CN215945757U - Spot welding test wire body and corresponding spot welding test all-in-one machine - Google Patents

Abstract

The utility model provides a spot welding test line body and a corresponding spot welding test integrated machine, wherein the spot welding test line body comprises: an equipment rack and a conveying device. The conveying device is positioned above the equipment rack and comprises a conveying part and a discharging part; the conveying part includes: the device comprises a structural shell, a conveying base, a conveying mould and a circulating mechanism; the conveying base seat is connected with the structural shell, the conveying base comprises a first conveying base and a second conveying base, the first conveying base is located above the second conveying base, the conveying die is located on the conveying base and is in sliding connection with the conveying base, the circulating mechanism comprises a first circulating mechanism and a second circulating mechanism, the first circulating mechanism is located on one side of the first conveying base, and the second circulating mechanism is located on the other side of the second conveying base. The spot welding test wire body is through setting up conveyor to carry out assembly line operation, change batch material loading into by traditional single material loading, single processing is changed into batch processing, has improved processing production efficiency.

Description

Spot welding test wire body and corresponding spot welding test all-in-one machine

Technical Field

The utility model relates to the field of rotor machining, in particular to a spot welding test line body and a corresponding spot welding test integrated machine.

Background

With the gradual development of industrial construction, manual spot welding is gradually replaced by mechanical spot welding, and the mechanical spot welding has the advantages of accuracy and high efficiency compared with the manual spot welding.

At present, mechanical spot welding can only carry out spot welding processing on a single rotor, only one rotor can be fed once, the rotor is fed after spot welding is finished, the next rotor can be fed after feeding is finished, the mechanical spot welding is long in rotor scheduling time, and large-scale batch production is difficult to meet.

Therefore, it is necessary to provide a spot welding test wire body and a corresponding spot welding test all-in-one machine to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a spot welding test line body and a corresponding spot welding test all-in-one machine, wherein the spot welding test line body is provided with a conveying device to carry out assembly line operation, so that the problems that the spot welding test line body and the corresponding spot welding test all-in-one machine in the prior art are mostly unreasonable in structural design, long in scheduling time and difficult to meet large-scale batch production are solved.

In order to solve the technical problems, the technical scheme of the utility model is as follows: a spot welding test line body is used for conveying a rotor to each processing station of the rotor; the spot welding test wire body includes:

an equipment rack, and

a conveying device located above the equipment rack, the conveying device including a conveying portion for conveying a rotor;

wherein the conveying part includes: the device comprises a structural shell, a conveying base, a conveying mould and a circulating mechanism; the conveying base is connected with the structural shell and comprises a first conveying base and a second conveying base, the first conveying base is positioned above the second conveying base, and the conveying mould is positioned on the conveying base and is in sliding connection with the conveying base; the circulating mechanism comprises a first circulating mechanism and a second circulating mechanism, the first circulating mechanism is located on one side of the first conveying base, and the second circulating mechanism is located on the other side of the second conveying base.

In the utility model, the structural shell comprises a top plate, a bottom plate, a first side plate, a second side plate, a first end plate and a second end plate, wherein the first side plate, the second side plate, the first end plate and the second end plate are all positioned above the bottom plate and connected with the bottom plate, the first end plate is positioned at one end of the first side plate and positioned at the other end of the second side plate, the second end plate is positioned at one end of the first side plate and positioned at one end of the second side plate, and the top plate, the bottom plate, the first side plate, the second side plate, the first end plate and the second end plate are detachably connected.

In the present invention, the first circulation mechanism includes: the first supporting block is located on one side of the conveying base and connected with the first side plate to push the first conveying base towards the second circulating mechanism to move, the first supporting block is located between the first driving block and the first conveying base and used for lifting the conveying mould to move upwards, and the first lifting assembly is located below the first supporting block and connected with the first supporting block and used for driving the first supporting block to move upwards and downwards.

In the utility model, a guide slide rail is arranged on one side of the first end plate close to the conveying part, the first support block comprises a bearing block and a guide block, the guide block is positioned below the bearing block, and the guide block is connected with the guide slide rail in a sliding manner.

In the present invention, the second circulation mechanism includes: the second supporting block, the second lifting assembly and the second driving block are located on the other side of the conveying base and connected with the second side plate to push the second conveying base to move towards the first circulating mechanism, the second supporting block is located between the second driving block and the second conveying base and used for lifting the conveying die to move downwards, and the second lifting assembly is located below the second supporting block and connected with the second supporting block and used for driving the second supporting block to move upwards and downwards.

