CN221689550U - A warm greenhouse for growing edible fungi - Google Patents

Abstract

The utility model discloses a heat preservation greenhouse for growing edible fungi, the structure of which includes a heat preservation chamber shell and a chamber door, the chamber door and the front of the heat preservation chamber shell are rotatably connected by a hinge, and also includes a circulating humidification mechanism, a heating mechanism and a ventilation mechanism, the circulating humidification mechanism is arranged at the lower side of the heat preservation chamber shell, the circulating humidification mechanism includes a water tank and a spray pipe, the water tank is arranged outside the heat preservation chamber shell, the spray pipe is fixedly connected to the inside of the heat preservation chamber shell and penetrates the heat preservation chamber shell, the outer end of the spray pipe is connected to a water pump, the other end of the water pump is connected to the water tank, the lower part of the heat preservation chamber shell is provided with a water collection channel, the water collection channel is arranged at a position below the spray pipe, one end of the water collection channel is provided with a drain, one end of the drain is connected to the heat preservation chamber shell, and the other end of the drain is connected to the water tank. The utility model belongs to the field of edible fungi cultivation, and specifically refers to a heat preservation greenhouse for growing edible fungi.

Description

A warm greenhouse for growing edible fungi

Technical Field

The utility model belongs to the field of edible fungi, and specifically refers to a warm-keeping greenhouse for growing edible fungi.

Background Art

To cultivate edible fungi, we need to pay attention to the preparation of the substrate, temperature control, shading measures and humidity control. The substrate should be wood fiber sawdust, cottonseed hulls, corn cobs, etc. The temperature should be controlled at around 24-27 degrees Celsius, and the shading work should be done thoroughly. Most edible fungi like to live in a relatively humid environment. They do not need artificial watering and only survive by absorbing moisture in the air and the substrate. Therefore, we must ensure that the air humidity around the container for cultivating edible fungi is large enough to provide sufficient water supply for the edible fungi.

Existing warm greenhouses for edible fungi can provide a shaded, humid and warm environment for edible fungi, but most greenhouses can only provide indoor heating. In order to ensure the shading effect, the cooling process is slow when the temperature is high. When the temperature is high for a long time, the growth rate of edible fungi will also be reduced. In order to ensure the humidity of the growth environment of edible fungi, most greenhouses use spraying humidification treatment for edible fungi. However, direct spraying can easily cause the humidity of the growth environment to be too high, which will also affect the growth rate of edible fungi.

Therefore, we propose a warm greenhouse for growing edible fungi to solve the above problems.

Utility Model Content

In view of the above situation, in order to overcome the defects of the prior art, the utility model provides a warm greenhouse for growing edible fungi, which avoids the problem of excessive humidity caused by spraying affecting the growth rate of edible fungi, and solves the problem of excessive temperature and slow cooling affecting the growth rate of edible fungi.

The technical solution adopted by the utility model is as follows: the warm greenhouse for growing edible fungi proposed by the utility model includes an insulation chamber shell and a chamber door, the chamber door and the front part of the insulation chamber shell are rotatably connected by a hinge, and also includes a circulating humidification mechanism, a heating mechanism and a ventilation mechanism, the circulating humidification mechanism is arranged at the lower part of the side of the insulation chamber shell, the circulating humidification mechanism includes a water tank and a spray pipe, the water tank is arranged outside the insulation chamber shell, the spray pipe is fixedly connected to the inside of the insulation chamber shell and penetrates the insulation chamber shell, the outer end of the spray pipe is connected to a water pump, and the other end of the water pump is connected to the water tank, the lower part of the insulation chamber shell is provided with a water collection channel, the water collection channel is arranged below the spray pipe, one end of the water collection channel is provided with a drain outlet, one end of the drain outlet is penetrated and connected to the insulation chamber shell, and the other end of the drain outlet is penetrated and connected to the water tank.

Furthermore, the heating mechanism is arranged at the lower side of the outer shell of the insulation chamber, and the heating mechanism includes an air inlet pipe and an air inlet. The air inlet is arranged at the lower side of the outer shell of the insulation chamber and passes through the outer shell of the insulation chamber. One end of the air inlet pipe is connected to the air inlet, and the other end of the air inlet pipe is connected to an exhaust fan. An exhaust pipe is provided at the outer end of the exhaust fan, a heating net is provided on the air inlet, and a thermometer is provided on the inner side of the outer shell of the insulation chamber.

Furthermore, a water inlet is provided at the upper portion of the water tank, a spray port is provided at the lower portion of the spray pipe, and the spray port is arranged above the air inlet.

Furthermore, the ventilation mechanism is arranged at the upper side of the insulation chamber shell, and the ventilation mechanism includes a ventilation fan, a sealing door, and a vent. The vent is arranged at the upper side of the insulation chamber shell and penetrates the insulation chamber shell. The ventilation fan is arranged in the vent, and the sealing door and the vent are rotatably connected by a hinge.

