CN217112642U - Battery charging detection cabinet - Google Patents

Abstract

The utility model discloses a battery charging detection cabinet, which comprises a base frame, a transverse moving mechanism, a linear encoder, a charging detection component and a terminal processor; the base frame is provided with a bearing plate which is transversely arranged; the transverse moving mechanism comprises a first rail and a transverse moving seat arranged on the first rail, and a code scanner is arranged on the transverse moving seat; the linear encoder comprises an encoding ruler and a reading head, the encoding ruler is parallel to the first track, and the reading head is arranged on the transverse moving seat; the charging detection assembly comprises a plurality of charging detection units, and each charging detection unit comprises a positive chuck, a negative chuck, a charging detection circuit and an accommodating area; all the accommodating areas are sequentially arranged on the bearing plate from left to right, and the code scanner faces the accommodating areas; and the code scanner, the linear encoder and all the charging detection circuits are electrically connected with the terminal processor. The battery charging and detecting work of batched batteries can be completed in the battery charging and detecting cabinet, the process of taking the batteries down and then taking the batteries to other detecting equipment is saved, and the efficiency is high.

Description

Battery charging detection cabinet

Technical Field

The utility model relates to a battery manufacturing technical field, in particular to battery charging detection cabinet.

Background

In the production process of the battery, the battery needs to be charged, and parameters such as internal resistance, open-circuit voltage and the like of the battery need to be detected. The existing process is to place the battery on a charging cabinet for charging, then take the battery down and take the battery down to detection equipment for parameter detection, and the overall efficiency of charging detection is low.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, the utility model provides a battery charging detection cabinet.

According to the embodiment of the utility model, the battery charging detection cabinet comprises a base frame, a transverse moving mechanism, a linear encoder, a charging detection assembly and a terminal processor; the base frame is provided with a bearing plate which is transversely arranged; the transverse moving mechanism comprises a first rail and a transverse moving seat arranged on the first rail, the first rail extends transversely, and a code scanner is arranged on the transverse moving seat; the linear encoder comprises an encoding ruler and a reading head, the encoding ruler is parallel to the first track, and the reading head is arranged on the transverse moving seat; the charging detection assembly comprises a plurality of charging detection units, each charging detection unit comprises a positive chuck, a negative chuck, a charging detection circuit and a containing area, the positive chucks and the negative chucks are electrically connected with the charging detection circuit, and the positive chucks and the negative chucks are arranged beside the containing areas; the accommodating areas of all the charging detection units are sequentially arranged on the bearing plate from left to right, and the code scanners face the accommodating areas; the code scanner, the linear encoder and all the charging detection circuits are electrically connected with the terminal processor.

According to the utility model discloses battery charging detection cabinet has following technological effect at least: when the battery charging detection circuit is used, identification codes which can be identified by a code scanner are arranged on batteries in advance, for example, when the code scanner is a two-dimensional code scanner, the batteries are sprayed or pasted with the two-dimensional codes, each battery is provided with different identification codes for numbering, a plurality of batteries are respectively placed in a plurality of accommodating areas, the positive pole and the negative pole of each battery are respectively clamped in a positive pole chuck and a negative pole chuck, and the charging detection circuit can charge the batteries, detect parameters and then transmit detected data to a terminal processor; the code scanner can scan the identification code on the battery in sequence by arranging the transverse moving mechanism, and due to the arrangement of the encoder, when the code scanner scans the identification code on the battery, the position information of the code scanner can be transmitted to the terminal processor, and the position information corresponds to the charging detection circuits connected with the battery, so that the data detected by each charging detection circuit can be accurately matched with the corresponding battery; the serial number and the detected data of the battery at each position can be obtained at the terminal processor, the charging and detecting work of the batteries in batches can be completed in one battery charging detection cabinet, the process of taking the batteries down and then taking the batteries to other detection equipment is saved, and the efficiency is high.

