CN112021080A - Tilia amurensis drilling equipment for agricultural production - Google Patents

Abstract

The invention relates to drilling equipment, in particular to tilia amurensis drilling equipment for agricultural production. The tilia amurensis drilling equipment for agricultural production is provided, which can make people feel easier. A linden drilling device for agricultural production comprises a bottom plate, wherein a servo motor is arranged on the upper side of the bottom plate; the support, bottom plate top both sides all rigid coupling have support and guide arm, and the guide arm of both sides is located between the support of both sides. According to the invention, the tilia can be fixed through the moving assembly, and the drilling assembly can drill holes on the tilia, so that manual operation is greatly reduced, and people can feel easier; the tilia can be pushed to rotate by 45 degrees through the special-shaped rod, so that people do not need to manually rotate the tilia, and the working efficiency can be improved; the sliding frame can be attracted by the magnets, the placing plates on the right side cannot rotate easily, and people can place the tilia amurensis into the two placing plates conveniently.

Description

Tilia amurensis drilling equipment for agricultural production

Technical Field

The invention relates to drilling equipment, in particular to tilia amurensis drilling equipment for agricultural production.

Background

The agricultural production refers to the production activities for planting crops, including the production of crops such as grains, cotton, oil, tea, sugar, vegetables and fruits, wherein the agaric has high nutritive value and fine taste, and is one of favorite foods, so people can plant some agarics, and holes need to be drilled on tilia amurensis when planting the agaric.

At present generally people are with holding tilia amurensis, then control the puncher with the foot and carry out the drilling to tilia amurensis, after having bored a hole, people rotate tilia amurensis again, punch to another department, at the drilling in-process, people need tightly hold tilia amurensis, still need control the puncher with the foot, once only can bore a hole in addition, greatly increased people's intensity of labour, lead to people fatigue very.

The device which can make people feel easier is designed to solve the existing problems.

Disclosure of Invention

In order to overcome the defects that people need to tightly hold a basswood and need to control the punching machine by feet, the labor intensity of people is greatly increased, and people are tired, the technical problem of the invention is as follows: the tilia amurensis drilling equipment for agricultural production is provided, which can make people feel easier.

The technical scheme is as follows: a linden drilling device for agricultural production comprises a bottom plate, wherein a servo motor is arranged on the upper side of the bottom plate; the guide rods on the two sides are positioned between the brackets on the two sides; the mounting frame is fixedly connected between the brackets on the two sides, and the guide rod penetrates through the mounting frame; the drilling assembly is arranged on the mounting frame and used for drilling a linden; the moving assembly is installed on the guide rod and used for moving the tilia amurensis to the drilling assembly.

Further, the drilling assembly comprises spline shafts, and at least four spline shafts are rotatably arranged on the outer side of the mounting frame at uniform intervals; the movable rod is connected to the upper part of the mounting frame in a sliding and penetrating manner, and the return spring is connected between the mounting frame and the movable rod; each spline shaft is sleeved with a sleeve in a sliding manner, the inner end of each sleeve is provided with a drill bit, each sleeve is fixedly sleeved with a bearing, and one bearing is fixedly connected with the movable rod; the outer ends of the spline shafts are provided with first bevel gears; the outer side of the mounting frame is rotatably provided with at least four rotating shafts at uniform intervals; each rotating shaft is fixedly sleeved with a second bevel gear which is meshed with the first bevel gear; each rotating shaft is fixedly sleeved with a first driving wheel, and a belt is wound between the first driving wheels; the second driving wheel is fixedly sleeved on an output shaft of the servo motor, the rotating frame is arranged on the second driving wheel, and the rotating frame is in contact with the movable rod; the gearbox is arranged on one side, close to the servo motor, of the bottom plate, connected with an output shaft of the servo motor and fixedly connected with one rotating shaft; the special-shaped frame is arranged on the bearing in a sliding manner; the upper parts of the brackets on the two sides are provided with supporting wheels which are used for supporting the rotating frame; the number of the push blocks is at least two, and the push blocks are fixedly connected to the inner wall of the rotating frame.

Further explaining, the moving assembly comprises a first support frame, and the first support frame and the second support frame are sleeved on the guide rod in a sliding manner; the number of the connecting rods is at least two, and the connecting rods are fixedly connected between the first supporting frame and the second supporting frame; the movable block is sleeved on the connecting rod in a sliding manner; the first spring is wound between the first support frame and the movable block; the movable block is rotatably provided with a placing disc, and the second supporting frame is also rotatably provided with a placing disc; the torsion spring is arranged at the joint of the second support frame and the placing disc; the push rod is fixedly connected to the first support frame; the pull rod is fixedly connected to the movable block.

