CN115140608B

CN115140608B - Clamping and fixing device for solder wire winding production

Info

Publication number: CN115140608B
Application number: CN202210778036.7A
Authority: CN
Inventors: 江沙
Original assignee: Shenzhen Xinhongtai Tin Industry Co ltd
Current assignee: Shenzhen Xinhongtai Tin Industry Co ltd
Priority date: 2022-07-04
Filing date: 2022-07-04
Publication date: 2024-05-03
Anticipated expiration: 2042-07-04
Also published as: CN115140608A

Abstract

The invention relates to a fixing device, in particular to a clamping and fixing device for solder wire winding production. The invention aims to provide a clamping and fixing device for solder wire winding production, which is more uniform in winding and has a heat dissipation function. The technical scheme is as follows: the utility model provides a solder wire is around production with centre gripping fixing device, including: a housing; the ventilation openings are formed in two sides of the shell; the clamping assembly is symmetrically arranged on one side of the inside of the shell; the pushing assembly is arranged on the inner side of the shell and is connected with the clamping assembly. After people pass through the guide cylinder and wind on the winding drum, when the guide cylinder continuously reciprocates left and right, the tin wire can be more uniformly wound on the winding drum, so that the working efficiency of people is effectively improved, and the winding drum is convenient for people to pack the winding drum better in later period.

Description

Clamping and fixing device for solder wire winding production

Technical Field

The invention relates to a fixing device, in particular to a clamping and fixing device for solder wire winding production.

Background

The solder wire consists of two parts of tin alloy and auxiliary agent, and has the characteristics of tin alloy wire with certain length and diameter, and can be matched with an electric soldering iron in the welding of electronic original devices.

In the solder wire production industry, after the solder wire is manufactured, the solder wire needs to be wound on a winding drum to be packaged and sold, at present, in the existing solder wire winding and fixing equipment, the winding drum is lower in stability in the rotating winding process, the winding drum is easy to separate, the winding speed and the working efficiency are affected, the winding is uneven, the solder wire is easy to gather, the labor intensity of people is increased, the solder wire does not have a heat dissipation function, and the equipment is difficult to perform winding work and other problems due to overhigh temperature in the winding process of the solder wire.

In summary, there is a need to design a clamping and fixing device for solder wire winding production, which has more uniform winding and heat dissipation function, so as to solve the above problems.

Disclosure of Invention

In order to overcome the defects that in the existing soldering wire winding and fixing equipment, winding is uneven, soldering wires are easy to gather at one place, labor intensity of people is increased, the equipment is difficult to perform winding work due to overhigh temperature, and the invention aims to provide the clamping and fixing device for soldering wire winding production, which is even in winding and has the heat dissipation function.

The technical scheme is as follows: the utility model provides a solder wire is around production with centre gripping fixing device, including: a housing; the ventilation openings are formed in two sides of the shell; the clamping assembly is symmetrically arranged on one side of the inside of the shell; the pushing component is arranged on the inner side of the shell and is connected with the clamping component; the clamping assembly is provided with eight jacking blocks in a uniformly sliding mode at intervals; the support component is arranged on one side of the inside of the shell; the support assembly is provided with two placing groove blocks; the driving assembly is arranged between the supporting assembly and the shell.

Furthermore, it is particularly preferred that the clamping assembly comprises: the upper side of the inner part of the shell is symmetrically and slidably provided with the supporting shell, and the supporting shell is slidably connected with the top block; the first springs are arranged between the top blocks and the supporting shell; the middle of the inside of the supporting shell is provided with the supporting frame; the support frame is uniformly provided with four first sliding rods in a sliding manner at intervals; the second springs are arranged between the first sliding rod and the supporting frame, and are sleeved on the supporting frame; the clamping blocks are arranged on the inner sides of the first sliding rods.

Furthermore, it is particularly preferred that the pushing assembly comprises: the first distance sensor is arranged in the middle of one side of the top of the shell; the middle of the other side of the inner part of the shell is provided with the first supporting block; the electric push rod is arranged on the inner side of the first supporting block; the first support rods are symmetrically arranged on one side of the inside of the shell; the first push rods are arranged between the first support rods in a sliding mode, and are connected with telescopic rods of the electric push rods; the second support rods are symmetrically arranged on one side of the inside of the shell; the sliding rods are arranged between the second support rods on two sides in a sliding mode, and the first push rod is matched with the sliding rods; the third springs are symmetrically arranged between the sliding rod and the shell, and are sleeved on the second supporting rod; the inner sides of the upper parts of the sliding rods are respectively provided with the first rotating shafts in a rotating mode, and the first rotating shafts are respectively connected with the supporting shell.

