CN221128246U - Fungus mushroom harvesting frame and fungus mushroom cultivation subassembly - Google Patents

Abstract

The utility model relates to the field of mushroom cultivation, in particular to a mushroom harvesting frame and a mushroom cultivation component, which comprises a frame body, wherein the frame body is provided with side rib plates, and a plurality of staggered middle rib plates divide a frame body space surrounded by the side rib plates into a plurality of harvesting holes; correspond to set up in every and gather downthehole bowl of gathering, gather the bowl and include: the outer side wall of the first cylindrical part is connected with the inner wall of the harvesting hole; a second cylindrical member coaxially disposed with the first cylindrical member, the outer wall of the second cylindrical member being connected to the lower section of the first cylindrical member by an outwardly flared connecting member, the axial projection of the second cylindrical member being received within the axial projection of the first cylindrical member; wherein, at least three convex teeth evenly distributed around the section of thick bamboo wall are set up to the last tube mouth inner wall of the second cylindric piece of at least one harvest bowl. The utility model can ensure that the mushrooms on a plurality of cultivation bottles grow uniformly and continuously on the frame, can separate the mushrooms in the cultivation bottles at the same time, and is convenient for mechanized operation.

Description

Fungus mushroom harvesting frame and fungus mushroom cultivation subassembly

Technical Field

The utility model relates to the field of mushroom cultivation, in particular to a mushroom harvesting frame and a mushroom cultivation component.

Background

The industrial bottle cultivation business of the edible fungi mainly refers to perennial cultivation in a factory by using cultivation bottles, and the perennial stable production of the edible fungi in the factory is realized by mechanization and standardization of cultivation.

The existing cultivation method of bottle cultivated edible fungi generally comprises the procedures of loading, sterilizing, cooling, culturing, fungus scratching, bud forcing, growing, harvesting and the like, edible fungi are cultivated according to the cultivation method, and most of the most original manual harvesting methods are adopted when harvesting, namely mature fruiting bodies are placed on an operation table and are directly picked by hands or sheared by simple devices such as scissors. The harvesting method has the following problems: the harvested edible fungus fruiting bodies are incomplete, so that the fruiting bodies are often damaged, secondary pollution of products is caused, and the quality of the products is directly affected. Meanwhile, the harvesting method can only harvest one bottle at a time, is complex in operation in the harvesting process, low in harvesting speed and low in harvesting efficiency, and cannot meet the harvesting requirements of large-scale industrial bottle-cultivated edible fungus cultivation.

Disclosure of utility model

Aiming at the defects of the prior art, the utility model provides the mushroom harvesting frame which is simple and compact in structure, can ensure that mushrooms on a plurality of cultivation bottles grow uniformly and continuously on the frame, can separate mushrooms in the cultivation bottles at the same time, is convenient for mechanized operation, has high integrity for the mushrooms harvested at the same time, can avoid secondary pollution, and can shape flowers of the mushrooms in the growing process.

The purpose of the utility model is realized in the following way: a mushroom harvesting frame comprising:

The frame body is provided with side rib plates, a plurality of staggered middle rib plates divide a frame body space surrounded by the side rib plates into a plurality of harvesting holes, and the plurality of harvesting holes are distributed in a matrix;

corresponding set up in every harvesting downthehole harvesting bowl, the harvesting bowl includes:

the outer side wall of the first cylindrical part is connected with the inner wall of the harvesting hole;

A second cylindrical member coaxially disposed with the first cylindrical member, the outer wall of the second cylindrical member being connected to the lower section of the first cylindrical member by an outwardly flared connecting member, the axial projection of the second cylindrical member being received within the axial projection of the first cylindrical member;

the inner wall of the upper cylinder mouth of the second cylindrical part of at least one harvesting bowl is provided with at least three convex teeth which are uniformly distributed around the cylinder wall, the outer end parts of the convex teeth are connected with the cylinder wall of the second cylindrical part, and the end wall of the inner extending end of the convex teeth is contracted downwards from top to bottom.

