CN210094152U

CN210094152U - Double-layer comprehensive greenhouse

Info

Publication number: CN210094152U
Application number: CN201920875478.7U
Authority: CN
Inventors: 孙树飞; 白京波
Original assignee: Qingzhou Caishen Agricultural Technology Co Ltd; Shandong Siyuan Agricultural Development Co Ltd
Current assignee: Qingzhou Caishen Agricultural Technology Co Ltd; Shandong Siyuan Agricultural Development Co Ltd
Priority date: 2019-06-11
Filing date: 2019-06-11
Publication date: 2020-02-21
Anticipated expiration: 2029-06-11

Abstract

The utility model discloses a double-deck comprehensive formula big-arch shelter belongs to warmhouse booth technical field, include: the heat preservation shed comprises a heat preservation shed, wherein a diagonal draw shed is arranged on the upper side of the heat preservation shed, the diagonal draw shed and the heat preservation shed are jointly connected with a plurality of main stand columns, the diagonal draw shed and the heat preservation shed both comprise shed films, the main stand columns are arranged in a row at a certain interval and fixed on the ground, and a main beam is connected between every two adjacent main stand columns; the inclined pull-up shed comprises an inclined pull beam, one end of the inclined pull beam is fixedly connected with the main upright post or the main beam, and the other end of the inclined pull beam is directly or indirectly fixed on the ground, the upper side of the inclined pull beam and a plurality of inclined pull cables are connected between the main upright posts, so that the situation that the heat insulation material on the heat insulation shed is wetted by rain, is blown down by wind, is covered by snow can be avoided, the labor capacity of farmers is reduced, the service life of the heat insulation material is prolonged, a heat insulation space can be formed between the inclined pull shed and the heat insulation shed, the heat insulation effect is better, and the cost is effectively reduced.

Description

Double-layer comprehensive greenhouse

Technical Field

The utility model belongs to the technical field of warmhouse booth, concretely relates to double-deck comprehensive formula big-arch shelter.

Background

Millions of greenhouses become main production sources of vegetables and fruits of people, the greenhouses in the prior art are single-layer greenhouse films, heat insulation materials cover the upper sides of the greenhouse films, the heat insulation materials are not prone to being dried after being wetted by rain, snow needs to be swept after snow falls, the labor capacity of farmers is large, and after the greenhouse films are long time, the heat insulation effect of the heat insulation materials can be reduced, the greenhouse films need to be replaced, and the cost is high. For carrying out effectual protection utility model double-layer greenhouse to insulation material, among the current double-layer greenhouse, owing to need dodge the insulation material on the inner greenhouse, the vertical support of outer big-arch shelter is few, and bearing structure realizes through horizontal frame basically, and horizontal span is big, for guaranteeing its support intensity moreover, the structure is more complicated, and is with high costs to can shelter from sunshine, influence the photosynthesis of below vegetables.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: the utility model provides a double-deck comprehensive formula big-arch shelter can avoid insulation material's damage, and it is effectual to keep warm, effective reduce cost.

In order to solve the technical problem, the technical scheme of the utility model is that:

a double-deck integrated greenhouse comprising: the heat preservation shed comprises a heat preservation shed, wherein a diagonal draw shed is arranged on the upper side of the heat preservation shed, the diagonal draw shed and the heat preservation shed are jointly connected with a plurality of main stand columns, the diagonal draw shed and the heat preservation shed both comprise shed films, the main stand columns are arranged in a row at a certain interval and fixed on the ground, and a main beam is connected between every two adjacent main stand columns; the inclined pull shed comprises an inclined pull beam, one end of the inclined pull beam is fixedly connected with the main column or the main beam, the other end of the inclined pull beam is directly or indirectly fixed on the ground, and a plurality of inclined pull cables are connected between the upper side of the inclined pull beam and the main column.

Furthermore, the inclined pull-up shed further comprises a plurality of supporting beams which are parallel to each other, one end of each supporting beam is connected to the main beam, the other end of each supporting beam is directly or indirectly fixed to the ground, and the supporting beams are parallel to the inclined pull beams.

Furthermore, adjacent between the supporting beam and adjacent supporting beam with all fixedly connected with many tie-beams between the oblique straining beam, the tie-beam with the girder is parallel.

