CN214978466U - Energy conversion structure for generating bending vibration and welding equipment - Google Patents

Abstract

The utility model relates to an ultrasonic bonding's technical field discloses a produce flexural vibration's transduction structure and welding equipment. Wherein, this produce the transducing structure of bending vibration includes: a transducer that generates axial vibration; the variable-amplitude structure comprises a first variable-amplitude rod and a second variable-amplitude rod, one end of the first variable-amplitude rod is connected to the transducer, one end of the first variable-amplitude rod is coaxially arranged with the transducer, the bottom of the second variable-amplitude rod is used for being connected with the welding head, the top of the second variable-amplitude rod is used for being connected with welding equipment, the other end of the first variable-amplitude rod is connected between the top and the bottom of the second variable-amplitude rod, and the first variable-amplitude rod and the second variable-amplitude rod are vertically arranged. The utility model discloses the transduction structure and the welding equipment of production flexural vibration that technical scheme provided, the vibration mode that bonding tool department produced is flexural vibration, and the bonding tool is not fragile or fracture, and the welding effect is better.

Description

Energy conversion structure for generating bending vibration and welding equipment

Technical Field

The patent of the utility model relates to an ultrasonic bonding's technical field particularly, relates to a produce flexural vibration's transduction structure and welding equipment.

Background

Ultrasonic welding is the conversion of electrical current into electrical energy by means of an ultrasonic generator, the converted high-frequency electrical energy being converted again into mechanical motion of the same frequency by means of a transducer, the mechanical motion then being transmitted via a horn structure to a welding head which transmits the received vibration energy to the joint of the workpieces to be welded, which are moved relative to one another essentially parallel to their welding surfaces, and the surfaces of the two objects being rubbed against one another under pressure to form a fusion between the molecular layers.

In the prior art, when ultrasonic welding is used, generally, a horizontal plane between two workpieces is welded, a welding head is pressed on one workpiece, and the welding head horizontally vibrates to enable the surfaces of the two workpieces to be jointed to be fused and welded.

However, when ultrasonic welding is performed at present, equipment does not directly and vertically press the welding head in the process of pressing the welding head, but presses the side edge of the welding head, so that the welding head has an upward torsion in use, the welding head is easily damaged or broken in the long-time use process, and the welding effect is poor.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a produce flexural vibration's transduction structure, aim at solving prior art, the bonding tool damages easily or splits, and welds the poor problem of effect.

The utility model discloses a realize like this, a produce flexural vibration's transduction structure, include:

a transducer that generates axial vibration;

the variable-amplitude structure comprises a first variable-amplitude rod and a second variable-amplitude rod, one end of the first variable-amplitude rod is connected to the transducer, one end of the first variable-amplitude rod is coaxially arranged with the transducer, the bottom of the second variable-amplitude rod is used for being connected with the welding head, the top of the second variable-amplitude rod is used for being connected with welding equipment, the other end of the first variable-amplitude rod is connected between the top and the bottom of the second variable-amplitude rod, and the first variable-amplitude rod and the second variable-amplitude rod are vertically arranged.

Optionally, the first horn includes a first connecting section and a second connecting section, the first connecting section is connected to the second connecting section, the first connecting section is cylindrical, the first connecting section is connected to the transducer, the second connecting section is flat, and the second connecting section is connected to the second horn.

Optionally, the second connecting section has a transition section connected to the first connecting section, and the thickness of the transition section gradually decreases along a direction from the second connecting section to the first connecting section.

Optionally, the width of the second connecting section gradually decreases along the direction from the first connecting section to the second horn.

Optionally, the other end of the first horn is provided with a fixed through hole, and the second horn is fixedly arranged through the fixed through hole.

Optionally, a fixed block is further disposed at the top of the second horn.

Optionally, the fixing block is provided with a plurality of blind holes, and the fixing block is mounted on the welding device through the blind holes.

Optionally, the fixed block is rectangular, and the second amplitude transformer is perpendicular to the center of the bottom surface of the fixed block.

Optionally, the fixed block and the second horn are integrally formed.

The utility model also provides a welding equipment, including pressure device with produce bending vibration's transduction structure. Wherein the transduction structure generating bending vibration comprises:

a transducer that generates axial vibration;

the variable-amplitude structure comprises a first variable-amplitude rod and a second variable-amplitude rod, one end of the first variable-amplitude rod is connected to the transducer, one end of the first variable-amplitude rod is coaxially arranged with the transducer, the bottom of the second variable-amplitude rod is used for being connected with the welding head, the top of the second variable-amplitude rod is used for being connected with welding equipment, the other end of the first variable-amplitude rod is connected between the top and the bottom of the second variable-amplitude rod, and the first variable-amplitude rod and the second variable-amplitude rod are vertically arranged;

the top of the second amplitude transformer is fixed on the pressurizing device, and the pressure applied by the pressurizing device is coaxially arranged with the second amplitude transformer.

