阅读说明：本技术 一种用于给螺母配螺丝的智能设备 (Intelligent device for matching screw with nut ) 是由 贾艳夏 于 2021-01-11 设计创作，主要内容包括：本发明公开的一种用于给螺母配螺丝的智能设备,本发明包括机体,所述机体中设有开口向上的生成空间,所述生成空间后壁左右对称的设有滑动空间,所述滑动空间下侧设有偏心滑盘空间,所述偏心滑盘空间左侧设有水箱,所述偏心滑盘空间右侧设有啮合空间,所述啮合空间上侧设有检测空间,所述检测空间右侧设有开口向下的选着空间,设备中设有生成装置可以根据不同的螺母生成不同螺栓,不用工作人员在去一个个的找适配螺栓,大大减少了工作人员的工作量,移动装置可以移动生成装置不用工作人员进行移动,大大提高了设备的效率。(The invention discloses intelligent equipment for matching screws with nuts, which comprises an equipment body, wherein a generating space with an upward opening is arranged in the equipment body, sliding spaces are symmetrically arranged on the left and right of the rear wall of the generating space, an eccentric sliding disc space is arranged on the lower side of the sliding space, a water tank is arranged on the left side of the eccentric sliding disc space, a meshing space is arranged on the right side of the eccentric sliding disc space, a detection space is arranged on the upper side of the meshing space, a selection space with a downward opening is arranged on the right side of the detection space, a generating device is arranged in the equipment and can generate different bolts according to different nuts, and workers do not need to find adaptive bolts one by one, so that the workload of the workers is greatly reduced, the generating device can be moved by a moving device without moving the workers, and the efficiency of the equipment is greatly improved.)

1. The utility model provides an intelligent equipment for being joined in marriage screw for nut, includes the organism, its characterized in that: the device comprises a machine body, wherein a generation space with an upward opening is arranged in the machine body, sliding spaces are symmetrically arranged on the left and right of the rear wall of the generation space, an eccentric sliding disc space is arranged on the lower side of the sliding space, a water tank is arranged on the left side of the eccentric sliding disc space, a meshing space is arranged on the right side of the eccentric sliding disc space, a detection space is arranged on the upper side of the meshing space, a selection space with a downward opening is arranged on the right side of the detection space, a bevel gear space is arranged on the upper side of the selection space, a generation device for generating temporary bolts according to nuts is arranged in the generation space, the generation device comprises large sliding rods fixedly arranged in each sliding space, an upper sliding block and a lower sliding block are respectively connected on each large sliding rod in a sliding mode, a pressure spring is respectively connected between each upper sliding block and each lower sliding, a movable nut box is fixedly connected to the two hinge rods, a fixed nut space with an upper opening and a lower opening is arranged in the movable nut box, a closing rack space is arranged on the right side of the fixed nut space, a right wall of the closing rack space is fixedly connected with an active motor, the left side of the active motor is in power connection with a left motor shaft which is rotatably connected with the right wall of the closing rack space, a driving main bevel gear is fixedly connected to the left motor shaft, a closing half-gear disc shaft is rotatably connected to the rear wall of the closing rack space, a driving auxiliary bevel gear and a closing half-gear disc are fixedly connected to the front side and the rear side of the closing half-gear disc shaft, the driving auxiliary bevel gear is meshed with the driving main bevel gear, a closing rack is slidably connected in the closing rack space, a pull-back spring is connected between the closing rack and the left wall of the closing rack space, and the closing, the right side surface of the source motor is dynamically connected with a right motor shaft which is rotationally connected with the left wall of the fixed nut space, a linkage main bevel gear is fixedly connected on the right motor shaft, a bevel gear shaft is rotationally connected between the upper wall and the lower wall of the fixed nut space, a linkage auxiliary bevel gear is fixedly connected on the bevel gear shaft, the linkage auxiliary bevel gear is meshed with the linkage main bevel gear, a movable abutting block is rotationally connected in the fixed nut space, the movable abutting block is a hollow toothed ring and can be meshed with the linkage auxiliary bevel gear, friction blocks are slidably connected in the movable abutting block in a bilateral symmetry manner, a micro spring is connected between each friction block and the movable abutting block, a fixed stable block is fixedly connected on the rear wall of the generated space, and a stable space with an upper opening and a lower opening is arranged in the middle of the fixed stable block, the device comprises a stable space, and is characterized in that a liquid guide pipe is arranged in the stable space, the left wall and the right wall of the stable space are bilaterally connected with stable sliding plates in a sliding manner, each stable sliding plate is respectively connected with a return spring between one side wall of the stable space, a deformation bolt is arranged in the stable space, a liquid communication pipe is arranged in the deformation bolt, a circle of soft deformation belt is arranged on the upper side of the deformation bolt, fixedly connected coolers which are bilaterally symmetrical on the left wall and the right wall of the generation space are provided with moving devices used for matching the generation devices between the generation space and the meshing space and the eccentric sliding disc space, a detection device used for detecting adaptive tooth plates is arranged in the detection space, a selection device used for selecting the tooth plates is arranged in the selection space, and a water supply device used for supplying water.