Furthermore, it is particularly preferred that the support assembly comprises: the middle of one side of the lower part in the shell is symmetrically provided with two first guide rods; the sliding frames are arranged between the first guide rods on the two sides in a sliding mode, and are connected with the placing groove blocks; the fourth springs are arranged between the sliding frame and the first guide rod, and are sleeved on the first guide rod; the second sliding rod is arranged between the inner sides of the lower parts of the sliding frames; the second supporting blocks are symmetrically arranged in the middle of the inside of the shell; the ejector rods are arranged between the second supporting blocks in a sliding mode, the ejector rods are matched with the second sliding rods, and the first ejector rods are matched with the second sliding rods; and the fifth springs are arranged between the ejector rods and the second supporting blocks, and are sleeved on the ejector rods.

Furthermore, it is particularly preferred that the drive assembly comprises: the middle of one side of the lower part in the shell is provided with the third supporting block; the second distance sensor is arranged on the other side of the top of the third supporting block; the driving motor is arranged in the middle of the lower side of the inner part of the shell; the fourth supporting block is symmetrically arranged on one side of the lower side of the inner part of the shell; the second rotating shaft is rotatably arranged between the inner sides of the fourth supporting blocks; the middle part of the second rotating shaft and the output shaft of the driving motor are respectively provided with a first bevel gear, and the first bevel gears are meshed with each other; the other side of the upper part in the shell is symmetrically provided with the fifth supporting block; the inner side of the fifth supporting block is provided with the shaft sleeve in a rotary mode; the inner sides of the shaft sleeves are provided with sliding shafts in a sliding mode, and the sliding shafts are connected with the first rotating shaft; the first transmission wheels are arranged on the outer sides of the shaft sleeves, and the first transmission wheels are arranged on the two sides of the second rotating shaft; the first driving belts are wound between the first driving wheels on two sides; and the sixth springs are arranged between the sliding shaft and the shaft sleeve.

Furthermore, it is particularly preferred that a guiding assembly is also included, the guiding assembly comprising: the stepping motor is arranged on one side, close to the driving motor, of the other side of the inner part of the shell; the sixth supporting block is symmetrically arranged on the other side of the inner part of the shell; the third rotating shaft is rotatably arranged between the inner sides of the sixth supporting blocks; the middle part of the third rotating shaft and the output shaft of the stepping motor are respectively provided with a second bevel gear, and the second bevel gears are meshed with each other; the sliding groove barrel is symmetrically and rotatably arranged on the other side of the inner upper part of the shell; the second driving wheels are arranged on the outer sides of the chute barrels, and the second driving wheels are also arranged on the two sides of the third rotating shaft; the second driving belt is wound between the second driving wheels at two sides; the second guide rod is symmetrically arranged on the other side of the upper part in the shell; the third sliding rod is arranged between the inner sides of the second guide rods in a sliding mode, and is matched with the chute barrel in a sliding mode; the guide cylinder is arranged on one side of the top of the third sliding rod.

In addition, it is particularly preferable to further include a heat dissipating assembly including: the heat dissipation button is arranged in the middle of one side of the inside of the shell, the ejector rod is matched with the heat dissipation button, and the heat dissipation button is positioned on the upper side of the third supporting block; the fixed block, the shell inboard with all be equipped with between the vent the fixed block: the fan is arranged on the inner side of the fixed block in a rotary mode.

In addition, particularly preferred is, still include the control box, be equipped with in the middle of shell one side the control box, install switching power supply, power module and control module in the control box, switching power supply is this device power supply, and switching power supply's output passes through electric connection with power module, and power module has the power master switch through the circuit connection, and power module passes through electric connection with control module, is connected with DS1302 clock circuit and 24C02 circuit on the control module, first distance sensor the second distance sensor with heat dissipation button all passes through electric connection with control module, electric putter step motor the driving motor with the fan all passes through peripheral circuit connection with control module.

The beneficial effects are as follows: 1. according to the winding device, after the clamping blocks move inwards to the inner side of the winding drum, when the clamping blocks move outwards, the clamping blocks clamp the winding drum, so that the stabilizing effect of the winding drum is improved, the winding drum is prevented from falling off when winding, and the winding work efficiency of the winding drum is effectively improved.

