CN218451210U - Low-carbon energy-saving seedling growth device - Google Patents

Abstract

The utility model discloses a low-carbon energy-saving forestry seedling culture device, which relates to the technical field of forestry seedling culture, and comprises a fixed base, wherein a rotating disc is arranged in the fixed base; the rotating disc is provided with an arc-shaped chute; a first turbine and a first worm are arranged in the fixed base; the sliding block can slide on the fixed base; a lifting base is arranged on the sliding block; a threaded rod and a fixed rod are arranged on the lifting base; the threaded rod and the fixed rod are sleeved with seedling raising frames. The utility model discloses a rotating disc is set up through the unable adjustment base internal rotation, and first worm drives first turbine rotation, and first turbine drives rotating disc rotation, and the slide bar slides in the arc spout, and the slide bar drives the slider of top to slide in the straight line spout simultaneously, and under arc spout and straight line spout combined action, the slider slides inside and outside, realizes that the nursery cabinet spreads or contracts; set up lifting pedestal through slider upper portion, the second worm drives the second turbine and rotates, and the second turbine drives the threaded rod and rotates, realizes that the nursery cabinet reciprocates.

Description

Low-carbon energy-saving seedling growth device

Technical Field

The utility model relates to a seedling growth technical field specifically is a low carbon energy-conserving seedling growth device.

Background

In recent years, the concept of 'low-carbon energy conservation' starts to be brought up to various national agenda, the development of low-carbon economy becomes a great trend, in the development of the low-carbon energy-saving economy, the development of the forestry occupies a considerable important position, the forestry is used for protecting the ecological balance of the environment, the forest is cultivated and protected to obtain wood and other forest products, and a production department which utilizes the natural characteristics of the forest to play a protection role needs a large number of tree seedlings, but in the outdoor cultivation process, the climate, the temperature, the humidity and other important indexes are not easily controlled, so that the seedlings grow slowly, the development of the seedlings is influenced, and in order to ensure the normal production of the seedlings, the indoor cultivation of the seedlings is generally carried out by means of a seedling cultivation device.

In order to better fit with the development concept of low carbon and energy conservation advocated by the nation, on one hand, the environment protection responsibility is positively undertaken, the energy conservation and consumption reduction indexes are completed, on the other hand, the economic structure is also adjusted, the resources are reasonably utilized, in the process of indoor cultivation of tree seedlings at present, the space utilization rate of most cultivation devices in the cultivation process is low, large indoor space is occupied, certain space and construction cost waste is caused, and the low carbon and energy conservation effect is not achieved.

In view of this, the present invention is especially provided.

Disclosure of Invention

The utility model aims at the above problem, a forestry seedling culture device with rotatory flexible function is provided, has solved the problem that culture in-process space utilization is low.

The utility model adopts the technical proposal that: a low-carbon energy-saving seedling growth device comprises a fixed base, a rotating disc, a first turbine, a first worm, a sliding block, a lifting base, a threaded rod, a fixed rod and a seedling growing frame;

a rotating disc is rotatably arranged in the fixed base, a first turbine is connected to the lower end of the rotating disc, a first worm matched with the first turbine is movably arranged in the fixed base, a through hole is formed in the fixed base, and the first worm penetrates through the through hole and is meshed with the first turbine;

the rotating disc is provided with a plurality of arc-shaped sliding chutes, and sliding rods respectively penetrate through and slide in the arc-shaped sliding chutes;

the fixed base is provided with a plurality of sliding blocks matched with the sliding rods, the bottom ends of the sliding blocks are respectively provided with a sliding rail, and the upper end of each sliding rod penetrates through an arc-shaped sliding groove and is connected with the bottom of the corresponding sliding rail;

the fixed base is provided with linear sliding chutes matched with the sliding rails, and each sliding rail is arranged in the matched linear sliding chute in a sliding manner;

a lifting base is arranged at the upper part of each sliding block;

each lifting base is provided with a threaded rod and a fixed rod;

threaded rod and dead lever top are equipped with the nursery cabinet jointly, round hole and screw hole have been seted up on the nursery cabinet respectively, the dead lever is run through in the round hole activity, screw hole internal thread runs through the threaded rod.