The plurality of harvesting holes are distributed in a matrix, and at least three convex teeth uniformly distributed around the cylinder wall are arranged on the inner wall of the upper cylinder opening of the second cylinder part of the harvesting bowl at the four corners of the frame body.

The cylinder wall of the second cylindrical part positioned at the edge of the frame body is provided with an edge-side reinforcing rib towards the outer side of the frame body, and the outer end wall of the edge-side reinforcing rib is contracted downwards from top to bottom.

The plate body that middle gusset is located every and gathers hole lateral wall includes two connection pieces, and two connection pieces are along middle gusset extending direction interval arrangement, keep somewhere the clearance between two connection pieces opposite ends, and this clearance is with keeping somewhere the clearance between the adjacent first cylindric piece and intersecting and forming the cavity, two connection pieces opposite ends all are equipped with the splice bar, the tip that splice bar both sides side direction extended is connected with adjacent first cylindric piece outer wall respectively.

The top of the cavity is connected with a top reinforcing rib in a closed mode.

The intersection of each rib plate is connected through a cylindrical node; the connecting piece includes a plurality of radials that wind section of thick bamboo wall distribution, the nearly heart end of radials is connected with the upper shed end of second cylindric spare, the radials distal end is connected with first cylindric spare lower shed end, and adjacent radials keep somewhere the clearance in the circumferencial direction.

The thickness of the side rib plate is smaller than the height of the first cylindrical part, and the side rib plate is flush with the upper opening end of the first cylindrical part.

The side rib plates, the middle rib plates and the harvesting bowl are integrally formed.

A fungus mushroom cultivation subassembly, its characterized in that: comprising the following steps:

any one of the mushroom harvesting frames;

a cultivation frame;

The upper opening end of each cultivation bottle is sleeved into the harvesting bowl of the mushroom harvesting frame, and the upper opening ends of the cultivation bottles positioned at four corners of the frame body are abutted with convex teeth in the corresponding harvesting bowl.

Adopt above-mentioned scheme, the beneficial effect is as follows, the framework provides whole support, make each harvest bowl relative position fixed, a plurality of crisscross intermediate gusset can strengthen whole framework, can cut apart into a plurality of solitary spaces in the framework simultaneously and be used for fixed harvest bowl, form the hole between harvest bowl and the downthehole wall of gathering, easily ventilate, be favorable to fungus mushroom evenly to grow, the first cylindric piece of harvest bowl is used for retraining the growth of fungus mushroom, the second cylindric piece is used for supplying the cultivation bottle to insert, make the head of cultivation bottle be located the harvest bowl, the connecting piece of expansion can be used for connecting first cylindric piece and second cylindric piece, this connecting piece can also make to gather the structure of big end down, respectively correspond to fungus mushroom root and fungus mushroom body, it can adapt to the shape of fungus mushroom to gather the bowl in the growth in-process simultaneously, when gathering the bowl can drive the fungus mushroom and cultivate the separation of medium in the bottle, the axial projection of second cylindric piece is held in the axial projection of first cylindric piece, also can stack the first cylindric piece when the first and pile up the second cylindric piece and stack the production, the second is convenient for pile up in the first aspect of the frame of stacking.