Compared with the prior art, the utility model provides a produce flexural vibration's transduction structure can make the bonding tool produce flexural vibration through this transduction structure, and then realizes the welding to, when the pressurization, directly pressurize at the top of second amplitude transformer, make the welding position of bonding tool be located the direction of the pressure of exerting, compare in current structure, the bonding tool is not fragile or fracture, therefore welding effect is better. Moreover, because the vibration mode generated at the welding head is bending vibration, when welding is carried out between workpieces with cambered surfaces, compared with the welding head with the horizontal vibration mode, the welding effect is better. The problem of among the prior art, the bonding tool damages easily or breaks, and welding effect is poor is solved.

Drawings

Fig. 1 is a schematic perspective view of a transduction structure for generating bending vibration according to the present invention;

fig. 2 is a schematic diagram of a vibration mode of the transduction structure for generating bending vibration according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The following describes the implementation of the present invention in detail with reference to specific embodiments.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present invention, it should be understood that if there are the terms "upper", "lower", "left", "right", etc. indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of the description, but it is not intended to indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore the terms describing the positional relationship in the drawings are only for illustrative purposes and are not to be construed as limitations of the present patent, and those skilled in the art can understand the specific meanings of the terms according to specific situations.

Referring to fig. 1 and 2, the preferred embodiment of the present invention is provided.

In the embodiment of the utility model provides an in, this produce flexural vibration's transduction structure, include:

a transducer 10, the transducer 10 generating axial vibrations;

the variable-amplitude structure comprises a first variable-amplitude rod 21 and a second variable-amplitude rod 22, one end of the first variable-amplitude rod 21 is connected to the transducer 10, one end of the first variable-amplitude rod 21 is coaxially arranged with the transducer 10, the bottom of the second variable-amplitude rod 22 is used for being connected with a welding head, the top of the second variable-amplitude rod 22 is used for being connected with welding equipment, the other end of the first variable-amplitude rod 21 is connected between the top and the bottom of the second variable-amplitude rod 22, and the first variable-amplitude rod 21 and the second variable-amplitude rod 22 are vertically arranged.

In the above structure, the transducer 10 is cylindrical, converts the high-frequency electric energy into the axial vibration with the same frequency, because the first amplitude transformer 21 is connected with the transducer 10 and is coaxially arranged, the first amplitude transformer 21 generates the axial vibration with the same frequency, the first amplitude transformer 21 then transmits the vibration to the second amplitude transformer 22 connected with the first amplitude transformer, because the welding equipment is connected to the top of the second amplitude transformer 22, the first amplitude transformer is immovable in the horizontal direction, and the second amplitude transformer 22 is located below the top and can swing through the vibration of the first amplitude transformer 21, namely, the bending vibration of the utility model is generated. Thus, the second horn 22 also produces bending vibrations at the bottom of the horn, as described in the present invention. During the process of welding the workpieces, the workpieces are rubbed by the bending vibration of the welding head and then welded together.

In this embodiment, the welding head can generate bending vibration through the transduction structure, so as to realize welding, and when the pressure is applied, the pressure is directly applied to the top of the second amplitude transformer 22, so that the welding position of the welding head is located in the direction of the applied pressure. Moreover, because the vibration mode generated at the welding head is bending vibration, when welding is carried out between workpieces with cambered surfaces, compared with the welding head with the horizontal vibration mode, the welding effect is better.

Referring to fig. 1 and 2, in an embodiment of the present invention, the first horn 21 includes a first connecting section 211 and a second connecting section 212, the first connecting section 211 and the second connecting section 212 are connected, the first connecting section 211 is cylindrical, the first connecting section 211 is connected to the transducer 10, the second connecting section 212 is flat, and the second connecting section 212 is connected to the second horn 22.

The first connecting section 211 is coaxially arranged with the transducer 10, and is fixedly connected with the transducer 10, and according to the actual situation, the first connecting section can be in threaded connection with the end of the transducer 10, that is, the other end of the transducer is inserted with a bolt to be in threaded connection with a threaded hole of the first connecting section, or is integrally arranged with the end of the transducer 10. The second connecting section 212 is flat, and the thickness of the flat is smaller than the width of the two sides in the length direction of the second horn 22, so that after the axial vibration transmitted from the first connecting section 211 is transmitted to the second connecting section 212, the second connecting section 212 can be changed into horizontal vibration in the length direction, and thus, as the second horn 22 is connected with the second connecting section 212, the joint of the second horn 22 and the second connecting section 212 can also generate horizontal vibration, so that the bottom of the second horn 22 generates bending vibration, and compared with a non-flat structure, a structure of the second horn 22 generates vibration.