Furthermore, the inside second worm wheel and the second worm that is equipped with of rotation of lifting pedestal, second worm wheel and second worm mesh mutually, the second worm runs through the lifting pedestal outside and is connected with the second and rotates the handle, the lifting pedestal connection second worm wheel is run through to the threaded rod below.

Furthermore, bearings which are matched with each other are respectively arranged at the connection part of the first worm and the fixed base and the connection part of the second worm wheel and the lifting base.

Furthermore, a central shaft is arranged at the center of the inside of the fixed base, and the rotating disc is rotatably sleeved on the central shaft.

Furthermore, a first rotating handle is connected to the outer side of the first worm.

The utility model has the advantages that: the utility model discloses a rotating disc is set up through the inside rotation of unable adjustment base, rotating disc lower extreme connects first turbine, unable adjustment base is inside to set up first worm, set up the arc spout on the rotating disc, unable adjustment base is last to set up the straight line spout, the slide bar can slide in the arc spout, the gliding slide bar can drive the slider of top to slide in the straight line spout, drive first worm through first rotation handle and rotate, first worm drives first turbine and rotates, first turbine drives the rotating disc and rotates, the slide bar slides in the arc spout this moment, the slide bar is when rotating in the arc spout, can drive the slider of top to slide in the straight line spout simultaneously through the slide rail, under the combined action of arc spout and straight line spout to the slider, realize inside and outside slip of slider, thereby make the nursery sock growing rack spread or contract, can be better operate according to the seedling cultivation condition;

set up lifting pedestal through slider upper portion, lifting pedestal is inside to be rotated and to be set up second turbine and second worm, and second turbine top connecting threaded rod drives the second turbine through rotating the second worm and rotates, and the second turbine drives the threaded rod and rotates to control nursery cabinet reciprocates, nursery cabinet removal in-process, the dead lever plays the stabilizing effect through the round hole on the nursery cabinet to it, and the convenience is handled the seedling on the eminence nursery cabinet. Simultaneously the utility model has the advantages of being simple in structure and convenient in operation, and the flexibility ratio is high.

In addition to the above-described objects, features and advantages, the present invention has other objects, features and advantages. The present invention will be described in further detail with reference to the drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification.

Fig. 1 is a schematic view of the overall closed state of the present invention;

fig. 2 is a bottom view of the fixing base of the present invention;

fig. 3 is a schematic structural view of the rotating disk and the second rotating disk of the present invention;

FIG. 4 is a schematic view of the slide rail of the present invention slidably disposed in the slide groove;

FIG. 5 is a schematic view of the structure of the rotary disk and the slide block of the present invention;

fig. 6 is a top view of the fixing disc of the present invention;

fig. 7 is a schematic structural view of a second worm wheel and a second worm according to the present invention;

fig. 8 is a schematic view of the overall expanded state of the present invention.

Reference numerals:

1 is a fixed base; 101 is a through hole; 102 is a straight chute; 2 is a rotating disc; 201 is an arc chute; 3 is a first worm; 301 is a first rotating handle; 4 is a first turbine; 401 is a slide bar; 5 is a slide block; 501, a sliding rail; 6 is a lifting base; 601 is a second turbine; 602 is a second worm; 603 is a second rotating handle; 7 is a threaded rod; 8 is a fixed rod; and 9 is a seedling raising frame.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Referring to fig. 1 to 8, a low-carbon and energy-saving seedling raising device for forestry comprises a fixed base 1, a rotating disc 2, a first turbine 4, a first worm 3, a sliding block 5, a lifting base 6, a threaded rod 7, a fixed rod 8 and a seedling raising frame 9;