In actual production, the bottle mouth of the cultivation bottle is deformed due to long-time use, meanwhile, the cultivation bottles are arranged in groups, and the position accuracy is low, so that the lower cylindrical part is required to be in larger clearance fit with the cultivation bottles, a reasonable clearance is kept, the sleeve frame work of the mushroom harvesting frame can be facilitated, higher tolerance is achieved, and meanwhile, the clearance between the cultivation bottles and the harvesting bowl is convenient to ventilate, so that the growth of mushrooms is facilitated; because the second cylindric piece needs great clearance fit at the cultivation bottleneck, after the cover frame, whole cover frame easily drops, can't guarantee the stability in the high position, influence mushroom cultivation, therefore through the last tube mouth inner wall that is located the second cylindric piece of the gathering bowl in framework four corners sets up at least three around tube wall evenly distributed's dogtooth, can form the interference to the top of the cultivation bottle of excessively inserting this second cylindric piece, thereby realize carrying out vertical ascending support to whole mushroom and gather the frame, keep high position's relatively stable, make mushroom gather the frame and can keep the neck position at the cultivation bottle, the neck of adjacent cultivation bottle can keep the space, be convenient for permeate water ventilative, simultaneously in mechanized harvesting process, be convenient for the inserted bar to insert this space and make body and mushroom gather the frame separation. Meanwhile, the convex teeth are arranged, the gaps between the convex teeth can be favorable for ventilation and water permeability, and the phenomenon that the ventilation and water permeability of the bottle mouth are reduced due to the arrangement of the limiting parts is reduced.

Simultaneously because the end wall of protruding tooth inner stretching end is from last shrink downwards, adopt this kind of structure, have comparatively excellent centering effect, prevent that the cultivation bottle from being eccentric and to the eccentric of bottle mouth spacing part, because the cultivation bottle needs to have great clearance with the second cylindric piece, this structure can be through protruding tooth automatic centering, the outline that makes cultivation bottleneck along can be through the end wall of shrink being hooped in the centering process, when having great hooping power, the aperture that a plurality of protruding tooth upper ends enclose is littleer, the cultivation bottle can't remove, adopt this kind of mode, the fungus mushroom harvesting frame not only can not drop, simultaneously can automatic centering and hooping to the cultivation bottle of grafting, prevent that the fungus mushroom harvesting frame from appearing spaciously moving the phenomenon in the cultivation in-process, avoid the position unstable that the phenomenon leads to that is moved, and to the situation of fungus mushroom damage and flower deformation.

Simultaneously, the spacing part in the scheme, namely the dogtooth, in the collection bowl that is provided with the dogtooth, evenly distribute around corresponding cultivation bottle, the fungus mushroom in this collection bowl receives the influence of dogtooth in the growth process, because the centering effect of dogtooth, cultivation bottle tends to be centered, and the dogtooth is less in axial projection area simultaneously, less to the influence of fungus mushroom side, consequently, fungus mushroom is grown well in the collection bowl that sets up the dogtooth, and the qualification rate is high.

According to the utility model, the fungus mushroom harvesting frames can be restrained on a plurality of cultivation bottles, the fungus mushroom harvesting frames are stable in position in the whole growth process, the situation that the harvesting frames are deviated due to external force or fungus mushroom growth is prevented in the whole growth and development stage, the fungus mushrooms on the plurality of cultivation bottles corresponding to the harvesting frames can be ensured to grow uniformly and continuously on the frames, the influence on the fungus mushrooms is reduced, and the fungus mushrooms have good flower shape and consistency. Meanwhile, the utility model has simple and compact structure, can facilitate the sleeving during the cultivation process, can facilitate the growth of the mushrooms, simultaneously shape the flower shape of the mushrooms, has higher permeability, is favorable for ventilation and water permeation, can quickly separate the mushrooms in a plurality of cultivation bottles at the same time by separating the mushroom harvesting frame from the cultivation bottles during the harvesting, is convenient for mechanical operation, has high integrity of the harvested mushrooms, and can also avoid secondary pollution during the manual harvesting process.

The utility model will be further described with reference to the drawings and the specific examples.

Drawings

Fig. 1 is a schematic structural diagram of the present utility model:

Fig. 2 is a schematic view of the bottom structure of the present utility model:

Fig. 3 is an enlarged view at a in fig. 2:

Fig. 4 is a schematic diagram of the stacked state of the present utility model:

fig. 5 is a reference diagram of the actual use state of the present utility model.