In the utility model, the conveying mould is provided with a conveying groove and a mounting groove, the conveying groove is positioned on the top surface of the conveying mould and is used for placing a rotor, the mounting groove is positioned on the bottom surface of the conveying mould, and the first support block is provided with a mounting column matched with the mounting groove.

In the utility model, the spot welding test line body further comprises a sliding block and a longitudinal driver, the sliding block is positioned below the conveying device, a sliding rail is arranged on the equipment rack and is perpendicular to the conveying direction of the rotor, the conveying device is connected with the equipment rack in a sliding mode through the sliding block, and the longitudinal driver is connected with the conveying device and is used for driving the conveying device to move on the equipment rack relatively.

In the present invention, the conveying device further includes a discharging portion, the discharging portion is located on one side of the conveying portion, and is configured to perform a discharging operation on the rotor, and the discharging portion includes: a blanking track and a blanking manipulator; the blanking track is connected with one side of the conveying device, the blanking track is arranged obliquely downwards, and the height of one end, close to the conveying part, of the blanking track is higher than that of one end, far away from the conveying part, of the blanking track; the blanking manipulator is positioned on one side of the blanking track and used for blanking the rotor positioned on the conveying part to the blanking part.

In the present invention, the blanking rail includes: sleeper, first guide rail and second guide rail, the sleeper with one side of conveying part is connected, first guide rail is located top one side of sleeper, the second guide rail is located the top opposite side of sleeper, be equipped with the connecting hole on the sleeper all be equipped with the mounting hole on first guide rail and the second guide rail, first guide rail and the second guide rail with the sleeper passes through the connecting hole with mounting hole bolted connection.

The utility model also provides a spot welding test all-in-one machine which comprises any one of the spot welding test wire bodies.

Compared with the prior art, the utility model has the beneficial effects that: according to the spot welding test line body and the corresponding spot welding test all-in-one machine, the spot welding test line body is provided with the conveying device to perform assembly line operation, so that the processing production efficiency is improved, and the problems that the spot welding test line body and the corresponding spot welding test all-in-one machine in the prior art are not reasonable in structural design, long in scheduling time and difficult to meet large-scale batch production are solved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required in the embodiments are briefly introduced below, and the drawings in the following description are only corresponding to some embodiments of the present invention.

Fig. 1 is a schematic structural diagram of a preferred embodiment of the spot welding and testing all-in-one machine of the utility model.

Fig. 2 is an enlarged view of a portion a of fig. 1.

Fig. 3 is a schematic structural diagram of a spot welding test wire body according to the present invention.

Fig. 4 is a schematic structural view of the first support block and the conveying mold in the present invention.

Fig. 5 is a schematic structural view of the blanking rail in the present invention.

Reference numerals: the device comprises an equipment rack 1, a slide rail 11, a conveying device 2, a conveying part 21, a structural housing 211, a top plate 2111, a first end plate 2112, a guide slide rail 2112a, a first conveying base 2121, a second conveying base 2122, a conveying mold 213, a conveying groove 2131, a mounting groove 2132, a first circulating mechanism 2141, a first support block 2141a, a bearing block 2141aa, a guide block 2141ab, a mounting column 2141ac, a first lifting assembly 2141b, a first driving block 2141c, a blanking part 22, a blanking track 221, a sleeper 2211, a first guide rail 2212, a second guide rail 2213, a blanking manipulator 222, a slide block 3 and a longitudinal driver 4.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the drawings, elements having similar structures are denoted by the same reference numerals.

The terms "first," "second," and the like in the terms of the utility model are used for descriptive purposes only and not for purposes of indication or implication relative importance, nor as a limitation on the order of precedence.

The following is a preferred embodiment of a spot welding test wire body and a corresponding spot welding test all-in-one machine, which can solve the above technical problems.

The utility model provides a spot welding test wire body and a corresponding spot welding test all-in-one machine, wherein the preferred embodiment of the spot welding test wire body is as follows: a spot welding test line body is used for conveying a rotor to each processing station of the rotor; the spot welding test wire body includes: an equipment rack and a conveying device. The conveying device is positioned above the equipment rack and comprises a conveying part.