Furthermore, the main upright post consists of two independent upright posts.

Furthermore, the two independent upright columns are parallel or the upper ends of the two independent upright columns form a triangular structure.

Furthermore, the double-layer comprehensive greenhouse is a single-slope greenhouse, an anchor is arranged on the ground on one side of the double-layer comprehensive greenhouse, and the main upright posts are connected with the anchor through fixing cables.

Furthermore, an underground working space is arranged below the double-layer comprehensive greenhouse and is communicated with the ground through a ventilation channel, an access channel and an emergency escape channel.

Furthermore, a fire-fighting water bag is arranged in the underground working space.

Further, the underground working space comprises one or more side-by-side circular or semicircular pipes.

Furthermore, a water pool is arranged in the double-layer comprehensive greenhouse and communicated with fire-fighting facilities in the underground working space.

After the technical scheme is adopted, the beneficial effects of the utility model are that:

because the utility model discloses a double-deck integrated type big-arch shelter includes: the upper side of the heat preservation shed is provided with a diagonal draw shed, the diagonal draw shed and the heat preservation shed are jointly connected with a plurality of main stand columns, the diagonal draw shed and the heat preservation shed both comprise shed films, the main stand columns are arranged in a row at a certain interval and fixed on the ground, and a main beam is connected between every two adjacent main stand columns; the inclined pull-up shed comprises an inclined pull beam, one end of the inclined pull beam is fixedly connected to the main upright post or the main beam, the other end of the inclined pull beam is directly or indirectly fixed to the ground, a plurality of inclined pull cables are connected between the upper side of the inclined pull beam and the main upright post, the inclined pull beam can prevent heat insulation materials on the heat insulation shed from being wetted by rain, blown over by wind and covered by snow, the labor capacity of farmers can be reduced, the service life of the heat insulation materials can be prolonged, the cost is low, a heat insulation space can be formed between the inclined pull beam and the heat insulation shed, the heat insulation effect is better, and the cost is effectively reduced.

Drawings

Fig. 1 is a schematic structural view of a first embodiment of the double-layer integrated greenhouse of the present invention;

fig. 2 is a schematic top view of a first embodiment of the double-layered integrated greenhouse of the present invention;

fig. 3 is a schematic structural view of the inside of the first embodiment of the double-layer integrated greenhouse of the present invention;

fig. 4 is a schematic structural diagram of a second embodiment of the double-layer integrated greenhouse of the present invention;

fig. 5 is a schematic structural view of a third embodiment of the double-layer integrated greenhouse of the present invention;

in the figure, 10-main upright post, 101-independent upright post, 11-diagonal tension beam, 12-diagonal tension cable, 13-shed film, 14-main beam, 15-connecting beam, 16-fixing cable, 17-anchoring, 18-vent, 19-supporting beam, 20-heat preservation shed, 21-steel beam, 22-auxiliary upright post, 23-heat preservation quilt, 24-vent, 25-inner shed film, 26-connecting shed, 30-wall, 31-underground working space, 32-access channel, 33-ventilation channel, 34-pipeline channel, 35-fire-fighting water sac, 36-pool, 37-emergency escape channel, 38-access platform and 39-rainproof heat preservation cover.

Detailed Description

The present invention will be further explained with reference to the drawings and examples.

All directions referred to in the present specification are based on the drawings, and represent relative positional relationships only, and do not represent absolute positional relationships.

The first embodiment is as follows:

as shown in fig. 1 and fig. 2, a double-layer integrated greenhouse comprises: the heat preservation shed 20, the upside of heat preservation shed 20 is provided with to draw the canopy to one side. Draw canopy and thermal-insulation shed 20 to one side and be connected with many head pillars 10 jointly, draw canopy and thermal-insulation shed 20 to one side all including canopy membrane 13, many head pillars 10 are arranged into one row and are fixed subaerial according to a determining deviation. A main beam 14 is connected between the adjacent main columns 10, can support the main columns 10 and can also be used as a pedestrian operation channel. The inclined pull shed comprises inclined pull beams 11, one ends of the inclined pull beams 11 are fixedly connected to main columns 10 or main beams 14, the other ends of the inclined pull beams 11 are directly or indirectly fixed to the ground, a plurality of inclined pull cables 12 are connected between the upper sides of the inclined pull beams 11 and the main columns 10, and the main columns 10 can be connected with different inclined pull beams 11 through the inclined pull cables 12. The heat preservation canopy 20 coats and is stamped insulation material, and the inclined pull canopy can avoid insulation material by the rain drench, by wind blow turn over, by the snow condition of covering, need not carry out the sunning, reducible peasant household amount of labour to extension insulation material's life, and stay cable 12 can effectively support and draw 1 to one side, and the cost is lower, can form a heat preservation space between inclined pull canopy and the heat preservation canopy 20 simultaneously, therefore the heat preservation effect is better.

