CN220744495U - Swing material-distributing conveying mechanism and laser frequency modulation device - Google Patents

Abstract

The utility model relates to the technical field of tuning fork crystal processing equipment, in particular to a swinging material distribution conveying mechanism and a laser frequency modulation device.

Description

Swing material-distributing conveying mechanism and laser frequency modulation device

Technical Field

The utility model relates to the technical field of tuning fork crystal machining equipment, in particular to a swing material-distributing and conveying mechanism and a laser frequency modulation device.

Background

In the production of tuning fork crystals, the tuning fork crystals are required to be subjected to frequency modulation treatment, the frequency of the tuning fork crystals is adjusted to a proper range, preparation is made for the press sealing of the later-stage process to improve the yield, and the frequency modulation treatment comprises two steps of detection and adjustment. In the prior art, the feeding conveying line and the laser frequency modulation device are arranged in one-to-one correspondence, however, the laser frequency modulation beat is longer, so that the waiting time of the conveying line is paused/the idling time is long, and the production efficiency is affected.

Disclosure of Invention

In order to achieve the above object, the present utility model provides a swing material-separating and conveying mechanism, comprising:

the feeding conveyor line can convey the carrier strip along the horizontal and longitudinal directions;

the first pushing piece is connected with a first horizontal driving source, and the first horizontal driving source can drive the first pushing piece to move horizontally and transversely so as to push the carrying strip on the feeding conveying line to the material moving piece;

the swing material distribution assembly comprises a base and a swing shaft arranged on the base, wherein the base is arranged at one end of the feeding conveying line so as to block the feeding conveying line, two material distribution pieces are arranged on the periphery of the swing shaft and can rotate to a horizontal position along with the swing shaft or to a position corresponding to the material moving piece;

the second pushing piece is arranged at one end of the material moving piece and is connected with a second horizontal driving source, and the second horizontal driving source is used for driving the second pushing piece to move horizontally and longitudinally so as to push the carrying strip on the material moving piece to the material distributing piece;

the two third pushing pieces are respectively arranged on two sides of the feeding conveying line and positioned at one end of the distributing piece, which rotates to the horizontal position, the third pushing pieces are connected with a third horizontal driving source, and the third horizontal driving source is used for driving the third pushing pieces to move longitudinally along the horizontal direction so as to push out the carrying strips of the distributing pieces.

In some possible implementation manners, the material distributing piece is provided with a material groove which penetrates through the material distributing piece from front to back, front ends of two opposite side edges of the material groove are respectively provided with an inclined guide surface, and a limiting part is further arranged above the material groove.

In some possible implementations, the angle between the two said dividing members is 90 °.

In some possible implementations, openings are provided on the two material-dividing members on the sides facing away from each other.

The utility model also provides a laser frequency modulation device, which comprises the swing material distribution conveying mechanism in the embodiment, and further comprises:

a base;

the two material guide tables are respectively arranged at two sides of the base and correspond to one end of the material distributing piece which rotates to the horizontal position, and the third material pushing piece can horizontally push the carrier bars on the material distributing piece to the material guide tables;

the clamping probe is arranged above the material guide table and is connected with a vertical clamping driving source, the clamping probe is connected with an external frequency analyzer, and the clamping driving source can drive the clamping probe to move downwards vertically so as to clamp one end of a tuning fork crystal and expose a tuning fork;

the laser is arranged vertically downwards and is aligned with the tuning fork.

In some possible implementations, an elastic roller is further arranged on the material guiding table at the rear end of the clamping probe, and the elastic roller elastically presses the carrier strip.

In some possible implementation manners, the rear end of the material guiding table is further provided with another swinging material distributing assembly, two ends of the swinging material distributing assembly, where the material distributing member is located at the bottom position, are respectively provided with a discharging conveying line and a fourth material pushing member, the fourth material pushing member is connected with a fourth horizontal driving source, and the fourth horizontal driving source can drive the fourth material pushing member to move along the horizontal longitudinal direction so as to push the carrier strip to the discharging conveying line.