the fixed base 1 is internally and rotatably provided with a rotating disc 2, a center shaft is arranged at the center of the inside of the fixed base 1, the rotating disc 2 is rotatably sleeved on the center shaft, the rotating disc 2 can rotate around the center shaft on the fixed base 1, the lower end of the rotating disc 2 is connected with a first turbine 4, a first worm 3 matched with the first turbine 4 is movably arranged in the fixed base 1, the fixed base 1 is provided with a through hole 101, the first worm 3 penetrates through the through hole 101 to be meshed with the first turbine 4, a matched bearing is arranged at the joint of the first worm 3 and the fixed base 1, the first worm 3 can freely rotate in the fixed base 1, the outer side of the first worm 3 is connected with a first rotating handle 301, the first rotating handle 301 is rotated to enable the first worm 3 to rotate, the first worm 3 drives the first turbine 4 meshed with the first worm 3 to rotate, and the first turbine 4 can drive the rotating disc 2 to rotate around the center shaft of the fixed base 1.

The rotating disc 2 is provided with a plurality of arc-shaped chutes 201, a plurality of sliding rods 401 penetrate through the arc-shaped chutes 201 respectively, a plurality of sliding blocks 5 matched with the sliding rods 401 are arranged on the fixed base 1, the bottom ends of the sliding blocks 5 are provided with sliding rails 501 respectively, the upper end of each sliding rod 401 penetrates through the arc-shaped chute 201 respectively and is connected with the bottom of the corresponding sliding rail 501, the fixed base 1 is provided with a linear chute 102 matched with the sliding rails, each sliding rail 501 is arranged in the linear chute 102 matched in a sliding manner, in the seedling raising process, when the raised seedlings need to be sprayed, fertilized, illuminated or otherwise processed, the raised seedlings need to be spread, the first rotating handle 301 can be rotated clockwise to drive the first worm 3 to rotate clockwise, the first worm 3 drives the first worm 4 to rotate anticlockwise, the first worm 4 drives the rotating disc 2 to rotate anticlockwise, at the moment, the sliding rods 401 slide outwards in the arc-shaped chutes 201, the sliding rods 401 can drive the sliding rails 501 above sliding blocks 5 to slide in the linear chutes 102 while sliding grooves 201 outwards, the sliding rails 201 and the sliding blocks 5 act on the outside together, thereby facilitating the seedling raising of the seedlings in the next step; when accomplishing spraying to cultivating the seedling, after the operation such as fertilization, for practicing thrift indoor cultivation space, be convenient for accomodate and place, often need to accomodate the seedling folding of cultivating, can first rotation handle 301 of anticlockwise rotation, drive first worm 3 anticlockwise rotation, first worm 3 drives first turbine 4 clockwise, first turbine 4 drives and rotates disc 2 clockwise, slide bar 401 slides to inside in arc spout 201 this moment, slide bar 401 is when inside gliding in arc spout 201, can drive the slide rail 501 of top and make slider 5 slide in sharp spout 102, under arc spout 201 and the combined action of sharp spout 102 to slider 5, slider 5 slides to the inside, the completion is folded the seedling of cultivating.