2. The smart device for screwing a nut as recited in claim 1, wherein: the moving device comprises a power motor fixedly installed on the right wall of the generation space, the left side surface of the power motor is in power connection with a power shaft which is rotatably connected with the left wall and the right wall of the generation space, a power sector gear is fixedly connected on the power shaft, a through shaft is rotatably connected in the generation space, pulling belt drum shafts are rotatably connected in the generation space in a bilateral symmetry manner, transmission main gears are fixedly connected on the left side and the right side of the through shaft in a bilateral symmetry manner, the transmission main gears can be meshed with the power sector gear, a transmission pinion and a pulling belt drum are fixedly connected on each pulling belt drum shaft, each transmission pinion is respectively meshed with the transmission main gear, a pulling belt is respectively connected between each pulling belt drum and the upper part and the lower part, and a transmission motor is fixedly connected on the bottom wall of the detection space, the bottom wall of the transmission motor is rotationally connected with a transmission motor, the bottom surface of the transmission motor is dynamically connected with a lower motor shaft which is rotationally connected with the top wall of the meshing space, a transmission main bevel gear is fixedly connected in the lower motor shaft, the left wall of the meshing space is rotationally connected with a transmission shaft, the transmission shaft extends rightwards to penetrate through the left wall of the meshing space to enter the eccentric sliding disc space, a driving bevel gear and a transmission auxiliary bevel gear are fixedly connected on the left side and the right side of the transmission shaft, the transmission auxiliary bevel gear is meshed with the transmission main bevel gear, the rear wall of the eccentric sliding disc space is rotationally connected with an eccentric sliding disc, the front side and the rear side of the eccentric sliding disc are fixedly connected with an eccentric sliding disc shaft and a driven bevel gear, the eccentric sliding disc shaft is meshed with the driving bevel gear, an eccentric moving rod is slidably connected in the eccentric sliding disc space, and, the eccentric moving rod extends upwards to penetrate through the top wall of the eccentric sliding disc space to enter the generating space, and the eccentric moving rod is fixedly connected with the fixed stabilizing block.

3. The smart device for screwing a nut as recited in claim 1, wherein: the detection device comprises a transmission motor top wall and an upper motor shaft which is connected with the bottom wall of the detection space in a rotating mode, a transmission main bevel gear is fixedly connected onto the upper motor shaft, a fan-shaped fluted disc shaft is connected onto the rear wall of the detection space in a rotating mode, a transmission auxiliary bevel gear and a fan-shaped fluted disc are fixedly connected onto the front side and the rear side of the fan-shaped fluted disc shaft, the transmission auxiliary bevel gear is meshed with the transmission main bevel gear, a detection rack is connected into the detection space in a sliding mode, the detection rack can be meshed with the fan-shaped fluted disc, a tension spring is connected between the detection rack and the right wall of the detection space, and a plurality of tooth plates are arranged.