2. After people pass through the guide cylinder and wind on the winding drum, when the guide cylinder continuously reciprocates left and right, the tin wire can be more uniformly wound on the winding drum, so that the working efficiency of people is effectively improved, and the winding drum is convenient for people to pack the winding drum better in later period.

3. After the ejector rod extrudes the heat dissipation button, the fan can be started to work, so that the heat dissipation effect is achieved, after the ejector rod is far away from the heat dissipation button, the fan can be closed, so that the device can well conduct heat dissipation during working, and the situation that the temperature inside the shell is too high is avoided.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of another perspective view of the present invention.

Fig. 3 is a schematic internal perspective view of the present invention.

Fig. 4 is a schematic internal perspective view of another view of the present invention.

Fig. 5 is a schematic view of the structure of the clamping assembly of the present invention.

FIG. 6 is a schematic view of a portion of the structure of the clamping assembly of the present invention.

Fig. 7 is a schematic structural view of the pushing assembly of the present invention.

Fig. 8 is a schematic structural view of the support assembly of the present invention.

Fig. 9 is a schematic view of a portion of the structure of the support assembly of the present invention.

Fig. 10 is a schematic structural view of the driving assembly of the present invention.

FIG. 11 is a schematic view of another view of the driving assembly of the present invention.

Fig. 12 is a schematic view of the guide assembly of the present invention.

Fig. 13 is a schematic view of another view of the guide assembly of the present invention.

Fig. 14 is a schematic structural diagram of a first portion of the heat dissipating assembly according to the present invention.

Fig. 15 is a schematic structural diagram of a second portion of the heat dissipating assembly according to the present invention.

Fig. 16 is a circuit block diagram of the present invention.

Fig. 17 is a schematic circuit diagram of the present invention.

Wherein the above figures include the following reference numerals: 1. a housing, 2, a ventilation opening, 3, a control box, 4, a top block, 5, a placement groove block, 6, a clamping component, 601, a supporting shell, 602, a first spring, 603, a supporting frame, 604, a first slide bar, 605, a second spring, 606, a clamping block, 7, a pushing component, 701, a first distance sensor, 702, a first supporting block, 703, an electric push rod, 704, a first supporting rod, 705, a first push rod, 706, a second supporting rod, 707, a slide bar, 708, a third spring, 709, a first rotating shaft, 8, a supporting component, 801, a first guide bar, 802, a slide frame, 803, a fourth spring, 804, a second slide bar, 805, a second supporting block, 806, a push rod, 807, a fifth spring, 9, a driving component, 901, third supporting block, 902, second distance sensor, 903, driving motor, 904, first bevel gear, 905, fourth supporting block, 906, second rotation shaft, 907, first driving wheel, 908, first driving belt, 909, fifth supporting block, 910, shaft sleeve, 911, sliding shaft, 912, sixth spring, 10, guiding component, 1001, stepping motor, 1002, second bevel gear, 1003, sixth supporting block, 1004, third rotation shaft, 1005, second driving wheel, 1006, second driving belt, 1007, chute barrel, 1008, second guiding rod, 1009, third sliding rod, 1010, guiding cylinder, 11, heat dissipating component, 1101, heat dissipating button, 1102, fixed block, 1103, fan.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

The utility model provides a soldering tin wire is around production with centre gripping fixing device, as shown in fig. 1-11, including shell 1, vent 2, kicking block 4, standing groove piece 5, clamping assembly 6, pushing assembly 7, supporting assembly 8 and actuating assembly 9, vent 2 is all installed to shell 1 left and right sides, clamping assembly 6 is installed to the inside left and right sides bilateral symmetry of shell 1, shell 1 inboard is provided with pushing assembly 7, pushing assembly 7 is connected with clamping assembly 6, eight kicking blocks 4 are installed to the equal interval uniform sliding on the clamping assembly 6, shell 1 inside front side is connected with supporting assembly 8, be connected with two standing groove pieces 5 on the supporting assembly 8, be connected with actuating assembly 9 between supporting assembly 8 and the shell 1.