As shown in fig. 2, the cable-stayed shelter includes a plurality of mutually parallel support beams 19, one end of each support beam 19 is connected to the main beam 14, the other end is directly or indirectly fixed to the ground, and the support beams 19 are parallel to the cable-stayed beams 11. The inclined shed further comprises a plurality of connecting beams 15 which are parallel to each other, the connecting beams 15 are fixedly connected between the adjacent supporting beams 19 and the inclined pulling beams 11, the connecting beams 15 are parallel to the main beams 14, and effective support can be formed on a shed film 13 covering the inclined shed. The cable-stayed shed can be of a flat structure or an arch structure bent upwards, and the corresponding cable-stayed beam 11 and the corresponding supporting beam 19 can be of a straight structure or an arc structure bent upwards.

As shown in fig. 1 and 2, the stay beam 11 is provided with a fixing point for connecting the stay cable 12, and the stay cable 12 is movably connected to the fixing point. The canopy membrane 13 of oblique pull canopy passes through the card membrane groove and pulls a canopy swing joint to one side, moves back from the top down when going up the membrane, and in fixed point department, canopy membrane 13 passes through the cushion fastening on oblique pull canopy. Install the fan 24 of putting on the main upright post 10 in the big-arch shelter, cover the canopy membrane 13 on drawing the canopy to one side and seted up the wind gap 18, the canopy membrane 13 that is located wind gap 18 department passes through the press mold rope to be fixed on drawing the canopy to one side, it sets up in one side that canopy membrane 13 is close to main upright post 10 to put wind gap 18, be located the top of fan 24 promptly, the canopy membrane 13 that puts wind gap 18 department can set up to multiple mode, if parallel pull open, also can be by one side upwards upset open, thereby can also be that the rotation of middle part connection revolution mechanic opens. The shed film 13 covering the diagonal sheds can adopt a shed film 13 with high light transmittance and long service life.

As shown in fig. 3, the thermal insulation shed 20 includes a steel beam 21 with one end connected to the main upright post 10 and the other end fixed on the ground, and a plurality of auxiliary upright posts 22 for supporting are further connected to the lower side of the steel beam 21, so as to effectively support the thermal insulation material on the thermal insulation shed 20, wherein the thermal insulation material is a thermal insulation quilt 23. The heat preservation quilt 23 is movably arranged on the heat preservation shed 20 and can be pulled or rolled up to increase the illumination of vegetables. In summer, the heat preservation shed 20 can be covered with a sunshade net to avoid the damage of vegetables caused by over-strong illumination. The lower side of the heat preservation shed 20 can be provided with an inner layer shed film 25, and the cold-intolerant vegetables can be planted in the inner layer shed film 25, so that the survival rate is improved.

As shown in fig. 1 and fig. 3, an underground working space 31 is further provided below the double-layer integrated greenhouse, the underground working space 31 includes a circular pipeline or a semicircular pipeline, and the underground working space 31 is of a thin-shell structure and can bear a larger pressure to ensure the stability of the structure. Wherein, the round pipeline and the semicircular pipeline can be concrete round pipes, and the manufacturing cost is low. The underground working space 31 is positioned under the planting area, can block the infiltration of pollutants such as chemical fertilizers in the greenhouse and the like, and plays a role in protecting underground water. Can be used to plant behind the earth flattening of secret workspace 31 top, be provided with the soil layer more than a meter in secret workspace 31 top, as the nutrient supply of crop moisture, can not cause the influence to the growth of vegetables. And the underground working space 31 is warm in winter and cool in summer, saves energy and protects environment, thereby conforming to the trend of the times.