4. The smart device for screwing a nut as recited in claim 1, wherein: the selection device comprises a power motor, a power motor right side face and a transmission shaft which is rotatably connected with a bevel gear space left wall, a rotary main bevel gear is fixedly connected to the transmission shaft, a linkage shaft is rotatably connected to the bottom wall of the bevel gear space, the linkage shaft extends downwards to penetrate through the bottom wall of the bevel gear space and enters the selected space, a rotary auxiliary bevel gear and a selection roller are fixedly connected to the upper side and the lower side of the linkage shaft, the rotary auxiliary bevel gear is meshed with the rotary main bevel gear, a suction block is slidably connected to the selection roller, a magnet is fixedly connected to the suction block, a taking-out selector is attracted to the suction block, a tooth plate placing rod is fixedly connected to the selected space, and a plurality of tooth plates are placed on the tooth plate placing rod.

5. The smart device for screwing a nut as recited in claim 1, wherein: the water supply device comprises a water pump fixedly mounted on the top wall of the water tank, and the water tank is communicated with a liquid pipe in the fixed stabilizing block.

Technical Field

The invention relates to the field of industry, in particular to intelligent equipment for screwing a nut.

Background

The threaded connection is a detachable fixed connection which is widely used, and has the advantages of simple structure, reliable connection, convenient assembly and disassembly and the like, but once a bolt matched with a nut is lost, the same trouble is found.

Disclosure of Invention

In order to solve the above problems, the present example designs an intelligent device for screwing nuts, the intelligent device for screwing nuts of the present example comprises a machine body, a generating space with an upward opening is arranged in the machine body, sliding spaces are symmetrically arranged on the left and right of the rear wall of the generating space, an eccentric sliding disc space is arranged on the lower side of the sliding space, a water tank is arranged on the left side of the eccentric sliding disc space, a meshing space is arranged on the right side of the eccentric sliding disc space, a detection space is arranged on the upper side of the meshing space, a selection space with a downward opening is arranged on the right side of the detection space, a bevel gear space is arranged on the upper side of the selection space, a generating device for generating temporary bolts according to nuts is arranged in the generating space, the generating device comprises large sliding rods fixedly arranged in each sliding space, and an upper sliding block and a lower sliding block are respectively connected on each large, a compression spring is connected between each upper sliding block and each lower sliding block and the bottom wall of the sliding space, each upper sliding block and each lower sliding block are respectively hinged with a hinge rod, a movable nut box is fixedly connected onto the two hinge rods, a fixed nut space with an upper opening and a lower opening is arranged in the movable nut box, a closing rack space is arranged on the right side of the fixed nut space, an active motor is fixedly connected onto the right wall of the closing rack space, the left side surface of the active motor is in power connection with a left motor shaft which is rotatably connected with the right wall of the closing rack space, a driving main bevel gear is fixedly connected onto the left motor shaft, a closing half-gear disc shaft is rotatably connected onto the rear wall of the closing rack space, a driving auxiliary bevel gear and a closing half-gear disc are fixedly connected onto the front side and the rear side of the closing half-gear disc shaft, the driving auxiliary bevel gear is meshed with, a pull-back spring is connected between the closing rack and the left wall of the closing rack space, the closing half fluted disc can be meshed with the closing rack, the right side surface of the source motor is in dynamic connection with a right motor shaft which is rotationally connected with the left wall of the fixing nut space, a linkage main bevel gear is fixedly connected on the right motor shaft, a bevel gear shaft is rotationally connected between the upper wall and the lower wall of the fixing nut space, a linkage auxiliary bevel gear is fixedly connected on the bevel gear shaft and meshed with the linkage main bevel gear, a movable abutting block is rotationally connected in the fixing nut space and is a hollow toothed ring, the movable abutting block can be meshed with the linkage auxiliary bevel gear, friction blocks are slidably connected in the movable abutting block in a bilateral symmetry manner, and a micro spring is connected between each friction block and the movable abutting block, the rear wall of the generating space is fixedly connected with a fixed stabilizing block, a stabilizing space with an upper opening and a lower opening is arranged in the middle of the fixed stabilizing block, a liquid guide pipe is arranged in the stabilizing space, stabilizing sliding plates are connected to the left wall and the right wall of the stabilizing space in a bilateral symmetry mode in a sliding mode, a return spring is connected between each stabilizing sliding plate and one side wall of the stabilizing space, a deformation bolt is arranged in the stabilizing space, a liquid communicating pipe is arranged in each deformation bolt, a circle of soft deformation belt is arranged on the upper side of each deformation bolt, coolers are fixedly connected to the left wall and the right wall of the generating space in a bilateral symmetry mode, moving devices used for matching the generating devices are arranged among the generating space, the meshing space and the eccentric sliding disc space, a detecting device used for detecting the adaptive tooth plates is arranged in the detecting space, and a selecting device used for selecting the tooth plates, and a water supply device for supplying water to the equipment is arranged in the water tank.