And, the second connection section 212 has a transition section 213 which is connected with the first connection section 211, and the thickness of the transition section 213 is gradually reduced along the direction from the second connection section 212 to the first connection section 211.

The thickness is defined as the distance between the upper and lower surfaces of the transition section 213 along the length of the second horn 22. Thus, on the one hand, the structural strength of the first horn 21 is increased, and on the other hand, the energy loss of vibration during transmission is reduced, so that most of the energy of the mechanical vibration generated by the transducer 10 can be transmitted to the second horn 22, and the welding effect is better. Specifically, the upper and lower surfaces of the transition section 213 are of an inwardly concave arc-surface-shaped structure, the upper and lower surfaces of the transition section 213 are in smooth transition with the upper and lower surfaces of the second connection section 212, and the center of the second connection section 212 is located in the axial direction of the first connection section 211, so that the second connection section 212 can better realize horizontal vibration.

Likewise, the width of the second connecting section 212 gradually decreases in the direction from the first connecting section 211 to the second horn 22.

The width here is the distance between the two sides of the transition section 213 in the horizontal direction perpendicular to the first horn 21. On the one hand, the structural strength of the first horn 21 is increased and, on the other hand, the energy loss of the vibrations during the transmission is reduced. Specifically, two side surfaces of the transition section 213 are arc surface-shaped structures protruding outwards, and the two side surfaces are in smooth transition with two sides of the second connection section 212 and a side surface of the first connection section 211. By combining the structure, the loss in the energy transfer process is greatly reduced.

Referring to fig. 1 and 2, in an embodiment of the present invention, the other end of the first amplitude transformer 21 has a fixing hole, and the second amplitude transformer 22 is fixedly disposed through the fixing hole.

Through this fixed perforation, realize the connection of second amplitude transformer 22 and first amplitude transformer 21, in this embodiment, first amplitude transformer 21 and second amplitude transformer 22 fixed connection, preferably, first amplitude transformer 21 and second amplitude transformer 22 integrated into one piece set up for its vibration frequency is unanimous, and vibration transmission effect is better. In addition, in the present embodiment, the length of the second horn 22 may be set according to the structure of the welding head and the workpiece to be welded, or the first horn 21 may be set at a specific position of the second horn 22, so as to adjust the vibration mode of the bending vibration, thereby improving the welding effect.

In addition, the second horn 22 of the present embodiment has a cylindrical rod shape, so that the first horn 21 transmits vibration, and the structure is stable. In another embodiment, the second horn 22 may be a flat bar, and the first horn 21 is connected to a side of the second horn 22, so that the second horn 22 can generate more significant bending vibration.

Referring to fig. 1 and 2, in an embodiment of the present invention, a fixing block 23 is further disposed on a top of the second horn 22.

The fixed block 23 is used for being mounted on the welding equipment, so that the second amplitude transformer 22 below the fixed block can generate bending vibration, and the fixed block 23 is pressed by a pressing device of the welding equipment, so that the pressure coaxial with the axis of the welding head can be applied, and the welding effect is better.

Specifically, the fixed block 23 is rectangular, and the second horn 22 is perpendicular to the center of the bottom surface of the fixed block 23.

Thus, when pressure is applied to the mounting block 23, the pressure is along the axis of the second horn 22 to facilitate subsequent welding. Preferably, the fixed block 23 has a square shape, and when the entire fixed block 23 is pressurized, the pressure direction thereof is along the axial direction of the second horn 22.

And, the fixing block 23 has a plurality of blind holes 23a, and the fixing block 23 is mounted on the welding apparatus through the blind holes 23 a.

In this embodiment, each side surface of the fixing block 23 is provided with four blind holes 23a, the four blind holes 23a are respectively located at four corners of each side surface, the blind holes 23a of the opposite side surfaces are arranged oppositely, and the blind holes 23a of the adjacent side surfaces are arranged incorrectly, so that the fixing block 23 can be stably fixed on a pressurizing device of a welding device, and when the fixing block 23 is pressurized and applied with force, the pressure is located at the center of the fixing block 23.

Further, the fixing block 23 and the second horn 22 are integrally formed.

Therefore, on one hand, the integrity of the transduction structure is improved, the strength is higher, on the other hand, the vibration frequency of each position is consistent, the vibration transmission is facilitated, and the ultrasonic welding is realized.

Referring to fig. 1 and fig. 2, in an embodiment of the present invention, a welding head can be fixed at the bottom of the second amplitude transformer 22, and of course, in this embodiment, the bottom of the second amplitude transformer 22 has a connector through which different types of welding heads can be connected to meet different welding requirements, in this embodiment, the connector is a cylindrical body with threads.