In the drawing, 100 is a frame body, 110 is a side rib plate, 120 is a middle rib plate, 130 is a harvesting hole, 131 is a connecting sheet, 132 is a cavity, 133 is a connecting rib, 134 is a top reinforcing rib, 135 is a web plate, 200 is a harvesting bowl, 210 is a first cylindrical part, 220 is a second cylindrical part, 221 is a side reinforcing rib, 240 is a convex tooth, 300 is a cultivation bottle, and 400 is a cultivation frame.

Detailed Description

Specific embodiments of the present utility model will be described in detail with reference to the accompanying drawings.

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. In the description of the present utility model, unless otherwise indicated, the meaning of a plurality is that two or more in the description of this specification, reference to the description of one embodiment, some embodiments, examples, specific examples, or some examples, etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

Referring to fig. 1 to 5, in one embodiment of a mushroom harvesting frame, the mushroom harvesting frame includes a frame body 100, the frame body 100 has side rib plates 110, the side rib plates 110 may be rectangular, corners of the side rib plates 110 may be transited by an arc plate body, and weight reducing holes may be formed in the side rib plates 110; the frame body 100 enclosed by the side rib plates 110 is divided into a plurality of harvesting holes 130 by the plurality of staggered middle rib plates 120, the plurality of harvesting holes 130 can be equally large rectangular holes, and the degree of density of the arrangement of the middle rib plates 120 can be adjusted as required, for example, the middle rib plates 120 in the middle of the frame body 100 have smaller density and larger growth space, in the embodiment, the middle rib plates 120 are uniformly arranged, the operations such as sleeving frames are facilitated, and the plurality of harvesting holes 130 are distributed in a matrix.

The harvesting bowls 200 corresponding to the harvesting holes 130 are arranged in the harvesting holes 130 in a matrix, and the harvesting bowls 200 corresponding to the harvesting holes 130 include a first cylindrical member 210 and a second cylindrical member 220 coaxially arranged with the first cylindrical member 210, which may be cylindrical or conical. The outer side wall of the first cylindrical part 210 is connected with the inner wall of the harvesting hole 130, and when the harvesting hole 130 is completely surrounded by the middle rib plates 120, the outer wall of the harvesting bowl 200 is connected with the four middle rib plates 120; when the harvesting holes 130 are surrounded by the middle rib plates 120 and the side rib plates 110, namely, the harvesting bowl 200 positioned at the side of the whole frame body 100, wherein the outer walls of the harvesting bowls 200 positioned at four corners of the frame body 100 are connected with the two middle rib plates 120 and simultaneously connected with the side rib plates 110 at the corners, and the rest of the harvesting bowls 200 positioned at the side of the whole frame body 100 are connected with the three middle rib plates 120 and simultaneously connected with the side rib plates 110.

The outer wall of the second barrel 220 is connected to the lower section of the first barrel 210 by an outwardly flared connector 230, the axial projection of the second barrel 220 being received within the axial projection of the first barrel 210.

Wherein, at least three convex teeth 240 uniformly distributed around the cylinder wall are arranged on the inner wall of the upper cylinder mouth of the second cylinder part 220 of at least one harvesting bowl 200, and when only one harvesting bowl 200 with the convex teeth 240 is arranged, the harvesting bowl 200 is preferably arranged at the center of the frame 100; for example, when the frame 100 is rectangular and the plurality of harvesting bowls 200 are distributed in a matrix, at least three protruding teeth 240 uniformly distributed around the wall of the cylinder can be disposed on the inner wall of the upper opening of the second cylindrical member 220 of the harvesting bowl 200 located in the center of the matrix, so as to meet the basic requirement. In this embodiment, at least three protruding teeth 240 uniformly distributed around the cylinder wall are disposed on the inner wall of the upper cylinder opening of the second cylinder member 220 of the harvesting bowl 200 located at four corners of the frame 100, the outer end portions of the protruding teeth 240 are connected with the cylinder wall of the second cylinder member 220, and the end wall of the inner extending end of the protruding teeth 240 is contracted from top to bottom, and the contraction can be performed in the form of an inclined plane or an arc surface. The number of the harvesting bowls 200 with the protruding teeth 240 is not limited in this embodiment, and of course, five harvesting bowls 200 with the protruding teeth 240 are shown in fig. 1, so that requirements can be met, higher stability can be achieved, materials can be saved, and the influence on the growth of mushrooms can be reduced.