The clamping assembly 6 comprises a supporting shell 601, a first spring 602, a supporting frame 603, a first sliding rod 604, a second spring 605 and a clamping block 606, wherein the supporting shell 601 is arranged on the upper side of the inside of the shell 1 in a bilateral symmetry sliding mode, the supporting shell 601 is connected with a top block 4 in a sliding mode, the first spring 602 is connected between the top block 4 and the supporting shell 601, the supporting frame 603 is fixedly connected in the middle of the inside of the supporting shell 601, the first sliding rod 604 is arranged on the front side, the rear side, the upper side and the lower side of the supporting frame 603 in a sliding mode, the second spring 605 is connected between the first sliding rod 604 and the supporting frame 603, the second spring 605 is sleeved on the supporting frame 603, and the clamping block 606 is fixedly connected on the inner side of the first sliding rod 604.

The pushing assembly 7 comprises a first distance sensor 701, a first supporting block 702, an electric push rod 703, first supporting rods 704, first push rods 705, second supporting rods 706, sliding rods 707, third springs 708 and a first rotating shaft 709, wherein the first distance sensor 701 is installed in the middle of the front side of the top of the shell 1, the first supporting block 702 is fixedly connected in the middle of the rear lower side of the inside of the shell 1, the electric push rod 703 is installed in the inner side of the first supporting block 702, the first supporting rods 704 are fixedly connected in a bilateral symmetry manner in the rear side of the inside of the shell 1, the first push rods 705 are connected between the first supporting rods 704 in a sliding manner, the first push rods 705 are connected with telescopic rods of the electric push rod 703, the two second supporting rods 706 are fixedly connected in a bilateral symmetry manner in the front side of the inside of the shell 1, the sliding rods 707 are matched with the sliding rods 707, the third springs 708 are symmetrically connected between the sliding rods 707 and the shell 1, the third springs 708 are sleeved on the second supporting rods 706, the inner side of the upper part of the sliding rods are rotatably provided with the first rotating shaft 709, and the first rotating shaft 601 are connected with the supporting shells 601.

The first distance sensor 701 is internally provided with a first preset value and a second preset value, the first preset value is larger than the second preset value, when the solder drum is required to be wound, a power supply main switch is pressed down to electrify the device, then people put the drum on the placing groove block 5, after the first distance sensor 701 senses the drum, the distance between the drum and the first distance sensor 701 reaches the first preset value of the first distance sensor 701, the first distance sensor 701 sends out a signal, the control module receives the signal and controls the electric push rod 703 to be closed after the expansion rod of the electric push rod 703 is elongated for 3 seconds, after the expansion rod of the electric push rod 703 is elongated, the first push rod 705 is driven to move forwards to touch the sliding rod 707, the first rotary shaft 709, the supporting shell 601, the top block 4 and the clamping block 606 are driven to move inwards, the third spring 708 is compressed, the clamping block 606 moves inwards to the inner side of the drum, the ejector block 4 moves inwards to contact with the winding drum to drive the ejector block 4 to move outwards, the first spring 602 is stretched to enable the four ejector blocks 4 to move outwards to contact the first sliding rod 604 to drive the first sliding rod 604 and the clamping block 606 to move outwards, the second spring 605 is compressed to enable the clamping block 606 to move outwards to clamp the winding drum, so that people can manually rotate the winding drum to wind tin wires, the winding drum rotates to drive the clamping block 606, the ejector block 4, the supporting shell 601 and the first rotating shaft 709 to rotate, at the moment, under the action of the ventilation opening 2, air circulation is kept in the shell 1, when tin wires wound on the winding drum are gradually increased, after the distance between the tin wires and the first distance sensor 701 reaches a second preset value of the first distance sensor 701, the first distance sensor 701 sends out a signal, the control module receives the signal to control the electric push rod 703 to shrink for 3 seconds and then close, after the telescopic rod of the electric push rod 703 is shortened, the first push rod 705 is driven to move backwards and away from the sliding rod 707, the third spring 708 is reset, the sliding rod 707, the first rotary shaft 709, the supporting shell 601, the top block 4 and the clamping block 606 are driven to move outwards, the top block 4 is far away from the winding drum, the first spring 602 is reset, the top block 4 is driven to move inwards, the four top blocks 4 at intervals move inwards and separate from the first sliding rod 604, the second spring 605 is reset, the first sliding rod 604 and the clamping block 606 are driven to move inwards and reset, the clamping block 606 cannot clamp the winding drum, so that people can take down the winding drum with a tin wire wound, and when the device is not used, people can press the power main switch again to cut off the power of the device.