According to some embodiments of the utility model, the loading board the sideslip mechanism the bar code scanner linear encoder with the detection subassembly that charges closes and is called detection device, be equipped with a plurality of detection device on the bed frame, all detection device sets gradually from last to down. Through setting up a plurality of detection device, make full use of space, the battery charge detects the cabinet and can once charge more batteries and detect.

According to some embodiments of the present invention, the accommodating area is disposed on an upper surface of the bearing plate; for two adjacent detection devices, the detection device positioned on the upper side is called an upper device, the detection device positioned on the lower side is called a lower device, and a first track of the lower device is arranged at the bottom of a bearing plate of the upper device; the detection device is characterized in that a cross beam is arranged on the base frame and is arranged above all the detection devices, the detection devices positioned at the top in all the detection devices are called top devices, and first tracks of the top devices are arranged on the cross beam. By arranging the first rail at the bottom of the loading plate of the upper device, the first rail, the traversing seat and the code scanner are all connected to the bottom of the loading plate of the upper device, the battery can move on the upper surface of the loading plate of the lower device, and the first rail, the traversing seat and the code scanner cannot obstruct the movement of the battery, so that the battery can be conveniently placed into or taken out of the accommodating area.

According to some embodiments of the present invention, the coding scale of the lower device is located at the bottom of the loading plate of the upper device, and the coding scale of the top device is located on the beam. Through setting up the coding ruler in the bottom of loading board, the movement of battery also can not hindered to the coding ruler, is convenient for the battery to put into the accommodation region, or takes out from the accommodation region.

According to some embodiments of the present invention, the base frame has a left support plate and a right support plate, and the bearing plate is disposed between the left support plate and the right support plate, with the left support plate being located at a left side relative to the right support plate; the transverse moving mechanism further comprises a rotary driver and a ball screw, the ball screw comprises a screw rod and a ball nut, the ball nut is connected with the transverse moving seat, the screw rod is arranged beside the first rail, the rotary driver is arranged on the right side of the right supporting plate, the right supporting plate is provided with a first through hole, and a driving shaft of the rotary driver is in linkage connection with the screw rod through the first through hole. The rotary driver is arranged in the outer area of the battery charging cabinet, the space inside the battery charging cabinet is saved, and the screw rod and the ball nut are simple in structure and small in vertical size, so that the transverse moving seat can be closer to the bottom of the bearing plate, and a large space is reserved for the battery to be put in or taken out.

According to some embodiments of the invention, the rotary drive is an electric motor. The motor has simple structure and is convenient to arrange.

According to some embodiments of the invention, the terminal processor is located on the left side of the left support plate. Therefore, the operation personnel can control and collect information on the left side of the battery charging cabinet, the rotary driver is arranged on the right side of the battery charging cabinet, the structure is reasonable, and the rotary driver cannot hinder the operation of the operation personnel.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic perspective view of a battery charging detection cabinet according to an embodiment of the present invention;

fig. 2 is the utility model discloses battery charging detects local cross-sectional view of left side of cabinet.

In the drawings:

100-a base frame; 110-left support plate; 120-right support plate; 130-a cross beam; 200-a terminal processor; 310-an upper carrier plate; 320-lower carrier plate; 331-positive electrode clamp; 332-negative grip; 410-a rotary drive; 420-a linear guide rail; 421-a slide block; 430-a screw rod; 431-ball nut; 440-a coding ruler; 441-a reading head; 450-a traversing seat; 460-a code scanner; 500-cell.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it should be understood that the orientation or positional relationship indicated with respect to the orientation description, such as up, down, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. The terms "a" or "an" mean one or more, the terms "a" or "an" mean two or more, the terms larger than, smaller than, exceeding, and the like are understood to include the number, and the terms "larger than, smaller than, within, and the like are understood to include the number. If there is a description of first and second for the purpose of distinguishing technical features only, this is not to be understood as indicating or implying a relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of technical features indicated.