Furthermore, an illumination lamp is provided on the upper inner part of the outer shell of the insulation chamber, and illumination lamps are provided on both the left and right sides of the outer shell of the insulation chamber.

Furthermore, a cultivation rack is provided in the insulation chamber shell, the cultivation rack is fixedly connected to the lower part of the insulation chamber shell, the cultivation rack is configured as a multi-layer structure, a plurality of cultivation boxes are provided on the cultivation rack, and the cultivation boxes are slidably connected to the cultivation rack.

The beneficial effects achieved by the utility model using the above structure are as follows:

1. The warm greenhouse for growing edible fungi proposed in this scheme increases the humidity inside the outer shell of the warm greenhouse by setting a circulating humidification mechanism, spraying through the spray port and blowing hot air heated by the heating net without directly spraying the cultivation box, so as to facilitate the edible fungi to directly absorb the moisture in the air, increase the moisture absorption rate of the edible fungi, and avoid directly spraying the edible fungi, which may slow down the growth rate of the edible fungi.

2. The warm greenhouse for growing edible fungi proposed in this scheme can quickly raise the temperature inside the outer shell of the insulation chamber to the required cultivation speed through the heating network through the cooperation of the heating mechanism and the ventilation mechanism. When the internal temperature is observed to be inappropriate through the thermometer, the outer shell of the insulation chamber can be quickly cooled down through the ventilation fan, which is convenient for ensuring the constant temperature inside the outer shell of the insulation chamber and the growth rate of the edible fungi.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of a first overall structure of the utility model;

FIG2 is a first overall cross-sectional schematic diagram of the present invention;

FIG3 is a second overall cross-sectional schematic diagram of the present invention;

FIG4 is a schematic diagram of a second overall structure of the present invention;

FIG5 is a third overall structural schematic diagram of the utility model.

Among them, 1. insulation room shell, 2. circulating humidification mechanism, 201. water pump, 202. water tank, 203. water inlet, 204. drain outlet, 205. water collection channel, 206. spray pipe, 207. spray outlet, 3. heating mechanism, 301. air inlet pipe, 302. exhaust fan, 303. exhaust pipe, 304. heating net, 305. air inlet, 4. ventilation mechanism, 401. ventilation fan, 402. sealing door, 403. vent, 5. cultivation rack, 6. cultivation box, 7. room door, 8. thermometer, 9. lighting lamp.

The accompanying drawings are used to provide a further understanding of the present invention and constitute a part of the specification. They are used together with the embodiments of the present invention to explain the present invention and do not constitute a limitation to the present invention.

DETAILED DESCRIPTION

The technical solutions in the embodiments of the utility model will be clearly and completely described below in conjunction with the drawings in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, rather than all of the embodiments; based on the embodiments of the utility model, all other embodiments obtained by ordinary technicians in this field without making creative work are within the scope of protection of the utility model.

As shown in Figures 1, 2 and 3, the utility model proposes a warm greenhouse for growing edible fungi, including a heat preservation greenhouse shell 1 and a door 7, the door 7 and the front of the heat preservation greenhouse shell 1 are rotatably connected by a hinge, and also includes a circulating humidification mechanism 2, a heating mechanism 3 and a ventilation mechanism 4, the circulating humidification mechanism 2 is arranged at the lower side of the heat preservation greenhouse shell 1, the circulating humidification mechanism 2 includes a water tank 202 and a spray pipe 206, the water tank 202 is arranged outside the heat preservation greenhouse shell 1, the spray pipe 20 6 is fixedly connected to the interior of the insulation chamber shell 1 and penetrates the insulation chamber shell 1, the outer end of the spray pipe 206 is connected to the water pump 201, and the other end of the water pump 201 is connected to the water tank 202. A water collecting channel 205 is provided at the lower part of the insulation chamber shell 1, and the water collecting channel 205 is arranged below the spray pipe 206. A drain outlet 204 is provided at one end of the water collecting channel 205, and one end of the drain outlet 204 is connected to the insulation chamber shell 1 through the other end of the drain outlet 204 is connected to the water tank 202 through the other end.

As shown in Figures 1, 2 and 3, the heating mechanism 3 is arranged at the lower side of the insulation chamber shell 1, and the heating mechanism 3 includes an air inlet pipe 301 and an air inlet 305. The air inlet 305 is arranged at the lower side of the insulation chamber shell 1 and penetrates the insulation chamber shell 1. One end of the air inlet pipe 301 is connected to the air inlet 305, and the other end of the air inlet pipe 301 is connected to an exhaust fan 302. An exhaust pipe 303 is provided at the outer end of the exhaust fan 302. A heating network 304 is provided on the air inlet 305. A thermometer 8 is provided on the inner side of the insulation chamber shell 1 to heat the inside of the insulation chamber shell 1 to ensure a constant temperature in the insulation chamber shell 1. A water inlet 203 is provided at the upper part of the water tank 202, and a spray port 207 is provided at the lower part of the spray pipe 206. The spray port 207 is arranged above the air inlet 305.