Wherein, the conveying part includes: the device comprises a structural shell, a conveying base, a conveying mould and a circulating mechanism; the conveying base seat is connected with the structural shell, the conveying base comprises a first conveying base and a second conveying base, the first conveying base is located above the second conveying base, the conveying die is located on the conveying base and is in sliding connection with the conveying base, the circulating mechanism comprises a first circulating mechanism and a second circulating mechanism, the first circulating mechanism is located on one side of the first conveying base, and the second circulating mechanism is located on the other side of the second conveying base.

According to the spot welding test line body and the corresponding spot welding test all-in-one machine, the spot welding test line body is provided with the conveying device to perform assembly line operation, the traditional single feeding is changed into batch feeding, and the single processing is changed into batch processing, so that the processing production efficiency is improved, and the problems that the spot welding test line body and the corresponding spot welding test all-in-one machine in the prior art are not reasonable in structural design, long in scheduling time and difficult to meet large-scale batch production are solved.

Referring to fig. 1 and 2, fig. 2 is an enlarged view of a portion a of a bitmap 1, and the overall structure of the spot welding test wire body of the present invention is described in detail as follows:

structural shell 211 includes roof 2111, the bottom plate, first curb plate, the second curb plate, first endplate 2112 and second endplate all are located the bottom plate top, be connected with the bottom plate, first endplate 2112 is located the one end of first curb plate, and is located the other end of second endplate, the second endplate is located the one end of first curb plate, and is located the one end of second endplate, roof 2111, the bottom plate, first curb plate, the second curb plate, first endplate 2112 and second endplate can dismantle the connection. Each block plate of the housing is detachably connected, so that the conveying mold 213 of different models can be replaced aiming at the rotors of different models, and the applicability of the product is improved.

The spot welding test wire body still includes slider 3, and slider 3 is located conveyor 2's below, is equipped with slide rail 11 on the equipment frame 1, and the direction of delivery of slide rail 11 perpendicular to rotor sets up, and conveyor 2 passes through slider 3 and 1 sliding connection of equipment frame. Because spot welding test all-in-one still includes multiple detection mechanism and data processing mechanism, the spot welding test wire body can slide on equipment rack 1, is favorable to adjusting the space, regularly overhauls detection mechanism and data processing mechanism, ensures the stability of equipment.

In addition, the spot welding test wire body further comprises a longitudinal driver 4, and the longitudinal driver 4 is connected with the conveying device 2 and used for driving the conveying device 2 to move relatively on the equipment rack 1. Use vertical driver 4 to replace artifical push-and-pull to change the position of spot welding test wire body on equipment rack 1 for it is more accurate to remove at every turn, avoids the artifical too big equipment damage that causes of exerting oneself simultaneously.

Referring to fig. 3, the spot welding test wire body of the present invention is described in detail as follows:

the first circulation mechanism 2141 includes: the first supporting block 2141a, the first lifting assembly 2141b, and the first driving block 2141c, the first driving block 2141c is located at one side of the first conveying base 2121, and is connected to the first side plate, for pushing the first conveying base 2121 to move toward the second circulating mechanism, the first supporting block 2141a is located between the first driving block 2141c and the first conveying base 2121, for lifting the conveying mold 213, and the first lifting assembly 2141b is located below the first supporting block 2141a, and is connected to the first supporting block 2141a, for driving the first supporting block 2141a to move up and down.

Meanwhile, the second circulation mechanism includes: the second supporting block is located on the other side of the second conveying base 2122, connected to the second side plate, and used for pushing the second conveying base 2122 to move towards the first circulating mechanism 2141, the second supporting block is located between the second driving block and the second conveying base 2122 and used for supporting and lifting the conveying mold 213, and the second lifting assembly is located below the second supporting block and connected to the second supporting block and used for driving the second supporting block to move up and down.

The first tray 2141a includes, on its motion trajectory: a first station and a second station. The first support block 2141a includes, on its motion trajectory: a third station and a fourth station. The first driving block 2141c pushes the first conveying mold 213 to move to the right, one conveying mold 213 at the rightmost end is pushed to the second supporting block at the third station, and the second supporting block is driven by the second lifting assembly to move downwards to the fourth station. The second driving block pushes the second conveying mold 213 to move left, the conveying mold 213 at the leftmost end is pushed to the first supporting block 2141a at the second station, and the first supporting block 2141a is driven by the first lifting assembly 2141b to move upward to the first station. So just realized the cycle work of spot welding test wire body for it is more high-efficient to carry the rotor.