In the description of the present invention, unless there is an explicit limitation, the words such as setting, installation, connection, etc. should be understood in a broad sense, and those skilled in the art can reasonably determine the specific meanings of the above words in combination with the specific contents of the technical solution.

The following describes a battery charging detection cabinet according to an embodiment of the present invention with reference to fig. 1 and 2.

The battery charging detection cabinet according to the embodiment of the utility model comprises a base frame 100, a transverse moving mechanism, a linear encoder, a charging detection assembly and a terminal processor 200; a bearing plate is transversely arranged on the base frame 100; the transverse moving mechanism comprises a first rail and a transverse moving seat 450 arranged on the first rail, the first rail extends transversely, and a code scanner 460 is arranged on the transverse moving seat 450; the linear encoder comprises an encoding scale 440 and a reading head 441, the encoding scale 440 is parallel to the first track, and the reading head 441 is arranged on the transverse moving seat 450; the charging detection assembly comprises a plurality of charging detection units, each charging detection unit comprises a positive electrode clamping head 331, a negative electrode clamping head 332, a charging detection circuit and an accommodating area, the positive electrode clamping heads 331 and the negative electrode clamping heads 332 are electrically connected with the charging detection circuit, and the positive electrode clamping heads 331 and the negative electrode clamping heads 332 are arranged beside the accommodating areas; the accommodating areas of all the charging detection units are sequentially arranged on the bearing plate from left to right, and the code scanner faces the accommodating areas; the bar code scanner 460, the linear encoder and all the charge detection circuits are electrically connected to the terminal processor 200.

For example, as shown in fig. 1, the base frame 100 includes a left support plate 110 and a right support plate 120 which are vertically disposed, the bearing plate is fixedly disposed between the left support plate 110 and the right support plate 120, the first rail may be disposed on the bearing plate, or on the base frame 100, or may be fixed beside the bearing plate by using an external support frame; the code scanner 460 is arranged above the bearing plate, and a scanning probe of the code scanner 460 faces downwards; the coding ruler 440 can be arranged on the bearing plate, also can be arranged on the base frame 100, and also can be fixed beside the bearing plate by using an external support frame; the positive electrode clamp 331 and the negative electrode clamp 332 are arranged at the rear part of the upper side surface of the bearing plate side by side, and the accommodating area is arranged at the front part of the upper side surface of the bearing plate; the bar code scanner 460 may be a bar code scanner 460 or a two-dimensional code scanner 460, and the bar code scanner 460 or the two-dimensional code scanner 460 can be purchased and obtained directly from the market, and the structure thereof is not described herein; the charge detection circuit is well known to those skilled in the battery field, such as the charge detection circuit disclosed in patent No. cn202020140278.x, and the charge detection circuit has not been applied to the charging cabinet in the prior art because the charge detection circuit only targets at one battery, and when charging the battery, a batch of batteries are usually put into the charging cabinet at the same time for charging.

When the battery charger is used, an identification code which can be identified by the code scanner 460 is arranged on the battery 500 in advance, for example, when the code scanner 460 is a two-dimensional code scanner 460, the battery is printed or pasted with the two-dimensional code, each battery is provided with different identification codes for numbering, a plurality of batteries are respectively placed in a plurality of accommodating areas, the positive electrode and the negative electrode of each battery are respectively clamped in the positive electrode clamping head 331 and the negative electrode clamping head 332, and the charging detection circuit can charge the batteries, detect parameters and transmit detected data to the terminal processor 200; by arranging the traversing mechanism, the code scanner 460 can scan the identification codes on the batteries in sequence, and due to the arrangement of the encoder, when the code scanner 460 scans the identification codes on the batteries, the position information can be transmitted to the terminal processor 200, and the position information corresponds to the charging detection circuits connected with the batteries, so that the data detected by each charging detection circuit can be accurately matched with the corresponding batteries; the terminal processor 200 can obtain the serial number and the detected data of the battery at each position, and can complete the charging and detecting work of the batteries in batches in a battery charging detection cabinet, so that the process of taking the batteries down and then taking the batteries to other detection equipment is saved, and the efficiency is high.