Compared with the prior art, the utility model has the beneficial effects that: the loading bars of the loading conveyor line are respectively conveyed to the two material guide tables through the swinging material distribution conveying mechanism so as to carry out laser frequency modulation production operation, the waiting/idling time of the loading conveyor line is reduced, the utilization rate of the loading conveyor line is improved, the loading bars are conveyed in a vertical posture of tuning fork crystals by the loading conveyor line, the loading bars are driven to rotate to a horizontal posture through the swinging material distribution component and are pushed to the material guide tables, and the operation requirements of the laser frequency modulation operation are met, namely, the material distribution conveying and the changing of the loading bar/tuning fork crystal conveying posture are carried out simultaneously, and the production efficiency is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic three-dimensional structure of a swing material-distributing and conveying mechanism according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of a swing material distributing assembly according to an embodiment of the present utility model;

fig. 3 is a schematic three-dimensional structure diagram of a laser frequency modulation device according to an embodiment of the present utility model;

fig. 4 is a schematic three-dimensional structure diagram of a laser frequency modulation device according to an embodiment of the present utility model.

Reference numerals illustrate:

the device comprises a base 10, a swinging shaft 11, a material moving part 12, a material distributing part 13, a material groove 131, an inclined guide surface 132, a limiting part 133, a rotation driving source 14 and a base 15; a feeding conveying line 20, a first pushing piece 21, a second pushing piece 22, a third pushing piece 23 and a fourth pushing piece 24; a first horizontal driving source 31, a second horizontal driving source 32, a third horizontal driving source 33, a fourth horizontal driving source 34; a material guiding table 40, a clamping probe 41, a clamping driving source 42, an elastic roller 43 and a blanking conveying line 44.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model. The terms "first" and "second" are used below 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 defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the embodiments of the present disclosure, unless otherwise indicated, the meaning of "a plurality" is two or more.

Referring to fig. 1 and 2, a swinging and distributing conveying mechanism is shown, which is used for conveying carrier bars conveyed along a feeding conveying line 20 to two material guiding tables 40 respectively so as to simultaneously carry out laser frequency modulation operation, thereby improving the utilization rate of the feeding conveying line 20 and the production efficiency of fork crystals, the swinging and distributing conveying mechanism comprises a feeding conveying line 20 and a swinging and distributing component arranged at the rear end of the feeding conveying line 20, two sides of the feeding conveying line 20 are correspondingly provided with a material moving part 12 and a first pushing part 21, the first pushing part 21 is connected with a first horizontal driving source 31, a plurality of tuning fork crystals are arranged on the carrier bars, the carrier bars are conveyed to one end close to the swinging and distributing component along the horizontal longitudinal direction on the feeding conveying line 20 in a tuning fork crystal vertical position (tuning fork head upwards), the first horizontal driving source 31 drives the first pushing part 21 to move horizontally and drive the carrier bars to push the carrier bars from the feeding conveying line 20 to the material moving part 12, one end of the material moving part 12 far away from the swinging and distributing component 12 is provided with a second pushing part 22 along the horizontal longitudinal direction, and the second pushing part 22 is connected with the second pushing part 32 along the horizontal driving source 32; the swinging and distributing assembly comprises a base 15 and a swinging shaft 11 arranged on the base 15, the swinging shaft 11 is connected with a rotating driving source 14 capable of rotating positively and negatively, the base 15 is arranged at one end of a feeding conveying line 20 to block the feeding conveying line 20, so that the carrier bars are prevented from falling and damaging due to continuous conveying along the feeding conveying line 20, two distributing pieces 13 are arranged on the periphery of the swinging shaft 11, the distributing pieces 13 can rotate along with the swinging shaft 11 to the positions corresponding to the distributing pieces 12, at the moment, a second horizontal driving source 32 pushes the carrier bars on the distributing pieces 12 onto the distributing pieces 13, the distributing pieces 13 rotate along with the swinging shaft 11 to the horizontal positions, at the moment, the carrier bars also rotate along with the distributing pieces 13 to the horizontal postures of tuning fork crystals, a third pushing piece 23 is arranged at one end of the position of the distributing pieces 13, and the third pushing piece 23 is connected with a third horizontal driving source 33, and the third horizontal driving source 33 is used for driving the third pushing piece 23 to move along the horizontal longitudinal direction so as to push the carrier bars on the distributing pieces 13 horizontally; in this embodiment, when one of the material separating members 13 rotates to a horizontal position along with the swinging shaft 11, the other material separating member 13 is just located at a position corresponding to the material moving member 12, so that the third pushing member 23 pushes out the carrier bar and the second pushing member 22 pushes the other carrier bar to the material separating member 13 at the same time, thereby further improving the production efficiency; it should be noted that, the third pushing member 23 has two and is separately disposed at two sides of the feeding conveying line 20, so as to correspondingly convey the carrier bars to two different stations, that is, one feeding conveying line 20 can simultaneously feed two laser frequency modulation devices, and the tuning fork crystal is placed on the carrier bars in a vertical posture and conveyed along the feeding conveying line 20 along with the carrier bars, after the swinging and distributing action of the swinging and distributing assembly, the tuning fork crystal can be conveyed to the laser frequency modulation device in a horizontal posture, so as to meet the placement requirement of the laser frequency modulation operation, that is, the swinging and distributing conveying mechanism can simultaneously realize the functions of distributing and conveying and adjusting the posture of the tuning fork crystal, thereby further improving the production efficiency.