The upper part of each sliding block 5 is provided with a lifting base 6, the interior of the lifting base 6 is rotatably provided with a second worm wheel 601 and a second worm 602, the second worm wheel 601 and the second worm 602 are meshed with each other, the second worm 602 penetrates through the outer side of the lifting base 6 and is connected with a second rotating handle 603, the joints of the second worm wheel 601, the second worm 602 and the lifting base 6 are respectively provided with a bearing matched with each other, the second worm wheel 601 and the second worm 602 can be freely rotated in the lifting base 6, each lifting base 6 is provided with a threaded rod 7 and a fixed rod 8, the lower part of the threaded rod 7 penetrates through the lifting base 6 and is connected with the second worm wheel 601, the upper parts of the threaded rod 7 and the fixed rod 8 are jointly sleeved with a seedling raising frame 9, the seedling raising frame 9 is respectively provided with a round hole and a threaded hole, the fixing rod 8 movably penetrates through the inside the round hole, the threaded rod 7 penetrates through the threaded hole, when a seedling on the high seedling frame 9 needs to be treated, the first rotating handle 301 is rotated to spread the seedling raising frame 9, then the second rotating handle 603 is used for clockwise rotating the second worm 602 to drive the second worm 601 to rotate the second worm 601, the seedling raising frame to move the seedling raising frame 9 counterclockwise, the seedling raising frame 9, and can be transplanted to a seedling raising frame 9 in the seedling raising process, and the seedling raising frame can be transplanted stably; after the operation is finished, the second worm 602 is rotated anticlockwise through the second rotating handle 603, the second worm 602 drives the second worm gear 601 to rotate clockwise, the second worm gear 601 drives the threaded rod 7 to rotate clockwise, at the moment, the seedling raising frame 9 moves upwards, and after the seedling raising frame is moved to a required height, the first rotating handle 301 is rotated to enable the seedling raising frame 9 to be folded in a shrinkage mode.

The utility model discloses a working process: in a seedling growth process of forestry, when the cultured seedlings need to be sprayed, fertilized, illuminated or otherwise manipulated, the cultured seedlings often need to be spread, the first rotating handle 301 is rotated clockwise to drive the first worm 3 to rotate clockwise, the first worm 3 drives the first turbine 4 to rotate counterclockwise, the first turbine 4 drives the rotating disc 2 to rotate counterclockwise, at this time, the sliding rod 401 slides outwards in the arc-shaped sliding groove 201 and simultaneously drives the sliding rail 501 above to slide the sliding block 5 in the linear sliding groove 102, and under the combined action of the arc-shaped sliding groove 201 and the linear sliding groove 102 on the sliding block 5, the sliding block 5 slides outwards to complete spreading of the cultured seedlings; when seedlings on a high-altitude seedling raising frame 9 need to be processed, the second worm 602 is rotated clockwise through the second rotating handle 603, the second worm 602 drives the second turbine 601 to rotate anticlockwise, the second turbine 601 drives the threaded rod 7 to rotate anticlockwise, at this time, the seedling raising frame 9 moves downwards, in the moving process of the seedling raising frame 9, the fixing rod 8 plays a stabilizing role for the seedling raising frame 9 through a round hole in the seedling raising frame, at this time, seedling planting or transplanting can be carried out on the seedling raising frame 9, after the operation is completed, the second worm 602 is rotated anticlockwise through the second rotating handle 603, the second worm 602 drives the second turbine 601 to rotate clockwise, the second turbine 601 drives the threaded rod 7 to rotate clockwise, at this time, the seedling raising frame 9 moves upwards, after the seedling raising frame moves to a required height, in order to save indoor cultivation space, the accommodating and placing are convenient, the cultivated seedlings often need to be folded and accommodated, the first rotating handle 301 is rotated anticlockwise, the first worm 3 is driven to rotate anticlockwise, the first turbine 4 drives the rotating disc 2 to rotate, at this moment, the sliding rod slides inwards in the arc-shaped sliding chute 401, the sliding block 401 slides downwards along the sliding chute 401, and the sliding block can slide along the sliding chute 102 and slide along the straight line, and the sliding chute 201, and the sliding block 201, and the sliding chute 401 can be carried out along the sliding of the sliding block, at the sliding chute 5, at the sliding chute 201.