As shown in fig. 1 and fig. 2, the double-layer integrated greenhouse can be a single-slope greenhouse, and further comprises a wall 30, the wall 30 and the heat preservation greenhouse 20 are connected to two sides of the main upright post 10 respectively, the main upright post 10 is connected to the other side of the diagonal greenhouse 11, a connection greenhouse 26 is installed, the lower side of the connection greenhouse 26 is connected to the wall 30, and a heat preservation space is enclosed by the connection greenhouse 26, the diagonal greenhouse, the heat preservation greenhouse 20 and the wall 30. The side of the wall 30 far away from the center of the greenhouse is provided with an anchor 17, and the main upright post 10 is connected with the anchor 17 through a fixed cable 16. The walls 30 may be constructed from earth dug from the ground, and the underground working space 31 is provided in a deep trench formed by the dug earth. Because the underground working space 31 is arranged in the deep groove formed by the building wall 30, the ground in the greenhouse is not lower than the external ground, so that the irrigation condition can not occur in the rainy period, and the property safety of farmers is ensured. Wherein, the depth range of the deep groove formed after digging out the soil is 6-8 meters, and can be properly adjusted according to the construction requirements.

As shown in fig. 1 and 3, the underground working space 31 is communicated with the ground through the ventilation channel 33, the access channel 32 and the emergency escape channel 37, so that the problem of insufficient land construction resources is solved, and the cost is effectively reduced. The underground working space 31 is provided with an access, a ventilation opening and an emergency escape opening, the access is communicated with the access passage 32, the ventilation opening is communicated with the ventilation passage 33, the emergency escape opening is communicated with the emergency escape passage 37, and the ventilation opening is arranged at the upper end of the underground working space 31. Be provided with fire-fighting water bag 35 and pipeline way 34 in the underground working space 31, the upper end of underground working space 31 is provided with the accommodation space, and fire-fighting water bag 35 sets up in the accommodation space, and pipeline way 34 sets up the lower extreme at underground working space 31, and pipeline way 34 includes the circuit pipeline, still is provided with the fire-fighting equipment with 7 intercommunications of fire-fighting water bag in the working space 3, and the fire-fighting equipment includes fire-fighting pipeline and shower nozzle.

As shown in fig. 3, the underground passageway is arranged at one end of the underground working space 31, an overground passageway is arranged on the wall 30 close to the end of the underground passageway, an access platform 38 is further arranged on one side of the wall 30 away from the center of the greenhouse, the access platform 38 is communicated with the access channel 32, the access channel 32 is respectively communicated with the overground passageway and the underground passageway, the greenhouse or the underground working space 31 can be accessed through the access platform 38, the overground passageway and the underground passageway are comprehensively arranged, materials can be saved, and the construction is convenient and space can be saved. The access passage 32 can be constructed by hollowing out the wall 32 constructed by soil, and the wall 32 can also be constructed by masonry and concrete, so that the stability is enhanced. A rainproof insulation cover 39 which can cover the access passage 32 is arranged between the access platform 38 and the wall 30, so as to avoid heat dissipation in the access passage 32.

As shown in fig. 3, a pool 36 can be further arranged in the double-layer comprehensive greenhouse, the pool 36 is communicated with the fire-fighting equipment in the underground working space 31, the pool 36 can provide a water source for the fire-fighting equipment, is used for guaranteeing fire safety, and can be used for fish culture and providing a water source for vegetables, wherein the pool 36 is provided with two pools which are respectively arranged at two ends of the greenhouse, and the two ends of the greenhouse wall 30 can shield sunlight and are not suitable for planting vegetables, so that the comprehensive utilization of the space can be enhanced.

Example two:

this embodiment is basically the same as the second embodiment, but differs therefrom in that:

as shown in fig. 4, the double-layer integrated greenhouse is an arched greenhouse, the oblique tension beams 11 are symmetrically arranged on both sides of the main column 10, and the main column 10 and the oblique tension beams 11 on both sides are symmetrically connected by the oblique tension cables 12, so that the stability of the main column 10 can be ensured. The underground workspace 31 may include a plurality of side-by-side circular or semi-circular pipes, though there is more space available.