Preferably, the moving device comprises a power motor fixedly installed on the right wall of the generation space, the left side surface of the power motor is in power connection with a power shaft which is rotatably connected with the left wall and the right wall of the generation space, the power shaft is fixedly connected with a power sector gear, the generation space is rotatably connected with a through shaft, the generation space is bilaterally and rotatably connected with a pulling belt drum shaft, the left side and the right side of the through shaft are fixedly connected with a transmission main gear, the transmission main gear can be meshed with the power sector gear, each pulling belt drum shaft is fixedly connected with a transmission pinion and a pulling belt drum, each transmission pinion is respectively meshed with the transmission main gear, each pulling belt drum is respectively connected with a pulling belt between an upper sliding block and a lower sliding block, and the bottom wall of the detection space is fixedly connected with a transmission motor, the bottom wall of the transmission motor is rotationally connected with a transmission motor, the bottom surface of the transmission motor is dynamically connected with a lower motor shaft which is rotationally connected with the top wall of the meshing space, a transmission main bevel gear is fixedly connected in the lower motor shaft, the left wall of the meshing space is rotationally connected with a transmission shaft, the transmission shaft extends rightwards to penetrate through the left wall of the meshing space to enter the eccentric sliding disc space, a driving bevel gear and a transmission auxiliary bevel gear are fixedly connected on the left side and the right side of the transmission shaft, the transmission auxiliary bevel gear is meshed with the transmission main bevel gear, the rear wall of the eccentric sliding disc space is rotationally connected with an eccentric sliding disc, the front side and the rear side of the eccentric sliding disc are fixedly connected with an eccentric sliding disc shaft and a driven bevel gear, the eccentric sliding disc shaft is meshed with the driving bevel gear, an eccentric moving rod is slidably connected in the eccentric sliding disc space, and, the eccentric moving rod extends upwards to penetrate through the top wall of the eccentric sliding disc space to enter the generating space, and the eccentric moving rod is fixedly connected with the fixed stabilizing block.

Preferably, the detection device comprises an upper motor shaft, wherein the upper wall of the transmission motor is in power connection with the bottom wall of the detection space in a rotating mode, a transmission main bevel gear is fixedly connected onto the upper motor shaft, a fan-shaped fluted disc shaft is rotatably connected onto the rear wall of the detection space, a transmission auxiliary bevel gear and a fan-shaped fluted disc are fixedly connected onto the front side and the rear side of the fan-shaped fluted disc shaft, the transmission auxiliary bevel gear is meshed with the transmission main bevel gear, a detection rack is slidably connected into the detection space and can be meshed with the fan-shaped fluted disc, a tension spring is connected between the detection rack and the right wall of the detection space, and a plurality of tooth plates are arranged on the detection rack.

Preferably, the selection device comprises a transmission shaft which is arranged on the right side face of the power motor and is rotatably connected with the left wall of the bevel gear space, a rotary main bevel gear is fixedly connected to the transmission shaft, the bottom wall of the bevel gear space is rotatably connected with a linkage shaft, the linkage shaft extends downwards to penetrate through the bottom wall of the bevel gear space and enters the selected space, a rotary auxiliary bevel gear and a selection roller are fixedly connected to the upper side and the lower side of the linkage shaft, the rotary auxiliary bevel gear is meshed with the rotary main bevel gear, a suction sliding block is slidably connected to the selection roller, a magnet is fixedly connected to the suction sliding block, a take-out selector is attracted to the suction sliding block, a tooth plate placing rod is fixedly connected to the selected space, and a plurality of tooth plates are placed on the tooth plate placing rod.

Preferably, the water supply device comprises a water pump fixedly mounted on the top wall of the water tank, and the water tank is communicated with the liquid pipe in the fixed stabilizing block.