The utility model has the advantages that: the utility model discloses a rotating disc is set up through the inside rotation of unable adjustment base, the rotating disc lower extreme is connected with first turbine, the inside first worm that sets up of unable adjustment base, set up the arc spout on the rotating disc, the last straight line spout that sets up of unable adjustment base, the slide bar can slide in the arc spout, the gliding slide bar can drive the slider of top and slide in the straight line spout, drive the rotation of first worm through first rotation handle, first worm drives the rotation of first turbine, first turbine drives the rotating disc and rotates, the slide bar slides in the arc spout this moment, when the slide bar rotates in the arc spout, can drive the slider of top and slide in the straight line spout through the slide rail simultaneously, under the combined action of arc spout and straight line spout to the slider, realize the inside and outside slip of slider, thereby make the nursery sock growing rack spread or contract, can be better operate according to the seedling condition; set up lifting pedestal through slider upper portion, lifting pedestal is inside to be rotated and to set up second turbine and second worm, and second turbine top connecting rod drives the second turbine through rotating the second worm and rotates, and the second turbine drives the threaded rod and rotates to control seedling raising frame reciprocates, seedling raising frame removal in-process, the dead lever play the stabilizing action through the round hole on the seedling raising frame to it, and the convenience is handled the seedling on the eminence seedling raising frame. Simultaneously the utility model has the advantages of being simple in structure and convenient in operation, and the flexibility ratio is high.

The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included within the protection scope of the present invention.

Claims (5)

1. A low-carbon energy-saving seedling growth device for forestry is characterized by comprising a fixed base (1), a rotating disc (2), a first turbine (4), a first worm (3), a sliding block (5), a lifting base (6), a threaded rod (7), a fixed rod (8) and a seedling growing frame (9);

a rotating disc (2) is rotatably arranged in the fixed base (1), a first turbine (4) is connected to the lower end of the rotating disc (2), a first worm (3) matched with the first turbine (4) is movably arranged in the fixed base (1), a through hole (101) is formed in the fixed base (1), and the first worm (3) penetrates through the through hole (101) and is meshed with the first turbine (4);

a plurality of arc-shaped sliding grooves (201) are formed in the rotating disc (2), and sliding rods (401) penetrate through the arc-shaped sliding grooves (201) respectively in a sliding manner;

a plurality of sliding blocks (5) matched with the sliding rods (401) are arranged on the fixed base (1), sliding rails (501) are respectively arranged at the bottom ends of the sliding blocks (5), and the upper end of each sliding rod (401) penetrates through the arc-shaped sliding groove (201) and is connected with the bottom of the corresponding sliding rail (501);

the fixed base (1) is provided with linear sliding chutes (102) matched with the sliding rails, and each sliding rail (501) is arranged in the corresponding linear sliding chute (102) in a sliding manner;

the upper part of each sliding block (5) is provided with a lifting base (6);

each lifting base (6) is provided with a threaded rod (7) and a fixed rod (8);

threaded rod (7) and dead lever (8) top are overlapped jointly and are equipped with seedling raising frame (9), round hole and screw hole have been seted up on seedling raising frame (9) respectively, dead lever (8) are run through in the round hole activity, threaded hole internal thread run through threaded rod (7).

2. A low-carbon energy-saving seedling raising device for forestry as claimed in claim 1, wherein a second turbine (601) and a second worm (602) are rotatably arranged in the lifting base (6), the second turbine (601) is meshed with the second worm (602), the second worm (602) penetrates through the outer side of the lifting base (6) and is connected with a second rotating handle (603), and a lower part of the threaded rod (7) penetrates through the lifting base (6) and is connected with the second turbine (601).

3. A low-carbon energy-saving seedling raising device for forestry as claimed in claim 2, wherein the joints of the first worm (3) and the fixed base (1), and the joints of the second worm wheel (601) and the second worm (602) and the lifting base (6) are respectively provided with bearings matched with each other.

4. A low-carbon energy-saving seedling raising device for forestry as claimed in claim 1, wherein a central shaft is arranged at the center inside the fixing base (1), and the rotating disc (2) is rotatably sleeved on the central shaft.

5. A low-carbon and energy-saving seedling raising device as claimed in claim 1, wherein a first rotating handle (301) is connected to the outer side of the first worm (3).

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