Example three:

this embodiment is basically the same as the third embodiment, but differs therefrom in that:

as shown in fig. 5, the main upright 10 is composed of two independent uprights 101, the two independent uprights 101 are parallel or the upper ends of the two independent uprights 101 form a triangular structure, the two independent uprights 101 can form a triangular structure with the ground or the upper ends of the two independent uprights 101 and the main beam 14 form a triangular structure, in this embodiment, the two independent uprights 101 and the ground preferably form a triangular structure, the top ends of the two independent uprights 101 are connected, the two independent uprights 101 are respectively located at two sides of the main beam 14, the inclined pull sheds, the thermal insulation sheds 20 and the inclined pull cables 12 at the two sides are respectively connected to the two independent uprights 101, so that the structural strength can be enhanced, a walkway can be formed between the two independent uprights 101.

The utility model discloses a double-deck comprehensive formula big-arch shelter is through setting up the oblique pull-up canopy at the upside of heat preservation canopy, and the pull-up canopy is fixed on the head tree by the suspension cable to one side, and the insulation material that the oblique pull-up canopy can avoid on the heat preservation canopy is drenched by the rain, is blown by the wind and turns over, by the condition that snow covered, reducible peasant household amount of labour to extension insulation material's life, the cost is lower, still can form a heat preservation space between oblique pull-up canopy and the heat preservation canopy, and the heat preservation effect is better, effectively the cost is reduced.

Although specific embodiments of the present invention have been described above, it should be understood by those skilled in the art that the described embodiments are only some of the embodiments of the present invention, rather than all embodiments, which are given by way of illustration only, and the scope of the present invention is defined by the appended claims. Without any inventive step, those skilled in the art can make various changes or modifications to the embodiments without departing from the spirit and scope of the present invention.

Claims

1. A double-deck integrated greenhouse comprising: the heat preservation shed is characterized in that a diagonal shed is arranged on the upper side of the heat preservation shed, the diagonal shed and the heat preservation shed are jointly connected with a plurality of main stand columns, the diagonal shed and the heat preservation shed both comprise shed films, the main stand columns are arranged in a row at a certain interval and fixed on the ground, and a main beam is connected between every two adjacent main stand columns;

the inclined pull shed comprises an inclined pull beam, one end of the inclined pull beam is fixedly connected with the main column or the main beam, the other end of the inclined pull beam is directly or indirectly fixed on the ground, and a plurality of inclined pull cables are connected between the upper side of the inclined pull beam and the main column.

2. The double-layer integrated greenhouse of claim 1, wherein the cable-stayed greenhouse further comprises a plurality of mutually parallel support beams, one end of each support beam is connected to the main beam, the other end of each support beam is directly or indirectly fixed on the ground, and the support beams are parallel to the diagonal draw beams.

3. The double-deck comprehensive greenhouse of claim 2, wherein a plurality of connecting beams are fixedly connected between the adjacent supporting beams and the diagonal draw beams, and the connecting beams are parallel to the main beams.

4. The double-deck integrated greenhouse of claim 1, wherein the main column is comprised of two independent columns.

5. The double-layer integrated greenhouse of claim 4, wherein the two independent columns are parallel or the upper ends of the two independent columns form a triangular structure.

6. The double-layer comprehensive greenhouse of claim 1, wherein the double-layer comprehensive greenhouse is a single-slope greenhouse, an anchor is arranged on the ground on one side of the double-layer comprehensive greenhouse, and the main upright posts are connected with the anchor through fixing cables.

7. The double-layer comprehensive greenhouse of claim 1, wherein an underground working space is arranged below the double-layer comprehensive greenhouse, and the underground working space is communicated with the ground through a ventilation channel, an access channel and an emergency escape channel.

8. The double-layer integrated greenhouse of claim 7, wherein a fire-fighting water bag is arranged in the underground working space.

9. The double-deck integrated greenhouse of claim 7, wherein the underground working space comprises one or more side-by-side circular or semi-circular pipes.

10. The double-layer integrated greenhouse of claim 7, wherein a water pool is arranged in the double-layer integrated greenhouse, and the water pool is communicated with fire-fighting facilities in the underground working space.