CN111183814B - Automatic iron wire winding plastic equipment of pine seedling - Google Patents

Abstract

The invention relates to garden seedling maintenance, in particular to automatic iron wire winding shaping equipment for pine seedlings. The invention provides a shaping device for automatically winding iron wires on pine saplings, which does not need too much manual participation, does not scratch hands and has high automation degree. An automatic iron wire winding shaping device for pine seedlings comprises a pushing frame, a supporting frame, a fixing plate, a speed reducing motor, a first bearing seat, a first rotating rod, a belt transmission assembly, a rotating disk, a placing rod, a lifting device and the like; the cart frame upside is connected with the support frame, the support frame upside is connected with the fixed plate, be connected with gear motor on the fixed plate. According to the invention, the rotating disc is adopted to rotate to drive the iron wires to move upwards through the guide sleeve, so that the iron wires are wound on the saplings upwards, the iron wires can be automatically wound on the saplings from bottom to top, the automation can be improved, and the working efficiency is improved.

Description

Automatic iron wire winding plastic equipment of pine seedling

Technical Field

The invention relates to garden seedling maintenance, in particular to automatic iron wire winding shaping equipment for pine seedlings.

Background

In the aspect of gardens sapling maintenance, for guaranteeing the correct growth of sapling, generally need be at its root winding iron wire, make its correct growth, but carry out the iron wire winding to the sapling at present and all adopt the manual work to go on, need artifical handheld iron wire to start upwards winding from the root, adopt artificial mode can not be quick to handle a large amount of saplings, efficiency is very low down, and at the in-process of winding iron wire, still make iron wire fish tail staff easily, whole iron wire twines to walk around journey automation degree low, it is very many to need artificial place.

In view of the above disadvantages, there is a need to design a pine seedling automatic iron wire winding shaping device which does not require too much manual participation, does not scratch hands, has high automation degree, and overcomes the disadvantages of low manual participation efficiency, easy iron wire scratching hands, and low automation degree.

Disclosure of Invention

In order to overcome the defects of low efficiency, easy scratch of iron wires on hands and low automation degree of manual participation at present, the invention has the technical problems that: the automatic iron wire winding shaping equipment for the pine saplings is high in automation degree, and does not need manual participation to be excessive.

The technical implementation scheme of the invention is as follows: an automatic iron wire winding shaping device for pine seedlings comprises a cart frame, a support frame, a fixing plate, a speed reducing motor, a first bearing seat, a first rotating rod, a belt transmission assembly, a rotating disc, a placing rod, a lifting device, a limiting device and a transmission device, wherein the support frame is connected to the upper side of the cart frame, the fixing plate is connected to the upper side of the support frame, the speed reducing motor is connected to the fixing plate, the first bearing seat is connected to the left side in the fixing plate, the first rotating rod is connected to the first bearing seat, the belt transmission assembly is connected between the first rotating rod and the speed reducing motor, the rotating disc is connected to the lower side of the first rotating rod, a through hole is formed in the middle of the rotating disc, the placing rod is connected to the rotating disc, the lifting device is arranged on the rotating disc, the limiting device is arranged on the lower side of the rotating disc, and is matched with the lifting device, and a transmission device is arranged on one side of the support frame close to the rotating disc and matched with the rotating disc and the lifting device.

In a preferred embodiment of the present invention, the ascending device includes a first guide sleeve, a first guide rail, a first fixture block, a rack, a guide sleeve, and a guide wheel, the first guide sleeve is connected to the inside of one side of the rotating disc near the support frame, the first guide rail is connected to the inside of the first guide sleeve in a sliding manner, the first guide rail has a structure with a groove at the bottom, the first fixture block is connected to one side of the lower side of the first guide rail away from the support frame, the first fixture block is matched with the limiting device, the rack is connected to one side of the lower side of the first guide rail near the support frame, the rack is matched with the transmission device, the guide sleeve is connected to one side of the lower side of the first guide rail away from the first fixture block, and the guide wheel is arranged in the guide sleeve.