Example 2

On the basis of embodiment 1, as shown in fig. 12-17, the supporting component 8 comprises a first guide rod 801, a sliding frame 802, a fourth spring 803, a second sliding rod 804, a second supporting block 805, a top rod 806 and a fifth spring 807, wherein the two first guide rods 801 are fixedly connected in a left-right symmetrical manner in the middle of the front side of the inner part of the shell 1, the sliding frame 802 is installed between the first guide rods 801 on the front side and the rear side, the sliding frame 802 is connected with the placing groove block 5, the fourth spring 803 is connected between the sliding frame 802 and the first guide rods 801, the fourth spring 803 is sleeved on the first guide rods 801, a second sliding rod 804 is connected between the inner side of the lower part of the sliding frame 802, the second supporting block 805 is fixedly connected in a left-right symmetrical manner in the middle of the inner part of the shell 1, the top rod 806 is slidably arranged between the second supporting block 805, the top rod 806 is matched with the second sliding rod 804, the first push rod 705 is matched with the second sliding rod 805, the fifth spring 807 is connected between the top rod 806 and the second supporting block 805, and the fifth spring 807 is sleeved on the top rod 807.

The driving assembly 9 comprises a third supporting block 901, a second distance sensor 902, a driving motor 903, a first bevel gear 904, a fourth supporting block 905, a second rotating shaft 906, a first transmission wheel 907, a first transmission belt 908, a fifth supporting block 909, a shaft sleeve 910, a sliding shaft 911 and a sixth spring 912, wherein the third supporting block 901 is fixedly connected in the middle of the lower front side in the housing 1, the second distance sensor 902 is installed on the rear side of the top of the third supporting block 901, the driving motor 903 is installed in the middle of the lower side in the housing 1, the fourth supporting block 905 is fixedly connected on the left and right sides of the front side of the lower side in the housing 1 in a symmetrical manner, the second rotating shaft 906 is rotatably arranged between the inner side of the fourth supporting block 905, the first bevel gear 904 is connected to the middle of the second rotating shaft 906, the first bevel gear 904 is meshed with the output shaft of the driving motor 903, the fifth supporting block 909 is fixedly connected on the left and right sides of the front side of the upper side in a symmetrical manner, the inner side of the shaft sleeve 910 is rotatably connected with the sliding shaft 910, the sliding shaft 911 is connected with the first rotating shaft 709, the upper and the lower side of the first bevel gear 907 is also rotatably connected with the first bevel gear 912, and the upper and the lower side of the transmission shaft 908 is rotatably arranged on the two sides of the first bevel gear 907.

The second distance sensor 902 is provided with a first preset value and a second preset value, the value of the first preset value is smaller than that of the second preset value, after people press the power main switch to power on the device, when the first rotating shaft 709 moves inwards, the sliding shaft 911 is driven to move inwards, the sixth spring 912 is stretched, when the first push rod 705 moves forwards, the first push rod 705 contacts with the push rod 806, the push rod 806 moves forwards, the fifth spring 807 is compressed, the push rod 806 moves forwards to contact with the second slide rod 804, the sliding frame 802 and the placing groove block 5 move downwards, the fourth spring 803 is compressed, the placing groove block 5 moves downwards to be away from the winding drum, after the distance between the first slide rod 604 and the second distance sensor 902 reaches the first preset value of the second distance sensor 902, the second distance sensor 902 sends out a signal, the control module receives the signal and then controls the driving motor 903 to electrify and work, under the action of the output shaft of the driving motor 903, thereby driving the first bevel gear 904, the second rotating shaft 906, the first transmission wheel 907, the first transmission belt 908 and the shaft sleeve 910 to rotate, and further driving the sliding shaft 911, the first rotating shaft 709, the supporting shell 601 and the winding drum to rotate, thus achieving the function of automatically winding tin wire, under the action that the placing groove block 5 is far away from the winding drum, the winding drum can perform better winding work, when the winding drum finishes the tin wire winding, the first rotating shaft 709 moves outwards, the sixth spring 912 resets, driving the sliding shaft 911 to move outwards for resetting, and the fifth spring 807 resets, driving the ejector 806 to move backwards for resetting, driving the ejector 806 to move backwards for keeping the ejector 806 away from the second sliding rod 804, the fourth spring 803 resets, driving the sliding frame 802 to perform winding work, the second slide bar 804 and the standing groove move upwards to reset, the second slide bar 804 moves upwards to be far away from the second distance sensor 902, after the distance between the second slide bar 804 and the second distance sensor 902 reaches a second preset value of the second distance sensor 902, the second distance sensor 902 sends out a signal, the control module receives the signal and then controls the driving motor 903 to stop working, and when the device is not needed, people press the power supply main switch again to cut off power to the device.