It can be appreciated that the convex teeth 240 can also strengthen the corresponding second cylindrical part 220, and meanwhile, the method has an excellent centering effect, the eccentricity of the cultivation bottle 300 and the eccentricity of the bottle mouth limiting part are prevented, because the cultivation bottle 300 needs to have a larger gap with the second cylindrical part 220, the outer contour of the mouth edge of the cultivation bottle 300 can be hooped through the contracted end wall in the centering process by the convex teeth 240, when the large hooping force is provided, the aperture enclosed by the upper end parts of the convex teeth 240 is smaller, the cultivation bottle 300 cannot move, by adopting the method, the mushroom harvesting frame cannot drop down, meanwhile, the transverse and longitudinal open-movement phenomenon of the cultivation bottle 300 in the cultivation process is prevented, the unstable position caused by the open-movement phenomenon is avoided, and the situations of mushroom damage and flower deformation are avoided.

Meanwhile, the spacing part in the scheme, namely the convex teeth 240 is adopted, in the harvesting bowl 200 provided with the convex teeth 240, the convex teeth 240 are uniformly distributed around the corresponding cultivation bottles 300, the mushrooms in the harvesting bowl 200 are uniformly influenced by the convex teeth 240 in the growth process, because the centering effect of the convex teeth 240, the cultivation bottles 300 tend to be centered, meanwhile, the convex teeth 240 have smaller axial projection area, and the influence on the sides of the mushrooms is smaller, so ventilation and water permeation are facilitated, and therefore, the mushrooms in the harvesting bowl 200 provided with the convex teeth 240 are well produced, and the qualification rate is high.

The side rib plates 110, the middle rib plates 120 and the harvesting bowl 200 can be integrally formed by polyethylene plastic, the forming process is simple, the processing precision is high, and the consistency of the mushroom harvesting frame is good.

In some implementations, the wall of the second cylindrical part 220 located at the edge of the frame body 100 is provided with an edge side reinforcing rib 221 towards the outer side of the frame body 100, the outer end wall of the edge side reinforcing rib 221 is contracted from top to bottom, by adopting the structure, the edge side reinforcing rib 221 can reinforce the second cylindrical part 220 around the frame body 100, the frame body 100 is prevented from touching the damage to the second cylindrical part 220 at the edge of the frame body, meanwhile, the edge side reinforcing rib 221 can be clamped in the first cylindrical part 210 of the mushroom harvesting frame located at the lower part when two mushroom harvesting frames are stacked, and the two mushroom harvesting frames are convenient to store and clamp when stacked, and are convenient to transfer and store in the automatic production process.

Still further, the thickness of limit gusset 110 is less than the height of first cylindric piece 210, limit gusset 110 flushes with first cylindric piece 210 upper end, adopts this structure, has the clearance between the limit gusset 110 of mushroom harvesting frame that stacks, through this clearance, can be convenient for the mushroom harvesting frame that stacks hold when the separation, perhaps overlap the frame machine and separate it.