In a preferred embodiment of the present invention, the limiting device includes a second guide sleeve, a second guide rail, a first elastic element, a connecting rod, and a second clamping block, the second guide sleeve is connected to a side of the lower side of the rotating disc away from the supporting frame, the second guide sleeve is connected to the second elastic element in a sliding manner, the first elastic element is connected between the second guide rail and the second guide sleeve, the connecting rod is connected to a side of the second guide rail close to the first guide rail, the second clamping block is connected to a side of the connecting rod close to the first clamping block, and the second clamping block is matched with the first clamping block.

In a preferred embodiment of the present invention, the transmission device includes a connecting frame, a second bearing seat, a second rotating rod, a bevel gear, a bevel block, a rotating shaft, a circular gear and a gear transmission assembly, the connecting frame is connected to a side of the supporting frame near the rack, the second bearing seat is connected to a side of the connecting frame near the rack, the second rotating rod is connected to the second bearing seat, the bevel gear is connected to an upper side of the second rotating rod, the bevel block is connected to a side of the rotating disc near the bevel gear, the bevel gear is engaged with the bevel block, the rotating shaft is rotatably connected to the connecting frame, the circular gear is connected to the rotating shaft, the circular gear is engaged with the rack, and the gear transmission assembly is connected between the rotating shaft and the second rotating rod.

In a preferred embodiment of the present invention, the positioning device further includes a positioning device, the positioning device includes a third guide rail, a third guide sleeve, a hanging ring, a hook, a moving rod, a clamping assembly, and a second elastic member, one side of the cart frame near the guide sleeve is connected with the third guide rail, the third guide rail is slidably connected with the third guide sleeve, the third guide sleeve is connected with the hanging ring, the hook is placed in the hanging ring, the moving rod is connected to the hook, the clamping assembly is arranged on the lower side of the moving rod, and the second elastic member is connected between the clamping assembly and the third guide sleeve.

In a preferred embodiment of the present invention, the clamping assembly includes an L-shaped frame, a movable clamping arm, and a screw, the L-shaped frame is connected to the lower side of the moving rod, a threaded hole is formed on the L-shaped frame, the movable clamping arm is disposed on the L-shaped frame, the screw is disposed in the movable clamping arm, the screw passes through the movable clamping arm, and the screw is matched with the threaded hole.

In a preferred embodiment of the invention, the belt drive assembly is a belt drive.

In a preferred embodiment of the present invention, the first elastic member and the second elastic member are straight springs.

The invention has the beneficial effects that: according to the invention, the rotating disc is rotated to drive the iron wire to move upwards through the guide sleeve so as to wind the iron wire upwards on the sapling, so that the iron wire can be automatically and continuously wound on the sapling from bottom to top, the automation can be improved, the working efficiency is improved, and in the process of winding the iron wire, the iron wire does not need to be manually held, and the hands of people can not be injured.

Drawings

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

Fig. 2 is a schematic front view of the ascending device according to the present invention.

Fig. 3 is a schematic front view of the limiting device of the present invention.

Fig. 4 is a front view of the transmission device of the present invention.

Fig. 5 is a schematic front view of the positioning device of the present invention.

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

The parts are labeled as follows: 1. a trolley frame, 2, a support frame, 3, a fixing plate, 4, a gear motor, 5, a first bearing seat, 6, a first rotating rod, 7, a belt transmission component, 8, a rotating disk, 81, a through hole, 9, a placing rod, 10, a lifting device, 11, a limiting device, 12, a transmission device, 101, a first guide sleeve, 102, a first guide rail, 103, a first fixture block, 104, a rack, 105, a guide sleeve, 106, a guide wheel, 111, a second guide sleeve, 112, a second guide rail, 113, a first elastic element, 114, a connecting rod, 115, a second fixture block, 121, a connecting frame, 122, a second bearing seat, 123, a second rotating rod, 124, a bevel gear, 125, a bevel gear block, 126, a rotating shaft, 127, a circular gear, 128, a gear transmission component, 13, a positioning device, 131, a third guide rail, 132, a third guide rail, 133, a hanging ring, 134, a hook, 135, a moving rod, 136, a clamping component, 137, 136, a third guide sleeve, 133, a hanging ring, a connecting rod, the second elastic piece, 1361, L-shaped frame, 1362, screw hole, 1363, activity arm lock, 1364, screw rod.