The guide assembly 10 comprises a stepping motor 1001, a second bevel gear 1002, a sixth supporting block 1003, a third rotating shaft 1004, a second driving wheel 1005, a second driving belt 1006, a chute barrel 1007, a second guide rod 1008, a third sliding rod 1009 and a guide cylinder 1010, wherein the stepping motor 1001 is arranged below the rear side of the inside of the casing 1, the stepping motor 1001 is positioned at the rear side of the driving motor 903, the sixth supporting block 1003 is fixedly connected on the left and right sides of the rear side of the inside of the casing 1, the third rotating shaft 1004 is rotatably arranged between the inner sides of the sixth supporting block 1003, the middle part of the third rotating shaft 1004 and the output shaft of the stepping motor 1001 are respectively provided with the second bevel gear 1002, the second bevel gears 1002 are meshed with each other, the left and right sides of the inside of the casing 1 are respectively provided with the second driving wheel 1005, the second driving wheels 1005 are respectively arranged on the outer sides of the chute barrel 1007, the second driving belts 1006 are respectively wound on the left and right sides of the second driving wheels, the left and right sides of the inside of the casing 1 are respectively fixedly connected on the rear side of the upper part of the second driving wheel, the third rotating shaft 1008 is provided with the third guide rod 1008, the third sliding rod 1009 is arranged on the left and right sides of the third sliding rod 1009, and the third sliding rod 1009 are matched with the sliding rod 1009.

When the broken reel is needed to be wound, people pass tin wire through the guide cylinder 1010, then the tin wire is wound on the reel, after the distance between the second slide rod 804 and the second distance sensor 902 reaches a first preset value of the second distance sensor 902, the second distance sensor 902 sends out a signal, after receiving the signal, the control module controls the output shaft of the stepping motor 1001 to rotate forward for 4 seconds and then to be closed, when the output shaft of the stepping motor 1001 rotates forward, the control module drives the second bevel gear 1002, the second rotating shaft 906, the second driving wheel 1005, the second driving belt 1006 and the chute cylinder 1007 to rotate forward, and then drives the third slide rod 1009 and the guide cylinder 1010 to move leftwards, under the action of the guide cylinder 1010, the control module controls the output shaft of the stepping motor 1001 to rotate reversely for 4 seconds after the stepping motor 1001 is closed for 1 second seconds, and then drives the second bevel gear 1002, the second rotating shaft 906, the second driving wheel 1006 and the chute cylinder 1007 to rotate reversely, and further drives the third slide rod 1009 and the guide cylinder 1010 to move rightwards, and if the control the second distance sensor 902 repeatedly stops the second distance sensor 902 after the second slide rod is controlled by the control module to send out a signal when the second distance sensor 902 reaches a preset value after the second distance sensor 902 is controlled on the first preset value.

The heat dissipation assembly 11 is further arranged, the heat dissipation assembly 11 comprises a heat dissipation button 1101, a fixing block 1102 and a fan 1103, the heat dissipation button 1101 is arranged in the middle of the front side of the inner portion of the shell 1, the ejector rod 806 is matched with the heat dissipation button 1101, the heat dissipation button 1101 is located on the upper side of the third supporting block 901, the fixing block 1102 is fixedly connected between the inner side of the shell 1 and the ventilation opening 2, and the fan 1103 is rotatably arranged on the inner side of the fixing block 1102.

When the ejector rod 806 moves forwards, the ejector rod 806 presses the heat dissipation button 1101, so that the control module controls the fans 1103 to be electrified to work, the left side fan 1103 and the right side fan 1103 rotate in opposite directions, the left side fan 1103 conveys air into the shell 1 through the left side ventilation opening 2, and then the right side fan 1103 distributes hot air in the shell 1 out through the right side ventilation opening 2, so that the heat dissipation effect is achieved, and when the ejector rod 806 moves backwards to be far away from the heat dissipation button 1101, the control module controls the fans 1103 to stop working.

Still including control box 3, install control box 3 in the middle of the shell 1 front side, install switching power supply in the control box 3, power module and control module, switching power supply is this device power supply, switching power supply's output and power module pass through electric connection, power module has the power master switch through the line connection, power module and control module pass through electric connection, be connected with DS1302 clock circuit and 24C02 circuit on the control module, first distance sensor 701, second distance sensor 902 and heat dissipation button 1101 all pass through electric connection with control module, electric putter 703, step motor 1001, driving motor 903 and fan 1103 all pass through peripheral circuit connection with control module.