In some embodiments, the plate body of each middle rib plate 120 located on the side wall of each harvesting hole 130 includes two connection pieces 131, the two connection pieces 131 are arranged at intervals along the extending direction of the middle rib plate 120, a gap is reserved between the opposite ends of the two connection pieces 131, the gap is intersected with the gap reserved between the adjacent first cylindrical parts 210 and forms a cavity 132, the opposite ends of the two connection pieces 131 are respectively provided with a connection rib 133, the laterally extending ends of the two sides of the connection rib 133 are respectively connected with the outer walls of the adjacent first cylindrical parts 210, by adopting the structure, the connection position of each middle rib plate 120 and the harvesting bowl 200 is two connection points spaced, the connection and stress on the harvesting bowl 200 are more dispersed, as shown in fig. 2, the harvesting bowl 200 is connected through eight connection points, stress concentration is prevented, the connection rib 133 has a larger width in the process of taking frames, the adjacent areas of the two harvesting bowls 200 can be contacted with the insert rod and then jacked up, the situation that the narrower contact area is smaller or the contact is unstable is avoided, the stress on the whole rib plate and the stress bowl 200 is more evenly stressed, and the phenomenon of stress concentration caused by stress concentration is avoided. Meanwhile, by adopting the structure, a gap is formed between the two connecting sheets 131, so that the material saving effect can be achieved, and meanwhile, compared with a conventional tangent structure, the gap can avoid the defect that a slit-shaped included angle area is difficult to clean.

Still further, the top of the cavity 132 is closed and connected with a top reinforcing rib 134, through which the cavity 132 can be closed, and the two harvesting bowls 200 and the middle rib plate 120 can be connected to form an integral structure, so that the strength of the mouth edge of the harvesting bowl 200 is higher, and meanwhile, when in integral molding, the die design is facilitated, and the situation of flash and the like during molding can be avoided; of course, the entire cavity 132 also forms a cavity with a downward opening, which is not prone to aggregate.

In the above embodiment, the intersections of the rib plates are connected by the cylindrical nodes, and the phenomenon of stress concentration at the intersections can be avoided by the connection of the cylindrical nodes. The connecting member 230 may be annular or conical, and of course, in this embodiment, the connecting member 230 includes a plurality of spokes 135 distributed around the wall of the cylinder, the proximal end of the spokes 135 is connected with the upper end of the second cylindrical member 220, the distal end of the spokes 135 is connected with the lower end of the first cylindrical member 210, and the adjacent spokes 135 leave a gap in the circumferential direction.

The utility model also provides an embodiment of a mushroom cultivation component, which comprises the mushroom harvesting frame, the cultivation frame 400 and a plurality of cultivation bottles 300, wherein the cultivation bottles 300 are detachably supported in the cultivation frame 400, the cultivation bottles 300 can be directly placed in the cultivation frame 400 or in sockets at the bottoms of the cultivation bottles 300, the upper opening end of each cultivation bottle 300 is sleeved in the harvesting bowl 200 of the mushroom harvesting frame, and the upper opening ends of the cultivation bottles 300 positioned at four corners of the frame 100 are abutted against the convex teeth 240 in the corresponding harvesting bowl 200.

In the cultivation process, after the bud forcing link is completed, arranging the cultivation bottles 300 removed from the bud forcing chamber in the transverse direction and the longitudinal direction of a cultivation basket, sleeving a mushroom harvesting frame above the whole frame of cultivation bottles 300, moving the whole frame of cultivation bottles into a fertility chamber for continuous development, controlling the temperature, the humidity, the concentration of carbon dioxide, the illumination intensity and the time parameter, and completing the fertility link; in harvesting, the harvesting device has upper rows of pins staggered in spatial height and lower rows of pins, e.g., lower rows of pins inserted crosswise into the column gaps of the bottlenecks of adjacent cultivation bottles 300, upper rows of pins inserted correspondingly into the column gaps of the bottlenecks of adjacent cultivation bottles 300, or into the column gaps of the bottlenecks of adjacent cultivation bottles 300. The two rows of the inserting rods are separated in the height direction, so that the mushrooms on the mushroom harvesting frame are integrally separated from the cultivation bottle 300, after harvesting is completed, the mushrooms on the mushroom harvesting frame are grabbed by a manipulator and transferred to a conveying device, and the mushrooms are separated from the mushroom harvesting frame.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the utility model, and it will be apparent to those skilled in the art that various modifications and variations can be made in the present utility model without departing from the spirit and scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (9)