Detailed Description

It is to be noted that, in the case of the different described embodiments, identical components are provided with the same reference numerals or the same component names, wherein the disclosure contained in the entire description can be transferred to identical components having the same reference numerals or the same component names in a meaningful manner. The positional references selected in the description, such as upper, lower, lateral, etc., refer also to the directly described and illustrated figures and are to be read into the new position in the sense of a change in position.

Example 1

The utility model provides an automatic iron wire plastic equipment that twines of pine seedling, as shown in figure 1, including pushing away frame 1, support frame 2, fixed plate 3, gear motor 4, first bearing frame 5, first bull stick 6, belt drive assembly 7, rotary disk 8, place pole 9, rising device 10, stop device 11 and transmission 12, specifically do:

a supporting frame 2 is connected on the right side of the upper side of the cart frame 1, a fixing plate 3 is connected on the upper side of the supporting frame 2, a speed reducing motor 4 is connected on the right side of the upper side of the fixed plate 3, a first bearing seat 5 is connected on the left side in the fixed plate 3, a first rotating rod 6 is connected in the first bearing seat 5, a belt transmission assembly 7 is connected between the upper side of the first rotating rod 6 and the output shaft of the speed reducing motor 4, the lower side of the first rotating rod 6 is connected with a rotating disc 8, the middle part of the rotating disc 8 is provided with a through hole 81, a placing rod 9 is connected to the right side of the upper side of the rotating disc 8, a lifting device 10 is arranged on the right side of the rotating disc 8, a limiting device 11 is arranged on the right side of the lower side of the rotating disc 8, the ascending device 10 is matched with the limiting device 11, a transmission device 12 is arranged below the left side of the support frame 2, and the transmission device 12 is matched with the rotating disc 8 and the lifting device 10.

When the sapling needs to be shaped by winding the steel wire, the device is pushed to the sapling edge to be shaped by the pushing frame 1, then the steel wire coil is placed on the placing rod 9, then the steel wire passes through the through hole 81 and the ascending device 10, at this time, the end of the steel wire can be fixed on the ground, at this time, the speed reducing motor 4 can be started, the speed reducing motor 4 drives the first rotating rod 6 to rotate by the belt transmission component 7, the first rotating rod 6 drives the rotating disc 8 to rotate, so as to drive the ascending device 10 and the limiting device 11 to rotate, so that the ascending device 10 drives the steel wire to wind the sapling, after the rotating disc 8 rotates for a circle, the rotating disc 8 enables the ascending device 10 to ascend by the transmission device 12, and the limiting device 11 limits the height of the ascending device 10 after ascending, at the moment, the rotating disc 8 continues to rotate, the rotating disc 8 drives the ascending device 10 with the ascending height to wind steel wires on the upper portion of the sapling, after circulation, shaping of the wound steel wires on the root portion of the sapling is completed, the gear motor 4 can be turned off at the moment, then the tail end of the fixed steel wire is loosened, the upper end of the steel wire is cut off, and at the moment, the rotating disc 8 can move out of the sapling position through the pushing frame 1 and arrives at other saplings needing shaping.