Further explaining, the special-shaped rod is further included, the special-shaped rod is connected to the second supporting frame in a penetrating mode in a sliding mode, the sliding groove is formed in the placing disc close to the special-shaped rod, and the sliding groove is matched with the special-shaped rod in a sliding mode; the first wedge block is fixedly connected to one side, facing the special-shaped rod, of the rotating frame; the supporting sleeve is arranged on one side, close to the servo motor, of the bottom plate; the contact rod is slidably penetrated in the support sleeve, and the rotating frame is contacted with the contact rod; the second wedge-shaped block is arranged on the upper side of the support sleeve in a sliding mode, and the contact rod and the special-shaped rod are in contact with the second wedge-shaped block; the second spring is sleeved on the contact rod, one end of the second spring is connected with the contact rod, and the other end of the second spring is connected with the supporting sleeve.

Further explaining, the device also comprises a sliding frame, wherein the sliding frame is connected to the upper part of the first supporting frame in a sliding way; the third spring is sleeved on the sliding frame, one end of the third spring is connected with the sliding frame, and the other end of the third spring is connected with the first support frame; the magnet, magnet embedded installation is on being close to the placing plate of carriage.

The invention has the beneficial effects that:

1. can be fixed with tilia amurensis through removing the subassembly, the drilling subassembly can be drilled tilia amurensis, and the manual operation that has significantly reduced for people can be light more.

2. Can promote tilia amurensis through the dysmorphism pole and rotate 45 degrees, just so need not people manual rotation tilia amurensis to can improve work efficiency.

3. The sliding frame can be attracted by the magnets, the placing plates on the right side cannot rotate easily, and people can place the tilia amurensis into the two placing plates conveniently.

Drawings

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

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

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

FIG. 4 is a schematic diagram of a first partial structure according to the present invention.

Fig. 5 is an enlarged view of a portion a of the present invention.

FIG. 6 is a second partial structure of the present invention.

Reference numbers in the drawings: 1-a bottom plate, 2-a servo motor, 3-a bracket, 4-a mounting frame, 5-a drilling assembly, 501-a spline shaft, 502-a movable rod, 503-a bearing, 504-a sleeve, 505-a first bevel gear, 506-a rotating shaft, 507-a second bevel gear, 508-a first transmission wheel, 509-a rotating frame, 510-a belt, 511-a second transmission wheel, 512-a gearbox, 513-a special frame, 514-a drill bit, 515-a supporting wheel, 516-a return spring, 517-a push block, 6-a guide rod, 7-a moving assembly, 701-a first supporting frame, 702-a second supporting frame, 703-a connecting rod, 704-a movable block, 705-a first spring, 706-a placing disc, 707-a torsion spring, 709 push rod, 710 pull rod, 8 special rod, 9 sliding chute, 10 first wedge block, 11 supporting sleeve, 12 contact rod, 13 second wedge block, 14 second spring, 15 sliding frame, 16 third spring and 17 magnet.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Example 1

A tilia amurensis drilling device for agricultural production is shown in attached figures 1-6 and comprises a bottom plate 1, a servo motor 2, a support 3, an installation frame 4, a drilling assembly 5, guide rods 6 and a moving assembly 7, wherein the servo motor 2 is installed in the middle of the top of the bottom plate 1 through bolts, the support 3 and the guide rods 6 are installed on the front side and the rear side of the top of the bottom plate 1, the two guide rods 6 are located between the two supports 3, the installation frame 4 which is circular in shape is connected between the two supports 3, the two guide rods 6 penetrate through the installation frame 4, the drilling assembly 5 is installed on the installation frame 4, and the moving assembly 7 is installed on the guide rods 6.

When needs are driped a hole to tilia amurensis, people fix tilia amurensis on removing subassembly 7, then start servo motor 2 work, servo motor 2 drive drilling subassembly 5 work, drilling subassembly 5 is driped a hole to tilia amurensis, after having bored the hole, people close servo motor 2, then control and remove subassembly 7 and remove tilia amurensis, drill another department to tilia amurensis, people start servo motor 2 work once more, continue to bore tilia amurensis, so relapse, can drill a hole to whole tilia amurensis, it can be fixed with tilia amurensis to remove subassembly 7, drilling subassembly 5 can be driped a hole to tilia amurensis, the manual operation that has significantly reduced, make the relaxation that people can be more. After the whole tilia amurensis is drilled with holes, people take down the tilia amurensis drilled with holes.

