacking mechanisms each being located below said conveying mechanism and between said two mutually parallel conveying chains.