Example 2

On the basis of embodiment 1, as shown in fig. 2 to 4, the ascending device 10 includes a first guide sleeve 101, a first guide rail 102, a first block 103, a rack 104, a guide sleeve 105, and a guide wheel 106, specifically:

the inner portion of the right side of the rotating disc 8 is connected with a first guide sleeve 101, the first guide sleeve 101 is connected with a first guide rail 102 in an inner sliding manner, the first guide rail 102 is of a structure with a groove at the bottom, a first clamping block 103 is connected to the lower portion of the left side of the first guide rail 102, the first clamping block 103 is matched with the limiting device 11, a rack 104 is connected to the lower portion of the right side of the first guide rail 102, the rack 104 is matched with the transmission device 12, a guide sleeve 105 is connected to the left portion of the lower side of the first guide rail 102, and a guide wheel 106 is connected to the guide sleeve 105 in an inner connecting manner.

The steel wire can pass through the guide sleeve 105, when the rotating disc 8 rotates, the rotating disc 8 will drive the first guide sleeve 101 and the first guide rail 102 to rotate, thereby driving the guide sleeve 105 to rotate, the guide sleeve 105 will drive the inner steel wire to rotate, thereby causing the guide sleeve 105 to rotate around the sapling, the steel wire is wound on the sapling, the guide wheel 106 will play a role of reducing guide friction, after the rotating disc 8 rotates for one circle, the transmission device 12 will drive the rack 104 and the first guide rail 102 to move upwards, thereby driving the guide sleeve 105 to move upwards, thereby causing the guide sleeve 105 to lift upwards the steel wire winding of the sapling, thereby causing the steel wire to be wound on the upper part of the sapling, after the first guide rail 102 moves upwards, the limiting device 11 will limit through the first block 103, therefore, the heights of the first guide rail 102 and the guide sleeve 105 are limited, and when the first guide rail 102 and the guide sleeve 105 need to move downwards, the limiting device 11 can be manually controlled to move the first guide rail 102 downwards.

The limiting device 11 includes a second guide sleeve 111, a second guide rail 112, a first elastic member 113, a connecting rod 114 and a second clamping block 115, and specifically:

a second guide sleeve 111 is connected to the right of the lower side of the rotating disc 8, the second guide sleeve 111 is located at the left of the first guide rail 102, a second guide rail 112 is connected to the second guide sleeve 111 in a sliding manner, a first elastic element 113 is connected between the second guide rail 112 and the second guide sleeve 111, a connecting rod 114 is connected to the right of the second guide rail 112, five second clamping blocks 115 are connected to the lower portion of the right of the connecting rod 114, and the second clamping blocks 115 are matched with the first clamping blocks 103.

When the first guide rail 102 moves upward, the first guide rail 102 drives the first latch 103 to move upward, at this time, the first latch 103 passes through the second latch 115, the second latch 115 is reset through the second guide rail 112 and the first elastic member 113, so that the second latch 115 can hold the first latch 103, thereby limiting the positions of the first latch 103 and the first guide rail 102, when the height of the first guide rail 102 needs to be reduced, the connecting rod 114 can be moved leftward, the connecting rod 114 moves leftward through the second guide rail 112, so that the second latch 115 moves leftward to be separated from the contact with the first latch 103, at this time, the first guide rail 102 can be moved downward, and after the connecting rod 114 is released, the first elastic member 113 drives the connecting rod 114 and the second guide rail 112 to reset.

The transmission device 12 includes a connecting frame 121, a second bearing seat 122, a second rotating rod 123, a bevel gear 124, a bevel gear block 125, a rotating shaft 126, a circular gear 127 and a gear transmission assembly 128, and specifically includes:

the support frame 2 left side below is connected with link 121, link 121 upside is connected with second bearing frame 122, second bull stick 123 is connected to second bearing frame 122 in, second bull stick 123 upside is connected with bevel gear 124, rotary disk 8 right side is connected with awl tooth piece 125, awl tooth piece 125 with bevel gear 124 meshing, link 121 left side lower part rotary type is connected with pivot 126, be connected with round gear 127 on the pivot 126, round gear 127 with the rack 104 meshing, pivot 126 with be connected with gear drive subassembly 128 between the second bull stick 123 downside.