The drilling assembly 5 comprises spline shafts 501, movable rods 502, bearings 503, sleeves 504, first bevel gears 505, rotating shafts 506, second bevel gears 507, first driving wheels 508, rotating frames 509, belts 510, second driving wheels 511, gearboxes 512, special-shaped frames 513, drills 514, supporting wheels 515, return springs 516 and push blocks 517, wherein four spline shafts 501 are rotatably installed on the outer side of the installation frame 4 at uniform intervals, the movable rods 502 are slidably arranged on the upper portion of the left side of the installation frame 4 through sliding sleeves, the return springs 516 are connected between the movable rods 502 and the installation frame 4, each spline shaft 501 is slidably provided with a sleeve 504, the drills 514 are installed at the inner ends of the sleeves 504, the bearings 503 are installed on the outer sides of the sleeves 504, the bearings 503 above are connected with the movable rods 502, the first bevel gears 505 are installed at the outer ends of the spline shafts 501, the four rotating shafts 506 are rotatably installed on the outer side of the installation frame, every pivot 506 is equipped with second bevel gear 507 and first drive wheel 508, four second bevel gears 507 mesh with four first bevel gears 505 respectively, around having belt 510 between four first drive wheels 508, install second drive wheel 511 on the output shaft of servo motor 2, be equipped with revolving frame 509 on the second drive wheel 511, revolving frame 509 and movable rod 502 contact, supporting wheel 515 is all installed on two supports 3 outside upper portions, two supporting wheel 515 all contact with revolving frame 509, both sides all are connected with ejector pad 517 about in the revolving frame 509, install gearbox 512 through the bolt in the middle of bottom plate 1 top, gearbox 512 is located servo motor 2 left side, gearbox 512 input and servo motor 2's output shaft are connected, gearbox 512 output is connected with the pivot 506 of below, four bearings 503 right sides slidingtype are equipped with special-shaped frame 513.

When the servo motor 2 is started to work, the servo motor 2 drives the lower rotating shaft 506 to rotate through the gearbox 512, so as to drive the lower first driving wheel 508 to rotate, drives the other three first driving wheels 508 to rotate through the belt 510, so as to drive the other three rotating shafts 506 to rotate, drives the spline shaft 501 to rotate through the first bevel gear 505 and the second bevel gear 507, so as to drive the sleeve 504 to rotate, the drill bit 514 rotates along with the first driving wheel, the servo motor 2 can also drive the second driving wheel 511 to rotate, the second driving wheel 511 drives the rotating frame 509 to rotate, the rotating frame 509 drives the push block 517 to rotate, when the push block 517 contacts the movable rod 502 in a rotating way, the push block 517 pushes the movable rod 502 to move downwards, the reset spring 516 is stretched, the movable rod 502 drives the upper bearing 503 to move downwards, drives the other three bearings 503 to move inwards through the special-shaped frame 513, so as to, the sleeve 504 slides on the spline shaft 501, so the sleeve 504 can still rotate, the sleeve 504 drives the drill bit 514 to move inwards to drill a bore hole in a linden tree, when the push block 517 rotates and is not in contact with the movable rod 502, the movable rod 502 resets upwards under the action of the reset spring 516, the movable rod 502 drives the bearing 503 above to reset upwards, the other three bearings 503 are driven to reset outwards through the special-shaped frame 513, the drill bit 514 resets outwards along with the reset, and people can turn off the servo motor 2.

The moving assembly 7 comprises a first supporting frame 701, a second supporting frame 702, a connecting rod 703, a movable block 704, a first spring 705, a placing plate 706, a torsion spring 707, a push rod 709 and a pull rod 710, wherein the first supporting frame 701 and the second supporting frame 702 are arranged on two guide rods 6 in a sliding manner, the first supporting frame 701 is positioned at the right side of the second supporting frame 702, the two connecting rods 703 are connected between the first supporting frame 701 and the second supporting frame 702, the movable block 704 is arranged on the two connecting rods 703 in a sliding manner, the first spring 705 is connected between the first supporting frame 701 and the movable block 704, the first spring 705 is sleeved on the connecting rod 703, the placing plate 706 is arranged on the movable block 704 in a rotating manner, the placing plate 706 is also arranged on the second supporting frame 702 in a rotating manner, the torsion spring 707 is arranged at the joint of the second supporting frame 702 and the placing plate 706 on the left side, the push rod, the lower right side of the movable block 704 is connected with a pull rod 710.