While the present invention has been described in detail with reference to the above embodiments, it will be apparent to those skilled in the art from this disclosure that various changes or modifications can be made therein without departing from the spirit and scope of the invention as defined in the following claims. Accordingly, the detailed description of the disclosed embodiments is to be taken only by way of illustration and not by way of limitation, and the scope of protection is defined by the content of the claims.

Claims

1. The utility model provides a solder wire is around production with centre gripping fixing device which characterized in that includes:

A housing (1);

the air vent (2) is arranged on two sides of the shell (1);

the clamping assembly (6) is symmetrically arranged on one side of the inside of the shell (1);

The pushing component (7) is arranged on the inner side of the shell (1), and the pushing component (7) is connected with the clamping component (6);

The jacking blocks (4) are uniformly and slidably arranged on the clamping assembly (6) at intervals, and eight jacking blocks (4) are arranged on the clamping assembly at intervals;

The support assembly (8) is arranged on one side of the interior of the shell (1);

the support assembly (8) is provided with two placing groove blocks (5);

The driving assembly (9) is arranged between the supporting assembly (8) and the shell (1);

The clamping assembly (6) comprises:

The support shell (601) is symmetrically arranged on the upper side of the inside of the shell (1) in a sliding mode, and the support shell (601) is connected with the top block (4) in a sliding mode;

The first springs (602) are arranged between the top blocks (4) and the supporting shell (601);

The support frames (603) are arranged in the middle of the inside of the support shell (601);

The first sliding rods (604) are uniformly arranged on the supporting frame (603) at intervals in a sliding manner, and four first sliding rods (604) are arranged on the supporting frame at intervals;

The second springs (605) are arranged between the first sliding rods (604) and the supporting frame (603), and the second springs (605) are sleeved on the supporting frame (603);

the clamping blocks (606) are arranged on the inner sides of the first sliding rods (604);

The pushing component (7) comprises:

A first distance sensor (701), wherein the first distance sensor (701) is arranged in the middle of one side of the top of the shell (1);

The first supporting block (702) is arranged in the middle of the other side of the inside of the shell (1);

an electric push rod (703), wherein the electric push rod (703) is arranged on the inner side of the first supporting block (702);

The first support rod (704) is symmetrically arranged on one side of the inside of the shell (1);

the first push rods (705), the first push rods (705) are arranged between the first support rods (704) in a sliding mode, and the first push rods (705) are connected with telescopic rods of the electric push rods (703);

The second support rods (706) are symmetrically arranged on one side of the inside of the shell (1);

The sliding rods (707) are arranged between the second support rods (706) at both sides in a sliding manner, and the first push rod (705) is matched with the sliding rods (707);

The third springs (708) are symmetrically arranged between the sliding rod (707) and the shell (1), and the third springs (708) are sleeved on the second supporting rod (706);

And the inner sides of the upper parts of the sliding rods (707) are respectively provided with the first rotating shafts (709) in a rotating mode, and the first rotating shafts (709) are respectively connected with the supporting shell (601).

2. A holding fixture for solder wire winding production according to claim 1, characterized in that the support assembly (8) comprises:

the first guide rods (801) are symmetrically arranged in the middle of one side of the lower part in the shell (1);

The sliding frames (802) are arranged between the first guide rods (801) on two sides in a sliding mode, and the sliding frames (802) are connected with the placing groove blocks (5);

the fourth springs (803) are arranged between the sliding frame (802) and the first guide rod (801), and the fourth springs (803) are sleeved on the first guide rod (801);

a second sliding rod (804), wherein the second sliding rod (804) is arranged between the inner sides of the lower part of the sliding frame (802);

The second supporting block (805) is symmetrically arranged in the middle of the inside of the shell (1);

the ejector rods (806) are arranged between the second supporting blocks (805) in a sliding mode, the ejector rods (806) are matched with the second sliding rods (804), and the first pushing rods (705) are matched with the second sliding rods (804);

And the fifth springs (807) are arranged between the ejector rods (806) and the second supporting blocks (805), and the fifth springs (807) are sleeved on the ejector rods (806).