The utility model discloses an in some embodiments, loading board, sideslip mechanism, bar code scanner 460, linear encoder and the detection component that charges close and are called detection device, are equipped with a plurality of detection devices on the bed frame 100, and all detection devices set gradually under to from last. All the bearing plates are arranged in sequence along the height direction of the base frame 100 and are parallel to each other; through setting up a plurality of detection device, make full use of space, the battery charge detects the cabinet and can once charge more batteries and detect.

In some embodiments of the present invention, the accommodating area is disposed on the upper surface of the bearing plate; for two adjacent detection devices, the detection device positioned on the upper side is called an upper device, the detection device positioned on the lower side is called a lower device, and a first track of the lower device is arranged at the bottom of a bearing plate of the upper device; the base frame 100 is provided with a cross beam 130, the cross beam 130 is disposed above all the detection devices, the detection device located at the top of all the detection devices is called a top device, and a first rail of the top device is disposed on the cross beam 130. Referring to fig. 2, the first rail may be a linear guide 420, the traverse seat 450 is disposed at the bottom of the first rail, and a slider 421 is disposed between the traverse seat 450 and the first rail, so that the traverse seat 450 can slide left and right on the first rail, and in order to stabilize the movement of the traverse seat 450, two linear guides 420 may be disposed in parallel, and a slider 421 is disposed on each of the two linear guides 420 and connected to the traverse seat 450; the traverse seat 450 may be a transversely arranged plate-shaped member, and the bar code scanner 460 may be fixedly installed at the bottom of the traverse seat 450 by means of bolting, clamping, bonding or other suitable means; the upper loading plate is referred to as an upper loading plate 310, the lower loading plate is referred to as a lower loading plate 320, the battery can be moved on the upper surface of the lower loading plate 320 by arranging the first rail at the bottom of the upper loading plate 310, the first rail, the traverse seat 450 and the code scanner 460 are all connected to the bottom of the upper loading plate 310, and the first rail, the traverse seat 450 and the code scanner 460 do not obstruct the movement of the battery, thereby facilitating the battery to be placed in or taken out of the receiving area.

In some embodiments of the present invention, the coding rule 440 of the lower device is disposed at the bottom of the loading board of the upper device, and the coding rule 440 of the top device is disposed on the beam 130. The first track may extend from the left support plate 110 to the right support plate 120, and the encoding ruler 440 also extends from the left support plate 110 to the right support plate 120; by arranging the coding ruler 440 at the bottom of the bearing plate, the coding ruler 440 does not obstruct the movement of the battery, so that the battery can be conveniently placed into or taken out of the accommodating area.

In some embodiments of the present invention, the base frame 100 has a left support plate 110 and a right support plate 120, and the bearing plate is disposed between the left support plate 110 and the right support plate 120, with the orientation of the left support plate 110 relative to the right support plate 120 as the left direction; the traversing mechanism further comprises a rotary driver 410 and a ball screw, the ball screw comprises a screw 430 and a ball nut 431, the ball nut 431 is connected with the traversing seat 450, the screw 430 is arranged at the side of the first track, the rotary driver 410 is arranged at the right side of the right support plate 120, the right support plate 120 is provided with a first through hole, and a driving shaft of the rotary driver 410 is connected with the screw 430 in a linkage manner through the first through hole. The screw 430 coaxially rotates with a driving shaft of the rotary driver 410, the screw 430 is connected with the driving shaft of the rotary driver 410 through a coupling, the ball nut 431 is fixedly arranged on the traverse seat 450, the ball nut 431 can be arranged between the two sliding blocks 421, and the rotary driver 410 can drive the screw 430 to rotate, so that the ball nut 431 and the traverse seat 450 transversely move; the rotary driver 410 is arranged at the outer area of the battery charging cabinet, the space at the inner side of the battery charging cabinet is saved, and the screw rod 430 and the ball nut 431 are simple in structure and small in vertical size, so that the transverse moving seat 450 can be relatively close to the bottom of the bearing plate, and a large space is reserved for placing or taking out the battery.