The invention has the beneficial effects that: the invention relates to intelligent equipment for matching screws with nuts, wherein a generating device is arranged in the equipment, different bolts can be generated according to different nuts, workers do not need to find the matched bolts one by one, the workload of the workers is greatly reduced, the generating device can be moved by a moving device without moving the workers, the efficiency of the equipment is greatly improved, a detection device can detect a matched tooth plate of the nut, and a selection device can select the matched tooth plate of the nut.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is an enlarged schematic view of A in FIG. 1;

FIG. 3 is an enlarged schematic view of B of FIG. 1;

fig. 4 is a schematic view of the structure of C-C in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to intelligent equipment for matching screws with nuts, which comprises an equipment body 21, wherein a generating space 22 with an upward opening is arranged in the equipment body 21, sliding spaces 24 are symmetrically arranged on the left and right of the rear wall of the generating space 22, an eccentric sliding disc space 45 is arranged on the lower side of the sliding space 24, a water tank 34 is arranged on the left side of the eccentric sliding disc space 45, a meshing space 48 is arranged on the right side of the eccentric sliding disc space 45, a detection space 63 is arranged on the upper side of the meshing space 48, a selection space 17 with a downward opening is arranged on the right side of the detection space 63, a bevel gear space 39 is arranged on the upper side of the selection space 17, a generating device for generating temporary bolts according to nuts is arranged in the generating space 22, the generating device comprises large sliding rods 25 fixedly arranged in each sliding space 24, and an upper sliding block and a lower sliding block 26 are respectively connected on each, a compression spring is connected between each up-down sliding block 26 and the bottom wall of the sliding space 24, each up-down sliding block 26 is hinged with a hinge rod 27, two hinge rods 27 are fixedly connected with a movable nut box 20, a fixed nut space 64 with an upper opening and a lower opening is arranged in the movable nut box 20, a closing rack space 66 is arranged on the right side of the fixed nut space 64, the right wall of the closing rack space 66 is fixedly connected with an active motor 72, the left side surface of the active motor 72 is in power connection with a left motor shaft 67 which is in rotary connection with the right wall of the closing rack space 66, a driving main bevel gear 68 is fixedly connected on the left motor shaft 67, a closing half-gear plate shaft 74 is in rotary connection with the rear wall of the closing rack space 66, driving auxiliary bevel gears 75 and a closing half-gear plate 76 are fixedly connected on the front and rear sides of the closing half-gear plate shaft 74, and the driving auxiliary bevel gears 75 are meshed with the, a closing rack 65 is connected in the closing rack space 66 in a sliding manner, a pull-back spring is connected between the closing rack 65 and the left wall of the closing rack space 66, the closing half-toothed disc 76 can be meshed with the closing rack 65, the right side surface of the source motor 72 is dynamically connected with a right motor shaft 71 which is rotatably connected with the left wall of the fixing nut space 64, a linkage main bevel gear 73 is fixedly connected on the right motor shaft 71, a bevel gear shaft 70 is rotatably connected between the upper wall and the lower wall of the fixing nut space 64, a linkage auxiliary bevel gear 69 is fixedly connected on the bevel gear shaft 70, the linkage auxiliary bevel gear 69 is meshed with the linkage main bevel gear 73, a movable abutting block 77 is rotatably connected in the fixing nut space 64, the movable abutting block 77 is a hollow toothed ring, and the movable abutting block 77 can be meshed with the linkage auxiliary bevel gear 69, the movable butting block 77 is provided with symmetrical friction blocks in a sliding manner, each friction block is connected with a micro spring between the movable butting block 77, the rear wall of the generation space 22 is fixedly connected with a fixed stabilizing block 78, a stabilizing space 80 with an upper opening and a lower opening is arranged in the middle of the fixed stabilizing block 78, a liquid guide pipe is arranged in the stabilizing space 80, the left wall and the right wall of the stabilizing space 80 are symmetrically provided with stable sliding plates 79 in a sliding manner, each stable sliding plate 79 is respectively connected with a return spring between one side wall of the stabilizing space 80, a deformation bolt 81 is arranged in the stabilizing space 80, a liquid communication pipe 82 is arranged in the deformation bolt 81, a circle of soft deformation belt is arranged on the upper side of the deformation bolt 81, the left wall and the right wall of the generation space 22 are symmetrically and fixedly connected with a cooler 23, the generation space 22, the meshing space 48, A moving device used for matching with a generating device is arranged between the eccentric sliding disc spaces 45, a detecting device used for detecting the adaptive tooth plates is arranged in the detecting space 63, a selecting device used for selecting the tooth plates is arranged in the bevel gear space 39 and the selecting space 17, and a water supply device used for supplying water to equipment is arranged in the water tank 34.