In addition, a guide rail 2112a11 is disposed on one side of the first side plate close to the conveying portion 21, the first supporting block 2141a includes a bearing block 2141aa and a guide block 2141ab, the guide block 2141ab is located below the bearing block 2141aa, and the guide block 2141ab is slidably connected to the guide rail 2112a 11. The guide block 2141ab is arranged to guide the up-and-down movement of the first support block 2141a, so that the first support block 2141a works more stably, and it can be understood that the second support block has the same structure.

Referring to fig. 4, the first supporting block 2141a and the conveying mold 213 of the present invention are described in detail as follows:

the conveying mold 213 is provided with a conveying groove 2131 and a mounting groove 2132, the conveying groove 2131 is located on the top surface of the conveying mold 213 and used for placing a rotor, the mounting groove 2132 is located on the bottom surface of the conveying mold 213, and the first supporting block 2141a is provided with a mounting column 2141ac matched with the mounting groove 2132. In order to enable the first supporting block 2141a to stably transport the conveying mold 213, the conveying mold 213 is provided with two mounting grooves 2132, the two mounting grooves 2132 are respectively located at two sides of the bottom surface of the conveying mold 213, and the first supporting block 2141a is also provided with two mounting posts 2141ac, which respectively correspond to the two mounting grooves 2132 of the conveying mold 213. It is understood that the second tray has the same structure as the first tray 2141 a.

Referring to fig. 5, the blanking guide rail of the present invention is explained in detail as follows:

in this scheme, unloading portion 22 is located one side of conveying portion 21 for carry out the unloading operation to the rotor, and unloading portion 22 includes: a feeding rail 221 and a feeding manipulator 222; the blanking track 221 is arranged obliquely downwards, and the height of one end of the blanking track 221 close to the conveying part 21 is higher than that of one end far away from the conveying part 21; the feeding robot 222 is located on one side of the feeding rail 221, and feeds the rotor located in the conveying unit 21 to the feeding unit 22. The rotor includes: the rotary body and the bearing are arranged in the rotary body in a penetrating mode and extend out of the rotary body, the discharging manipulator 222 is used for directly discharging the rotor to the discharging rail 221, the moving distance of the manipulator is reduced, and discharging efficiency is improved.

Wherein, unloading track 221 includes: sleeper 2211, first guide rail 2212 and second guide rail 2213, sleeper 2211 is connected with one side of conveyor 21, first guide rail 2212 is located sleeper 2211's top one side, second guide rail 2213 is located sleeper 2211's top opposite side, be equipped with the connecting hole on sleeper 2211 and all be equipped with the mounting hole on first guide rail 2212 and the second guide rail 2213, first guide rail 2212 and second guide rail 2213 pass through connecting hole and mounting hole bolted connection with sleeper 2211. When rotors with different specifications are encountered, the positions of the first guide rail 2212 and the second guide rail 2213 on the sleeper 2211 can be changed, so that the width between the first guide rail 2212 and the second guide rail 2213 is changed, and the applicability of the blanking track 221 is improved.

The working principle of the utility model is as follows: the rotor is loaded to the conveyor device, the conveyor device 2 drives the rotor to move forward to each processing station, wherein the conveyor device 2 can circularly convey the rotor, and the motion track of the first support block 2141a comprises: a first station and a second station. The first support block 2141a includes, on its motion trajectory: a third station and a fourth station. The first driving block 2141c pushes the first conveying mold 213 to move to the right, one conveying mold 213 at the rightmost end is pushed to the second supporting block at the third station, and the second supporting block is driven by the second lifting assembly to move downwards to the fourth station. The second driving block pushes the second conveying mold 213 to move left, the conveying mold 213 at the leftmost end is pushed to the first supporting block 2141a at the second station, and the first supporting block 2141a is driven by the first lifting assembly 2141b to move upward to the first station. After the rotor passes through the conveying unit 21 and reaches the feeding unit 22, the feeding robot 222 feeds the rotor.

This completes the rotor conveying process of the present preferred embodiment.

In summary, although the present invention has been described with reference to the preferred embodiments, the above-described preferred embodiments are not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, therefore, the scope of the present invention shall be determined by the appended claims.