1. A mushroom harvesting frame, characterized by comprising:

the frame body (100) is provided with edge rib plates (110), and a plurality of staggered middle rib plates (120) divide a frame body space surrounded by the edge rib plates (110) into a plurality of harvesting holes (130);

A harvesting bowl (200) disposed within each harvesting hole (130) in correspondence, the harvesting bowl (200) comprising:

A first cylindrical part (210), the outer side wall of which is connected with the inner wall of the harvesting hole (130);

A second cylindrical member (220) coaxially arranged with the first cylindrical member (210), the outer wall of which is connected to the lower section of the first cylindrical member (210) by an outwardly flared connecting member, the axial projection of the second cylindrical member (220) being accommodated within the axial projection of the first cylindrical member (210);

The inner wall of the upper cylinder mouth of the second cylinder (220) of the at least one harvesting bowl (200) is provided with at least three convex teeth (240) uniformly distributed around the cylinder wall, the outer end parts of the convex teeth (240) are connected with the cylinder wall of the second cylinder (220), and the end wall of the inner extending end of the convex teeth (240) is contracted downwards from top to bottom.

2. The mushroom harvesting frame as claimed in claim 1, wherein: the plurality of harvesting holes (130) are distributed in a matrix, and at least three convex teeth (240) uniformly distributed around the cylinder wall are arranged on the inner wall of the upper cylinder opening of the second cylinder part (220) of the harvesting bowl (200) at the four corners of the frame body.

3. The mushroom harvesting frame as claimed in claim 1, wherein: the cylinder wall of the second cylinder (220) positioned at the side of the frame (100) is provided with a side reinforcing rib (221) towards the outer side of the frame (100), and the outer end wall of the side reinforcing rib (221) is contracted from top to bottom.

4. The mushroom harvesting frame as claimed in claim 1, wherein: the middle rib plate (120) is located the plate body of every harvesting hole (130) lateral wall and includes two connection pieces (131), and two connection pieces (131) are along middle rib plate (120) extending direction interval arrangement, keep somewhere the clearance between two connection pieces (131) opposite ends, and this clearance is with keeping somewhere clearance between adjacent first cylindric piece (210) and intersecting and forming cavity (132), and two connection pieces (131) opposite ends all are equipped with connecting rib (133), the tip that connecting rib (133) both sides side direction extends is connected with adjacent first cylindric piece (210) outer wall respectively.

5. The mushroom harvesting frame as claimed in claim 4, wherein: the top of the cavity (132) is connected with a top reinforcing rib (134) in a closed mode.

6. The mushroom harvesting frame as claimed in claim 1, wherein: the intersection of each rib plate is connected through a cylindrical node; the connecting piece comprises a plurality of radial plates (135) distributed around the wall of the cylinder, the proximal end of each radial plate (135) is connected with the upper opening end of the second cylindrical piece (220), the distal end of each radial plate (135) is connected with the lower opening end of the first cylindrical piece (210), and gaps are reserved between the adjacent radial plates (135) in the circumferential direction.

7. A mushroom harvesting frame according to any one of claims 1 or 3, wherein: the thickness of the side rib plate (110) is smaller than the height of the first cylindrical part (210), and the side rib plate (110) is flush with the upper opening end of the first cylindrical part (210).

8. The mushroom harvesting frame as claimed in claim 1, wherein: the side rib plates (110), the middle rib plates (120) and the harvesting bowl (200) are integrally formed.

9. A fungus mushroom cultivation subassembly, its characterized in that: comprising the following steps:

A mushroom harvesting frame according to any one of claims 1-8;

A cultivation frame (400);

A plurality of cultivation bottles (300) in cultivation frame (400) are detachably supported, and the upper mouth end of each cultivation bottle (300) is sleeved into harvesting bowl (200) of fungus mushroom harvesting frame, and the upper mouth ends of cultivation bottles (300) located at four corners of the frame body are abutted with convex teeth (240) in corresponding harvesting bowl (200).