When the rotating disc 8 rotates, the rotating disc 8 drives the bevel gear block 125 to rotate, after the rotating disc 8 rotates for one circle, the bevel gear block 125 contacts the bevel gear 124, the bevel gear block 125 drives the bevel gear 124 to rotate, the bevel gear 124 drives the second rotating rod 123 to rotate, the second rotating rod 123 drives the rotating shaft 126 to rotate clockwise through the gear transmission assembly 128, the rotating shaft 126 drives the circular gear 127 to rotate clockwise, and the circular gear 127 drives the rack 104 to move upwards, so as to drive the first guide rail 102 and the guide sleeve 105 to move upwards.

Example 3

On the basis of embodiment 2, as shown in fig. 4 to 6, the positioning device 13 is further included, the positioning device 13 includes a third guide rail 131, a third guide sleeve 132, a hanging ring 133, a hook 134, a moving rod 135, a clamping assembly 136 and a second elastic member 137, specifically:

the utility model discloses a shallow, including shallow frame 1, third guide rail 131 upper side left is connected with third guide pin bushing 132, third guide pin bushing 132 front side is connected with link 133, couple 134 has been placed in the link 133, be connected with carriage release lever 135 on the couple 134, carriage release lever 135 downside is connected with clamping component 136, clamping component 136 upside with be connected with second elastic component 137 between the third guide pin bushing 132 downside.

The hook 134 can be hung in the hook ring hanging ring 133, at this time, the second elastic member 137 enters a stressed state, when the device moves to the edge of a seedling, the tail end of the steel wire can be placed in the clamping component 136, the steel wire is clamped through the clamping component 136, the third guide sleeve 132 can be moved leftwards at this time, the third guide sleeve 132 drives the clamping component 136 to move leftwards to enable the clamping component 136 to move to the upper side of the ground, at this time, the hook 134 can be taken out of the hook ring 133, at this time, the second elastic member 137 recovers from the stressed state, so that the clamping component 136 is driven to move downwards, and the clamping component 136 drives the steel wire to move downwards to be fixed on the ground.

The clamping assembly 136 includes an L-shaped frame 1361, a movable clamping arm 1363 and a screw 1364, and specifically:

an L-shaped frame 1361 is connected to the rear of the lower side of the moving rod 135, a threaded hole 1362 is formed in the left of the rear side of the L-shaped frame 1361, a movable clamping arm 1363 is arranged on the rear side of the L-shaped frame 1361, a screw 1364 is arranged in the movable clamping arm 1363, the screw 1364 penetrates through the movable clamping arm 1363, the screw 1364 is screwed into the threaded hole 1362, and the movable clamping arm 1363 is fixed to the L-shaped frame 1361 through the screw 1364.

The end of the steel wire can be placed between the L-shaped frame 1361 and the movable clamping arm 1363, then the screw 1364 is rotated, the screw 1364 will drive the movable clamping arm 1363 to move toward the L-shaped frame 1361, so as to clamp the steel wire, and when the steel wire needs to be released, the screw 1364 can be reversed, so that the movable clamping arm 1363 no longer clamps the L-shaped frame 1361.

Further, the belt transmission assembly 7 is a belt transmission.

Further, the first elastic member 113 and the second elastic member 137 are straight springs.

The embodiments described above are provided to enable persons skilled in the art to make or use the invention and that modifications or variations can be made to the embodiments described above by persons skilled in the art without departing from the inventive concept of the present invention, so that the scope of protection of the present invention is not limited by the embodiments described above but should be accorded the widest scope consistent with the innovative features set forth in the claims.