In some possible implementation manners, referring to fig. 2, the material distributing member is provided with a trough 131 penetrating from front to back, the second material pushing member 22 pushes the carrier bar to the trough 131, the carrier bar rotates along with the material distributing member to the tuning fork crystal to be in a horizontal posture, the front ends of two opposite sides of the trough 131 are respectively provided with an inclined guide surface 132, so as to ensure that the second material pushing member 22 can accurately push the carrier bar into the trough 131, and a limit part 133 is further arranged above the trough 131, so as to avoid the problem that the carrier bar is broken due to falling out of the trough 131 when swinging along with the material distributing member 13.

In some possible implementation manners, the included angle between the two material separating pieces 13 on the swinging shaft 11 is 90 °, so when one material separating piece 13 is located at a position corresponding to the material moving piece 12, the other material separating piece 13 is located at a horizontal position, so that the third material pushing piece 23 can conveniently push out the carrier strips in the material separating pieces, that is, the two material separating pieces 13 can be produced simultaneously, and the efficiency is improved.

In some possible implementation manners, the sides, facing away from each other, of the two material distributing pieces 13 are provided with openings, and the sizes of the openings are larger than those of the carrier bars, so that if the machine is in error, the carrier bars can be taken out from the openings, and the machine is convenient to reset and maintain.

The utility model also provides a laser frequency modulation device, refer to fig. 3 and 4, it includes the swing feed conveying mechanism as above embodiment, further include the base 10 and divide two guide tables 40 set up on both sides of the base 10, two guide tables 40 correspond to two material-dividing pieces 13 turned to the horizontal position separately, the third pushing piece 23 can push the carrier bar of the tuning fork crystal in the trough 131 in horizontal posture to the guide table 40, the upper side of the guide table 40 is provided with the clamp probe 41 and laser (not shown) facing down vertically and aligning the tuning fork, the clamp probe 41 is connected with the clamp driving source 42, the clamp driving source 42 can drive the clamp probe 41 to move down vertically and turn on one end of the tuning fork close to the carrier bar, in order to ensure the tuning fork to reveal and facilitate the subsequent laser frequency modulation operation, the clamp probe 41 connects with the external frequency analyzer (not shown) to make the tuning fork crystal frequency analysis through the frequency analyzer, and control the laser to make the tuning fork crystal frequency adjustment according to the analysis result, in particular, send out the laser to change the thickness of the tuning fork crystal, in order to change the frequency range of the tuning fork crystal, and then pass the tuning fork crystal frequency adjustment.

In some possible implementation manners, the elastic roller 43 is further disposed on the material guiding table 40 at the rear end of the clamping probe 41, and the elastic roller 43 is elastically pressed against the carrier bar from top to bottom, so as to avoid the problem that the carrier bar on the material guiding table 40 is transferred to be in place due to the inertia effect of the carrier bar when the third material pushing member 23 pushes the carrier bar, so that the clamping probe 41 cannot align and clamp the tuning fork crystal.