In another embodiment, in order to achieve the adjustable amplitude of the bottom bending vibration of the second horn 22, the fixing block 23 has a plurality of different fixing positions, and in connection with the above embodiment, eight blind holes 23a may be formed on a side surface of one side of the fixing block 23, and four adjacent blind holes 23a are a fixing position, and thus there are three fixing positions, which are not limited to the number of fixing positions, and thus, by fixing different positions of the fixing block 23, the distance from the fixing position to the bottom of the second horn 22 is changed, and thus, when the transducer 10 vibrates the second horn 22, the amplitude of the bottom of the second horn 22 is also changed, so that the amplitude can be adjusted as required, and a better welding effect can be achieved according to different welding workpieces.

Referring to fig. 1 and 2 in combination, a welding apparatus is also provided that includes a pressure applying device and a transducing structure that produces bending vibrations. Wherein, the above embodiments of the present invention can be referred to for the transduction structure generating bending vibration, and the details are not repeated herein.

And, the top of the second horn 22 is fixed to a pressurizing means, and the pressurizing means applies a pressure coaxially arranged with the second horn 22.

The direction of the pressure applied by the pressurizing means is coaxial with the second horn 22, so that the direction of the pressure passes through the welding location, whereby damage or breakage of the welding head can be avoided. Specifically, the fixing structure of the top of the second horn 22 can refer to the above embodiments, and is not repeated, in an embodiment, the pressurizing device has four movable fixing plates, each fixing plate has four fixing columns, each fixing plate is attached to one side surface of the fixing block 23, and the fixing columns are embedded into the blind holes 23a, so that the fixing block 23 is clamped and fixed, and stability is ensured.

And, in order to make the pressure to be arranged coaxially with the second horn 22, the four fixing plates are movably provided on a top plate, the pressure is applied through the top plate, and then uniformly acts on the fixing block 23, and since the second horn 22 is located at the center of the bottom surface of the fixing block 23, the direction of the applied pressure is made coaxial with the second horn 22. Of course, in another embodiment, a pressurizing blind hole 23a is provided at the center of the top surface of the fixing block 23, and the pressurizing means has a pressurizing column embedded in the pressurizing blind hole 23a, and the direction of the pressurizing force is achieved by applying pressure to the pressurizing column.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A transducing structure for generating bending vibrations, comprising:

a transducer that generates axial vibration;

the variable-amplitude structure comprises a first variable-amplitude rod and a second variable-amplitude rod, one end of the first variable-amplitude rod is connected to the transducer, one end of the first variable-amplitude rod is coaxially arranged with the transducer, the bottom of the second variable-amplitude rod is used for being connected with the welding head, the top of the second variable-amplitude rod is used for being connected with welding equipment, the other end of the first variable-amplitude rod is connected between the top and the bottom of the second variable-amplitude rod, and the first variable-amplitude rod and the second variable-amplitude rod are vertically arranged.

2. The bending vibration generating transduction structure of claim 1, wherein the first horn comprises a first connecting section and a second connecting section, the first connecting section and the second connecting section being connected, the first connecting section being cylindrical, the first connecting section being connected to the transducer, the second connecting section being flat, the second connecting section being connected to the second horn.

3. A bending vibration generating transducing structure of claim 2, wherein said second connecting section has a transition section interfacing with said first connecting section, said transition section having a thickness that decreases in a direction from said second connecting section to said first connecting section.

4. A bending vibration generating transducing structure of claim 2, wherein said second connecting section has a width which decreases gradually in a direction from said first connecting section to said second horn.

5. A bending vibration generating transducing structure as defined in any of claims 1 to 4 wherein the other end of the first horn has a fixing aperture and the second horn is fixedly mounted through the fixing aperture.

6. A bending vibration generating transduction structure according to any one of claims 1 to 4 further characterized in that a fixing block is provided on the top of said second horn.

7. A bending vibration generating transducing structure as claimed in claim 6, wherein said anchor block has a plurality of blind holes therein, said anchor block being mounted to the welding apparatus through said blind holes.

8. The structure for transducing bending vibration of claim 6, wherein the fixing block has a rectangular parallelepiped shape, and the second horn is perpendicular to the center of the bottom surface of the fixing block.

9. The bending vibration generating transducing structure of claim 6, wherein said anchor block and said second horn are integrally formed.

10. A welding apparatus comprising a pressure applying means to which the tip portion of the second horn is fixed and the bending vibration generating transducing structure of any one of claims 1 to 9, the pressure applying means applying a pressure coaxially arranged with the second horn.

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