Claims (6)

1. An automatic iron wire winding shaping device for pine seedlings comprises a cart frame and a support frame, wherein the support frame is connected to the upper side of the cart frame, and the automatic iron wire winding shaping device is characterized by further comprising a fixing plate, a speed reducing motor, a first bearing seat, a first rotating rod, a belt transmission assembly, a rotating disk, a placing rod, a lifting device, a limiting device and a transmission device, the fixing plate is connected to the upper side of the support frame, the speed reducing motor is connected to the fixing plate, the first bearing seat is connected to the left side in the fixing plate, the first rotating rod is connected to the first bearing seat, the belt transmission assembly is connected between the first rotating rod and the speed reducing motor, the rotating disk is connected to the lower side of the first rotating rod, a through hole is formed in the middle of the rotating disk, the placing rod is connected to the rotating disk, the lifting device is arranged on the rotating disk, the limiting device is arranged on the lower side of the rotating disk, and is matched with the lifting device, a transmission device is arranged on one side of the support frame, which is close to the rotating disc, and the transmission device is matched with the rotating disc and the lifting device;

the ascending device comprises a first guide sleeve, a first guide rail, a first clamping block, a rack, a guide sleeve and a guide wheel, the first guide sleeve is connected inside one side, close to the support frame, of the rotating disc, the first guide rail is connected inside the first guide sleeve in a sliding mode, the first guide rail is of a structure with a groove in the bottom, the first clamping block is connected to one side, far away from the support frame, of the lower side of the first guide rail, the first clamping block is matched with the limiting device, the rack is connected to one side, close to the support frame, of the lower side of the first guide rail, the rack is matched with the transmission device, the guide sleeve is connected to one side, far away from the first clamping block, of the lower side of the first guide rail, and the guide wheel is arranged in the guide sleeve;

the limiting device comprises a second guide sleeve, a second guide rail, a first elastic part, a connecting rod and a second clamping block, wherein one side, far away from the support frame, of the lower side of the rotating disc is connected with the second guide sleeve, the second guide rail is connected in the second guide sleeve in a sliding mode, the first elastic part is connected between the second guide rail and the second guide sleeve, one side, close to the first guide rail, of the second guide rail is connected with the connecting rod, one side, close to the first clamping block, of the connecting rod is connected with the second clamping block, and the second clamping block is matched with the first clamping block.

2. The automatic pine seedling iron wire winding shaping equipment according to claim 1, wherein the transmission device comprises a connecting frame, a second bearing seat, a second rotating rod, a bevel gear, a bevel block, a rotating shaft, a circular gear and a gear transmission assembly, the connecting frame is connected to one side of the supporting frame close to the rack, the second bearing seat is connected to one side of the connecting frame upper portion close to the rack, the second rotating rod is connected to the inside of the second bearing seat, the bevel gear is connected to the upper side of the second rotating rod, the bevel block is connected to one side of the rotating disc close to the bevel gear, the bevel gear is meshed with the bevel block, the rotating shaft is rotatably connected to the connecting frame, the circular gear is connected to the rotating shaft, the circular gear is meshed with the rack, and the gear transmission assembly is connected between the rotating shaft and the second rotating rod.

3. The automatic iron wire winding and shaping equipment for pine seedlings according to claim 2, further comprising a positioning device, wherein the positioning device comprises a third guide rail, a third guide sleeve, a hanging ring, a hook, a moving rod, a clamping assembly and a second elastic member, the third guide rail is connected to one side of the pusher frame close to the guide sleeve, the third guide rail is slidably connected with the third guide sleeve, the hanging ring is connected to the third guide sleeve, the hook is placed in the hanging ring, the moving rod is connected to the hook, the clamping assembly is arranged on the lower side of the moving rod, and the second elastic member is connected between the clamping assembly and the third guide sleeve.

4. The automatic iron wire winding and shaping equipment for pine seedlings according to claim 3, wherein the clamping assembly comprises an L-shaped frame, a movable clamping arm and a screw rod, the L-shaped frame is connected to the lower side of the moving rod, a threaded hole is formed in the L-shaped frame, the movable clamping arm is arranged on the L-shaped frame, the screw rod is placed in the movable clamping arm, the screw rod penetrates through the movable clamping arm, and the screw rod is matched with the threaded hole.

5. The automatic pine seedling iron wire winding shaping device as claimed in claim 4, wherein the belt transmission component is a belt transmission.

6. The automatic pine seedling iron wire winding shaping device of claim 5, wherein the first elastic member and the second elastic member are straight springs.

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