In some embodiments of the present invention, the rotary drive 410 is an electric motor. The motor has simple structure and is convenient to arrange; the rotary driver 410 may be a stepping motor electrically connected to the terminal processor 200, and the terminal processor 200 controls the start and stop of the stepping motor to control the movement of the barcode scanner 460.

In some embodiments of the present invention, the terminal processor 200 is disposed on the left side of the left support plate 110. The terminal processor 200 may be installed on the left support plate 110, such that an operator may perform manipulation and information collection on the left side of the battery charging cabinet, and the rotary driver 410 is installed on the right side of the battery charging cabinet, which is reasonable in structure, and the rotary driver 410 does not hinder the operator's work.

The above description is for the purpose of illustrating the preferred embodiments of the present invention, but the present invention is not limited to the illustrated embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention, and such equivalent modifications or substitutions are included in the scope of the present invention defined by the appended claims.

Claims (7)

1. A battery charging detection cabinet, comprising:

the bearing plate is transversely arranged on the base frame;

the transverse moving mechanism comprises a first rail and a transverse moving seat arranged on the first rail, the first rail extends transversely, and a code scanner is arranged on the transverse moving seat;

the linear encoder comprises an encoding ruler and a reading head, the encoding ruler is parallel to the first track, and the reading head is arranged on the transverse moving seat;

the charging detection assembly comprises a plurality of charging detection units, each charging detection unit comprises a positive chuck, a negative chuck, a charging detection circuit and a containing area, the positive chucks and the negative chucks are electrically connected with the charging detection circuit, and the positive chucks and the negative chucks are arranged beside the containing areas; the accommodating areas of all the charging detection units are sequentially arranged on the bearing plate from left to right, and the code scanners face the accommodating areas;

and the code scanner, the linear encoder and all the charging detection circuits are electrically connected with the terminal processor.

2. The battery charging detection cabinet of claim 1, wherein: the loading board, the sideslip mechanism, the bar code scanner, linear encoder and the detection subassembly that charges jointly are called detection device, be equipped with a plurality of detection device on the bed frame, all detection device sets gradually from last to bottom.

3. The battery charging detection cabinet of claim 2, wherein: the accommodating area is arranged on the upper surface of the bearing plate; for two adjacent detection devices, the detection device positioned on the upper side is called an upper device, the detection device positioned on the lower side is called a lower device, and a first track of the lower device is arranged at the bottom of a bearing plate of the upper device; the detection device is characterized in that a cross beam is arranged on the base frame and is arranged above all the detection devices, the detection devices positioned at the top in all the detection devices are called top devices, and first tracks of the top devices are arranged on the cross beam.

4. The battery charging detection cabinet of claim 3, wherein: the coding ruler of the lower device is arranged at the bottom of the bearing plate of the upper device, and the coding ruler of the top device is arranged on the cross beam.

5. The battery charging detection cabinet of claim 3, wherein: the base frame is provided with a left supporting plate and a right supporting plate, the position of the left supporting plate relative to the right supporting plate is taken as the left side, and the bearing plate is arranged between the left supporting plate and the right supporting plate; the transverse moving mechanism further comprises a rotary driver and a ball screw, the ball screw comprises a screw rod and a ball nut, the ball nut is connected with the transverse moving seat, the screw rod is arranged beside the first rail, the rotary driver is arranged on the right side of the right supporting plate, the right supporting plate is provided with a first through hole, and a driving shaft of the rotary driver is in linkage connection with the screw rod through the first through hole.

6. The battery charging detection cabinet of claim 5, wherein: the rotary drive is an electric motor.

7. The battery charging detection cabinet of claim 5, wherein: the terminal processor is arranged on the left side of the left supporting plate.

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