In some possible implementations, referring to fig. 4, a rear end of the guide table 40 is further provided with another swing and feed assembly, a lower end of the swing and feed assembly is further provided with a blanking conveying line 44 and a fourth pushing member 24, the third pushing member 23 may push the carrier bar onto the guide table 40 and push the tuning fork crystal/carrier bar with laser tuning after the rear end of the guide table 40 onto the feed member 13 of the swing and feed assembly, the swing and feed assembly is configured to swing the feed member 13 to move the carrier bar with the operation completed to a position corresponding to the blanking conveying line 44, the fourth pushing member 24 is connected to a fourth horizontal driving source 34, and the fourth horizontal driving source 34 drives the fourth pushing member 24 to move along the horizontal longitudinal direction so as to push the carrier bar in the feed member 13 to the blanking conveying line 44.

The foregoing is merely illustrative of specific embodiments of the present utility model, and the scope of the present utility model is not limited thereto, but any changes or substitutions within the technical scope of the present utility model should be covered by the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (7)

1. The utility model provides a swing feed conveyor which characterized in that includes:

the feeding conveyor line can convey the carrier strip along the horizontal and longitudinal directions;

the first pushing piece is connected with a first horizontal driving source, and the first horizontal driving source can drive the first pushing piece to move horizontally and transversely so as to push the carrying strip on the feeding conveying line to the material moving piece;

the swing material distribution assembly comprises a base and a swing shaft arranged on the base, wherein the base is arranged at one end of the feeding conveying line so as to block the feeding conveying line, two material distribution pieces are arranged on the periphery of the swing shaft and can rotate to a horizontal position along with the swing shaft or to a position corresponding to the material moving piece;

the second pushing piece is arranged at one end of the material moving piece and is connected with a second horizontal driving source, and the second horizontal driving source is used for driving the second pushing piece to move horizontally and longitudinally so as to push the carrying strip on the material moving piece to the material distributing piece;

the two third pushing pieces are respectively arranged on two sides of the feeding conveying line and positioned at one end of the distributing piece, which rotates to the horizontal position, the third pushing pieces are connected with a third horizontal driving source, and the third horizontal driving source is used for driving the third pushing pieces to move longitudinally along the horizontal direction so as to push out the carrying strips of the distributing pieces.

2. The swing material distributing and conveying mechanism according to claim 1, wherein the material distributing piece is provided with a trough penetrating through the material distributing piece from front to back, front ends of two opposite sides of the trough are respectively provided with an inclined guide surface, and a limiting part is further arranged above the trough.

3. A swinging distributing and conveying mechanism according to claim 1, wherein the angle between two distributing members is 90 °.

4. A swing dispensing conveyor according to claim 2 or claim 3, wherein the two said dispensing members are provided with openings on opposite sides thereof.

5. A laser frequency modulation device comprising the oscillating feed conveyor mechanism of any one of claims 1 to 4, further comprising:

a base;

the two material guide tables are respectively arranged at two sides of the base and correspond to one end of the material distributing piece which rotates to the horizontal position, and the third material pushing piece can horizontally push the carrier bars on the material distributing piece to the material guide tables;

the clamping probe is arranged above the material guide table and is connected with a vertical clamping driving source, the clamping probe is connected with an external frequency analyzer, and the clamping driving source can drive the clamping probe to move downwards vertically so as to clamp one end of a tuning fork crystal and expose a tuning fork;

the laser is arranged vertically downwards and is aligned with the tuning fork.

6. The laser frequency modulation device according to claim 5, wherein an elastic roller is further arranged on the material guiding table at the rear end of the clamping probe, and the elastic roller is elastically pressed against the carrier strip.

7. The laser frequency modulation device according to claim 5, wherein the rear end of the material guiding table is further provided with another swinging material distribution assembly, two ends of the swinging material distribution assembly, which are positioned at the bottom, of the material distribution member are respectively provided with a material discharging conveying line and a fourth material pushing member, the fourth material pushing member is connected with a fourth horizontal driving source, and the fourth horizontal driving source can drive the fourth material pushing member to move along the horizontal and longitudinal directions so as to push a carrier bar to the material discharging conveying line.