People pull the pull rod 710 rightwards, the pull rod 710 drives the movable block 704 to move rightwards, the first spring 705 is compressed, the movable block 704 moves rightwards to drive the right placing plates 706 to move rightwards, then people place tilia timpani into the two placing plates 706, then the pull rod 710 is loosened, the movable block 704 moves leftwards under the action of the first spring 705, the movable block 704 drives the right placing plates 706 to move leftwards to clamp the tilia timpani, people start the servo motor 2 to work again to drill the tilia, after the holes are drilled, people close the servo motor 2, rotate the tilia 45 degrees, the tilia drives the placing plates 706 to rotate 45 degrees, the torsion spring 707 is twisted, then people start the servo motor 2 again to work to continue to drill the tilia bore, after the holes are drilled, people close the servo motor 2, then loosen the tilia, under the action of the torsion spring 707, the left placing plates 706 rotate to reset, the tilia amurensis rotates in the opposite direction to reset, people push the push rod 709 leftwards, the push rod 709 drives the first support frame 701 to move leftwards, the movable block 704 is driven to move leftwards through the connecting rod 703, the placing plate 706 on the right side is driven to move leftwards, the tilia amurensis moves leftwards along with the moving plate, after the tilia amurensis moves leftwards for a certain distance, people stop pushing the push rod 709, then the servo motor 2 is started again to work, drilling is continuously performed on the tilia amurensis, and the steps are repeated, so that the whole tilia amurensis can be. After the whole tilia is drilled with holes, people pull the push rod 709 rightwards, the push rod 709 drives the tilia to move rightwards, the tilia is moved to the initial position, and then the tilia is taken down.

Example 2

On the basis of embodiment 1, as shown in fig. 1, 4, 5 and 6, the portable electronic device further includes a special-shaped rod 8, a first wedge 10, a support sleeve 11, a contact rod 12, a second wedge 13 and a second spring 14, the special-shaped rod 8 is slidably disposed on the left side of the second support frame 702 through a sliding sleeve, a sliding slot 9 is formed on the left side of the placement tray 706 on the left side, the sliding slot 9 is slidably engaged with the special-shaped rod 8, the first wedge 10 is connected to the upper left side of the rotating frame 509, the support sleeve 11 is connected to the middle of the top of the bottom plate 1, the support sleeve 11 is located on the left side of the transmission case 512, the contact rod 12 is slidably disposed in the support sleeve 11, the rotating frame 509 is in contact with the contact rod 12, the second spring 14 is sleeved on the contact rod 12, the left end of the second spring 14 is connected to the contact rod 12, the right end of the second spring 14 is connected to the support, both the contact bar 12 and the profiled bar 8 are in contact with a second wedge block 13.

When revolving frame 509 rotates, revolving frame 509 drives second wedge 13 and rotates, when second wedge 13 rotates and touches contact bar 12, second wedge 13 promotes contact bar 12 and moves left, second spring 14 is stretched, contact bar 12 promotes second wedge 13 rebound, second wedge 13 promotes special-shaped rod 8 rebound, special-shaped rod 8 drives left dish 706 of placing through spout 9 and rotates 45 degrees, left dish 706 of placing drives linden and rotates 45 degrees, torsion spring 707 is twisted up, at this moment, ejector pad 517 just touches movable rod 502, ejector pad 517 promotes drill bit 514 rebound, bore linden, just so do not need people manual rotation linden, thereby can improve work efficiency. When the second wedge-shaped block 13 is not in contact with the contact rod 12, the contact rod 12 is reset rightwards under the action of the second spring 14, the second wedge-shaped block 13 is reset downwards under the action of self gravity, the placing disc 706 on the left side rotates in the opposite direction to be reset under the action of the torsion spring 707, and the special-shaped rod 8 is driven to reset downwards through the sliding groove 9.

The upper portion of the first support frame 701 is provided with the sliding frame 15 in a sliding mode through a sliding hole, the sliding frame 15 is sleeved with the third spring 16, the left end of the third spring 16 is connected with the sliding frame 15, the right end of the third spring 16 is connected with the first support frame 701, and the magnets 17 are installed on the front portion and the rear portion of the placement disc 706 on the right side in an embedded mode.