Advantageously, the moving device comprises a power motor 38 fixedly installed on the right wall of the generating space 22, a power shaft 36 rotatably connected between the right wall and the left wall of the generating space 22 is rotatably connected to the left side surface of the power motor 38, a power sector gear 35 is fixedly connected to the power shaft 36, a through shaft 29 is rotatably connected to the generating space 22, pulling belt drums 31 are rotatably connected to the generating space 22 in a left-right symmetrical manner, transmission main gears 28 are fixedly connected to the through shaft 29 in a left-right symmetrical manner, the transmission main gears 28 can be meshed with the power sector gear 35, a transmission pinion 30 and a pulling belt drum 32 are fixedly connected to each pulling belt drum 31, each transmission pinion 30 is respectively meshed with the transmission main gear 28, each pulling belt drum 32 is respectively connected to the upper and lower sliding blocks 26, the bottom wall of the detection space 63 is fixedly connected with a transmission motor 57, the bottom wall of the transmission motor 57 is rotatably connected with the transmission motor 57, the bottom surface of the transmission motor 57 is in power connection with a lower motor shaft 56 which is rotatably connected with the top wall of the engagement space 48, a transmission main bevel gear 50 is fixedly connected in the lower motor shaft 56, the left wall of the engagement space 48 is rotatably connected with a transmission shaft 47, the transmission shaft 47 extends rightwards to penetrate through the left wall of the engagement space 48 to enter the eccentric sliding disk space 45, the left side and the right side of the transmission shaft 47 are fixedly connected with a driving bevel gear 84 and a transmission auxiliary bevel gear 49, the transmission auxiliary bevel gear 49 is meshed with the transmission main bevel gear 50, the rear wall of the eccentric sliding disk space 45 is rotatably connected with an eccentric sliding disk 46, the front side and the rear side of the eccentric sliding disk 46 are fixedly connected with an eccentric sliding disk shaft 44 and a driven bevel gear, an eccentric moving rod 55 is connected in the eccentric sliding disk space 45 in a sliding manner, the eccentric moving rod 55 is connected with the eccentric sliding disk 46 in a sliding manner, the eccentric moving rod 55 extends upwards to penetrate through the top wall of the eccentric sliding disk space 45 to enter the generating space 22, and the eccentric moving rod 55 is fixedly connected with the fixed stabilizing block 78.

Advantageously, the detecting device comprises an upper motor shaft 58 which is mounted on the top wall of the transmission motor 57 and is rotatably connected with the bottom wall of the detecting space 63, a transmission main bevel gear 59 is fixedly connected to the upper motor shaft 58, a sector-shaped gear plate shaft 60 is rotatably connected to the rear wall of the detecting space 63, a transmission auxiliary bevel gear 61 and a sector-shaped gear plate 62 are fixedly connected to the front and rear sides of the sector-shaped gear plate shaft 60, the transmission auxiliary bevel gear 61 is meshed with the transmission main bevel gear 59, a detecting rack 43 is slidably connected in the detecting space 63, the detecting rack 43 can be meshed with the sector-shaped gear plate 62, a tension spring is connected between the detecting rack 43 and the right wall of the detecting space 63, and a plurality of tooth plates are arranged on the detecting rack 43.