Claims (10)

1. A spot welding test line body is used for conveying a rotor to each processing station of the rotor; its characterized in that, the spot welding test wire body includes:

an equipment rack, and

a conveying device located above the equipment rack, the conveying device including a conveying portion for conveying a rotor;

wherein the conveying part includes: the device comprises a structural shell, a conveying base, a conveying mould and a circulating mechanism; the conveying base is connected with the structural shell and comprises a first conveying base and a second conveying base, the first conveying base is positioned above the second conveying base, and the conveying mould is positioned on the conveying base and is in sliding connection with the conveying base; the circulating mechanism comprises a first circulating mechanism and a second circulating mechanism, the first circulating mechanism is located on one side of the first conveying base, and the second circulating mechanism is located on the other side of the second conveying base.

2. The spot welding test wire body of claim 1, wherein the structural casing comprises a top plate, a bottom plate, a first side plate, a second side plate, a first end plate and a second end plate, the first side plate, the second side plate, the first end plate and the second end plate are all located above the bottom plate and connected with the bottom plate, the first end plate is located at one end of the first side plate and located at the other end of the second side plate, the second end plate is located at one end of the first side plate and located at one end of the second side plate, and the top plate, the bottom plate, the first side plate, the second side plate, the first end plate and the second end plate are detachably connected.

3. The spot welding test wire body of claim 2, wherein the first cycling mechanism comprises: the first supporting block is located on one side of the conveying base and connected with the first side plate to push the first conveying base towards the second circulating mechanism to move, the first supporting block is located between the first driving block and the first conveying base and used for lifting the conveying mould to move upwards, and the first lifting assembly is located below the first supporting block and connected with the first supporting block and used for driving the first supporting block to move upwards and downwards.

4. The spot welding test wire body according to claim 3, wherein a guide slide rail is disposed on a side of the first end plate close to the conveying portion, the first support block comprises a bearing block and a guide block, the guide block is located below the bearing block, and the guide block is slidably connected to the guide slide rail.

5. The spot welding test wire body of claim 2, wherein the second circulation mechanism comprises: the second supporting block, the second lifting assembly and the second driving block are located on the other side of the conveying base and connected with the second side plate to push the second conveying base to move towards the first circulating mechanism, the second supporting block is located between the second driving block and the second conveying base and used for lifting the conveying die to move downwards, and the second lifting assembly is located below the second supporting block and connected with the second supporting block and used for driving the second supporting block to move upwards and downwards.

6. The spot welding test wire body according to claim 3, wherein a conveying groove and a mounting groove are arranged on the conveying mold, the conveying groove is located on the top surface of the conveying mold and used for placing a rotor, the mounting groove is located on the bottom surface of the conveying mold, and the first support block is provided with a mounting column matched with the mounting groove.

7. The spot welding test wire body according to claim 1, further comprising a slider and a longitudinal driver, wherein the slider is located below the conveying device, a slide rail is arranged on the equipment rack, the slide rail is perpendicular to a conveying direction of the rotor, the conveying device is slidably connected with the equipment rack through the slider, and the longitudinal driver is connected with the conveying device and used for driving the conveying device to move relatively on the equipment rack.

8. The spot welding test wire body according to claim 1, wherein the conveying device further comprises a blanking portion located at one side of the conveying portion for performing a blanking operation on a rotor, the blanking portion comprising: a blanking track and a blanking manipulator; the blanking track is connected with one side of the conveying device, the blanking track is arranged obliquely downwards, and the height of one end, close to the conveying part, of the blanking track is higher than that of one end, far away from the conveying part, of the blanking track; the blanking manipulator is positioned on one side of the blanking track and used for blanking the rotor positioned on the conveying part to the blanking part.

9. The spot welding test wire body of claim 8, wherein the blanking track comprises: sleeper, first guide rail and second guide rail, the sleeper with one side of conveying part is connected, first guide rail is located top one side of sleeper, the second guide rail is located the top opposite side of sleeper, be equipped with the connecting hole on the sleeper all be equipped with the mounting hole on first guide rail and the second guide rail, first guide rail and the second guide rail with the sleeper passes through the connecting hole with mounting hole bolted connection.

10. An all-in-one machine for spot welding and testing, which is characterized by comprising the spot welding test wire body according to any one of claims 1-9.

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