People pull the pull rod 710 rightwards, the pull rod 710 drives the movable block 704 to move rightwards, the first spring 705 is compressed, the movable block 704 moves rightwards to drive the right placing plate 706 to move rightwards, the magnet 17 is driven to move rightwards, when the magnet 17 moves rightwards to touch the sliding frame 15, the magnet 17 is adsorbed on the sliding frame 15, the right placing plate 706 cannot easily rotate, people can place tilia amurensis bassiana into the two placing plates 706 conveniently, people continue to pull the pull rod 710 rightwards, the magnet 17 continues to move rightwards, the magnet 17 pushes the sliding frame 15 to move rightwards, the third spring 16 is compressed, and therefore the device is suitable for placing tilia amurensis bass. When one releases the pull rod 710, the carriage 15 will return to the left under the influence of the third spring 16.

It should be understood that this example is only for illustrating the present invention and is not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and such equivalents may fall within the scope of the present invention as defined in the appended claims.

Claims (5)

1. A linden drilling equipment for agricultural production is characterized by comprising:

the servo motor is arranged on the upper side of the bottom plate;

the guide rods on the two sides are positioned between the brackets on the two sides;

the mounting frame is fixedly connected between the brackets on the two sides, and the guide rod penetrates through the mounting frame;

the drilling assembly is arranged on the mounting frame and used for drilling a linden;

the moving assembly is installed on the guide rod and used for moving the tilia amurensis to the drilling assembly.

2. The apparatus for drilling linden wood for agricultural production according to claim 1, wherein the drilling assembly comprises:

at least four spline shafts are rotatably arranged on the outer side of the mounting frame at uniform intervals;

the movable rod is connected to the upper part of the mounting frame in a sliding and penetrating manner, and the return spring is connected between the mounting frame and the movable rod;

each spline shaft is sleeved with a sleeve in a sliding manner, the inner end of each sleeve is provided with a drill bit, each sleeve is fixedly sleeved with a bearing, and one bearing is fixedly connected with the movable rod;

the outer ends of the spline shafts are provided with first bevel gears;

the outer side of the mounting frame is rotatably provided with at least four rotating shafts at uniform intervals;

each rotating shaft is fixedly sleeved with a second bevel gear which is meshed with the first bevel gear;

each rotating shaft is fixedly sleeved with a first driving wheel, and a belt is wound between the first driving wheels;

the second driving wheel is fixedly sleeved on an output shaft of the servo motor, the rotating frame is arranged on the second driving wheel, and the rotating frame is in contact with the movable rod;

the gearbox is arranged on one side, close to the servo motor, of the bottom plate, connected with an output shaft of the servo motor and fixedly connected with one rotating shaft;

the special-shaped frame is arranged on the bearing in a sliding manner;

the upper parts of the brackets on the two sides are provided with supporting wheels which are used for supporting the rotating frame;

the number of the push blocks is at least two, and the push blocks are fixedly connected to the inner wall of the rotating frame.

3. The apparatus for drilling linden wood for agricultural production as claimed in claim 2, wherein the moving assembly comprises:

the first support frame and the second support frame are sleeved on the guide rod in a sliding mode;

the number of the connecting rods is at least two, and the connecting rods are fixedly connected between the first supporting frame and the second supporting frame;

the movable block is sleeved on the connecting rod in a sliding manner;

the first spring is wound between the first support frame and the movable block;

the movable block is rotatably provided with a placing disc, and the second supporting frame is also rotatably provided with a placing disc;

the torsion spring is arranged at the joint of the second support frame and the placing disc;

the push rod is fixedly connected to the first support frame;

the pull rod is fixedly connected to the movable block.

4. The apparatus for drilling Tilia amurensis for agricultural production according to claim 3, further comprising:

the special-shaped rod is connected to the second supporting frame in a sliding and penetrating mode, the sliding groove is formed in the placing disc close to the special-shaped rod, and the sliding groove is matched with the special-shaped rod in a sliding mode;

the first wedge block is fixedly connected to one side, facing the special-shaped rod, of the rotating frame;

the supporting sleeve is arranged on one side, close to the servo motor, of the bottom plate;

the contact rod is slidably penetrated in the support sleeve, and the rotating frame is contacted with the contact rod;

the second wedge-shaped block is arranged on the upper side of the support sleeve in a sliding mode, and the contact rod and the special-shaped rod are in contact with the second wedge-shaped block;

the second spring is sleeved on the contact rod, one end of the second spring is connected with the contact rod, and the other end of the second spring is connected with the supporting sleeve.

5. The apparatus for drilling Tilia amurensis for agricultural production according to claim 4, further comprising:

the sliding frame is connected to the upper part of the first support frame in a sliding mode;

the third spring is sleeved on the sliding frame, one end of the third spring is connected with the sliding frame, and the other end of the third spring is connected with the first support frame;

the magnet, magnet embedded installation is on being close to the placing plate of carriage.

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