Advantageously, the selection means comprise a step-rotating shaft 16, which is power-mounted on the right side of the power motor 38 and is rotatably connected to the left wall of the bevel gear space 39, a rotary main bevel gear 40 is fixedly connected on the transmission shaft 16, a linkage shaft 42 is rotatably connected on the bottom wall of the bevel gear space 39, the linkage shaft 42 extends downward through the bottom wall of the bevel gear space 39 into the selection space 17, the upper side and the lower side of the linkage shaft 42 are fixedly connected with a rotary bevel pinion 41 and a selection roller 51, the rotary sub bevel gear 41 is engaged with the rotary main bevel gear 40, the selection cylinder 51 has a suction slider 19 slidably connected therein, a magnet is fixedly connected in the suction slider 19, a take-out selector 53 is sucked on the suction slider 19, a dental plate placing rod 52 is fixedly connected in the selected space 17, and a plurality of dental plates are placed on the dental plate placing rod 52.

Advantageously, the water supply means comprises a water pump 33 fixedly mounted on the top wall of the water tank 34, the water tank 34 communicating with a liquid pipe in the stationary stabilizing block 78.

The use steps herein are described in detail below with reference to fig. 1-4:

in the initial state, the traveling nut case 20 is positioned above the generation space 22, the deformed bolt 81 is positioned below the generation space 22, the extraction selector 53 is positioned above the selection space 17, and the detection rack 43 is positioned on the right side of the detection space 63.

When it is desired to produce a mating bolt, the nut is placed in the fixed nut space 64, the linked main bevel gear 73 is reversely actuated, so that the left motor shaft 67 is rotated, so that the driven main bevel gear 68 is rotated, so that the driven auxiliary bevel gear 75 is rotated, so that the closed half-toothed disc 76 is rotated, so that the closed rack 65 is moved leftward, so that the fixed nut space 64 is closed, so that the nut is abutted against the two friction blocks, the power motor 38 is reversely actuated, so that the power shaft 36 is rotated, so that the power sector gear 35 is rotated, so that the left transmission main gear 28 is rotated, so that the penetrating shaft 29 is rotated, so that the right transmission main gear 28 is rotated, so that the two transmission auxiliary gears 30 are rotated, so that the two pull belt drum shafts 31 are rotated, so that the two pull belt drums 32 are rotated, so that the movable nut box 20 is moved downward, the transmission motor 57 is reversely actuated to rotate the lower motor shaft 56 to rotate the step main bevel gear 50 to rotate the step sub bevel gear 49 to rotate the transmission shaft 47 to rotate the drive bevel gear 84 to rotate the driven bevel gear 83 to rotate the eccentric slide 46 to rotate the eccentric slide shaft 44 to rotate the eccentric slide 55 to move the eccentric slide rod 55 upward to insert the deformed bolt 81 into the fixed stable block 78 to be clamped by the two stable slides 79 to communicate the communicating liquid pipe 82 with the liquid pipe in the fixed stable block 78 to sleeve the nut to the deformed bolt 81, the water pump 33 is actuated to enter the water in the water tank 34 into the communicating liquid pipe 82 to change the soft deformed belt into a threaded shape, the two coolers 23 are actuated to solidify the water in the communicating liquid pipe 82 into a threaded shape, the source motor 72 is forwardly actuated so that the right motor shaft 71 is rotated, so that the linkage main bevel gear 73 is rotated, so that the linkage sub bevel gear 69 is rotated, so that the bevel gear shaft 70 is rotated, so that the moving abutment block 77 is rotated, the cooperation transmission motor 57 is reversely actuated again, so that the communication liquid pipe 82 with the screw thread is downwardly moved, the transmission motor 57 is forwardly actuated, so that the upper motor shaft 58 is rotated, so that the transmission main bevel gear 59 is rotated, so that the transmission sub bevel gear 61 is rotated, so that the sector-shaped toothed disc 62 is rotated, so that the detection rack 43 is leftwardly moved by one tooth plate of the detection adaptation, the power motor 38 is forwardly actuated, so that the pipetting slide 19 takes out the tooth plate of the adaptation, thereby tapping the bolt without the screw thread.

The invention has the beneficial effects that: the invention relates to intelligent equipment for matching screws with nuts, wherein a generating device is arranged in the equipment, different bolts can be generated according to different nuts, workers do not need to find the matched bolts one by one, the workload of the workers is greatly reduced, the generating device can be moved by a moving device without moving the workers, the efficiency of the equipment is greatly improved, a detection device can detect a matched tooth plate of the nut, and a selection device can select the matched tooth plate of the nut.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.