3. A holding fixture for solder wire winding production according to claim 2, characterized in that the drive assembly (9) comprises:

The third supporting block (901) is arranged in the middle of one side of the lower part in the shell (1);

The second distance sensor (902) is arranged on the other side of the top of the third supporting block (901);

a driving motor (903), wherein the driving motor (903) is arranged in the middle of the lower side of the inner part of the shell (1);

A fourth supporting block (905), wherein one side of the lower side of the inner part of the shell (1) is symmetrically provided with the fourth supporting block (905);

a second rotating shaft (906), wherein the second rotating shaft (906) is rotatably arranged between the inner sides of the fourth supporting blocks (905);

The middle part of the second rotating shaft (906) and the output shaft of the driving motor (903) are respectively provided with a first bevel gear (904), and the first bevel gears (904) are meshed with each other;

a fifth supporting block (909), wherein the other side of the upper part in the shell (1) is symmetrically provided with the fifth supporting block (909);

The shaft sleeve (910), the inner side of the fifth supporting block (909) is provided with the shaft sleeve (910) in a rotary mode;

A sliding shaft (911), wherein the sliding shafts (911) are arranged on the inner sides of the shaft sleeves (910) in a sliding manner, and the sliding shafts (911) are connected with the first rotating shaft (709);

the first transmission wheels (907) are arranged on the outer sides of the shaft sleeves (910), and the first transmission wheels (907) are arranged on the two sides of the second rotating shaft (906);

A first driving belt (908), wherein the first driving belt (908) is wound between the first driving wheels (907) at two sides;

And a sixth spring (912), wherein the sixth spring (912) is arranged between the sliding shaft (911) and the shaft sleeve (910).

4. A holding fixture for solder wire winding production according to claim 3, further comprising a guide assembly (10), the guide assembly (10) comprising:

a stepping motor (1001), wherein the stepping motor (1001) is arranged on one side, close to the driving motor (903), of the other side of the inside of the shell (1);

A sixth supporting block (1003), wherein the sixth supporting block (1003) is symmetrically arranged on the other side of the inner part of the shell (1);

a third rotating shaft (1004), wherein the third rotating shaft (1004) is rotatably arranged between the inner sides of the sixth supporting blocks (1003);

the middle part of the third rotating shaft (1004) and the output shaft of the stepping motor (1001) are respectively provided with a second bevel gear (1002), and the second bevel gears (1002) are meshed with each other;

The sliding chute barrel (1007) is symmetrically and rotatably arranged on the other side of the inner upper part of the shell (1);

The second driving wheels (1005) are arranged on the outer sides of the chute barrels (1007), and the second driving wheels (1005) are also arranged on the two sides of the third rotating shaft (1004);

the second driving belt (1006) is wound between the second driving wheels (1005) at two sides;

The second guide rod (1008) is symmetrically arranged on the other side of the upper part in the shell (1);

The third sliding rod (1009) is arranged between the inner sides of the second guide rods (1008) in a sliding mode, and the third sliding rod (1009) is in sliding fit with the chute barrel (1007);

And a guide cylinder (1010), wherein one side of the top of the third sliding rod (1009) is provided with the guide cylinder (1010).

5. The clamping and fixing device for solder wire winding production according to claim 4, further comprising a heat dissipation assembly (11), wherein the heat dissipation assembly (11) comprises:

The heat dissipation button (1101), be equipped with in the middle of one side of shell (1) inside heat dissipation button (1101), ejector pin (806) with heat dissipation button (1101) cooperation, heat dissipation button (1101) are located third supporting shoe (901) upside;

fixed block (1102), shell (1) inboard with all be equipped with between vent (2) fixed block (1102):

and the fans (1103) are arranged on the inner sides of the fixed blocks (1102) in a rotating mode.

6. The clamping and fixing device for solder wire winding production according to claim 5, further comprising a control box (3), wherein the control box (3) is arranged in the middle of one side of the shell (1), a switching power supply, a power supply module and a control module are arranged in the control box (3), the switching power supply supplies power to the device, an output end of the switching power supply is electrically connected with the power supply module, the power supply module is connected with a power supply main switch through a circuit, the power supply module is electrically connected with the control module, a DS1302 clock circuit and a 24C02 circuit are connected with the control module, the first distance sensor (701), the second distance sensor (902) and the heat dissipation button (1101) are electrically connected with the control module, and the electric push rod (703), the driving motor (903), the stepping motor (1001) and the fan (1103) are connected with the control module through peripheral circuits.