As shown in Figure 5, the ventilation mechanism 4 is arranged at the upper side of the insulation chamber shell 1, and the ventilation mechanism 4 includes a ventilation fan 401, a sealing door 402, and a vent 403. The vent 403 is arranged at the upper side of the insulation chamber shell 1 and penetrates the insulation chamber shell 1. The ventilation fan 401 is arranged in the vent 403, and the sealing door 402 and the vent 403 are rotatably connected by a hinge. When the temperature inside the insulation chamber shell 1 is too high, the interior of the insulation chamber shell 1 is exhausted and cooled, so as to avoid the temperature inside the insulation chamber shell 1 being too high.

As shown in FIG. 2 , FIG. 3 and FIG. 4 , a lighting lamp 9 is provided on the upper inner part of the insulation chamber shell 1 , and lighting lamps 9 are provided on both the left and right sides of the insulation chamber shell 1 for illuminating the interior of the insulation chamber shell 1 when personnel enter the insulation chamber shell 1 .

As shown in Figure 1, a cultivation rack 5 is provided in the insulation chamber shell 1, and the cultivation rack 5 is fixedly connected to the lower part of the insulation chamber shell 1. The cultivation rack 5 is set as a multi-layer structure, and a plurality of cultivation boxes 6 are provided on the cultivation rack 5. The cultivation boxes 6 and the cultivation rack 5 are slidably connected. Most edible fungi grow faster in the absence of light, and multi-layer cultivation can make more effective use of the space of the insulation chamber shell 1.

During specific use, the cultivation box 6 in which the edible fungi are cultivated is pushed onto the cultivation rack 5 along the shelves on the cultivation rack 5, the sealing door 402 is rotated to close the vent 403, the ventilation fan 401 is turned off, water is injected into the water tank 202 through the water inlet 203, the water pump 201 is started to extract the water in the water tank 202, and the water is sprayed inside the insulation chamber shell 1 from the spray port 207 through the spray pipe 206. The spray water begins to evaporate and evaporate under the hot air heated by the heating network 304, humidifying the air in the insulation chamber shell 1, so that the edible fungi on the cultivation box 6 can absorb water for growth, and the outflowing spray water flows into the water tank 202 from the drain port 204 along the water collection channel 205 for continued use, thereby saving water resources.

Start the exhaust fan 302 to draw air from the exhaust pipe 303, and the air reaches the air inlet 305 through the air inlet pipe 301, and start the heating network 304 to heat the air sucked by the exhaust fan 302 and enter the interior through the air inlet 305, so as to quickly heat the interior of the insulation chamber shell 1. The real-time temperature in the insulation chamber shell 1 can be observed by the thermometer 8. When the temperature is high, turn and open the sealing door 402, and start the ventilation fan 401 to discharge the hot air in the insulation chamber shell 1, so as to cool down the interior of the insulation chamber shell 1, so as to more quickly ensure the constant temperature inside the insulation chamber shell 1 and ensure the growth rate of the edible fungi in the insulation chamber shell 1.

The above describes the utility model and its implementation methods, which are not restrictive. The drawings show only one implementation method of the utility model, and the actual structure is not limited thereto. In short, if ordinary technicians in this field are inspired by it and design structural methods and embodiments similar to the technical solution without creativity without departing from the purpose of the invention of the utility model, they should all fall within the protection scope of the utility model.

Claims (6)

1. The utility model provides a plant domestic fungus with cold-proof greenhouse, includes cold-proof housing and room door, room door and cold-proof housing front portion are through hinge rotation connection, its characterized in that: still include circulation humidification mechanism, heating mechanism and ventilation mechanism, circulation humidification mechanism locates heat preservation housing side lower part, circulation humidification mechanism includes water tank and shower, the outside of heat preservation housing is located to the water tank, inside rigid coupling of shower and heat preservation housing just runs through the heat preservation housing, the shower outer end is connected with the water pump, the water pump other end is connected with the water tank, heat preservation housing lower part is equipped with the catchment way, the catchment way is located shower below position, catchment way one end is equipped with the outlet, outlet one end and heat preservation housing through connection, outlet other end and water tank through connection.

2. The warmth-keeping greenhouse for edible fungi planting according to claim 1, wherein: the heating mechanism is arranged at the lower part of the side edge of the heat preservation chamber housing and comprises an air inlet pipe and an air inlet, the air inlet is arranged at the lower part of the side edge of the heat preservation chamber housing and penetrates through the heat preservation chamber housing, one end of the air inlet pipe is connected with the air inlet, the other end of the air inlet pipe is connected with an exhaust fan, the outer end of the exhaust fan is provided with an exhaust pipe, a heating net is arranged on the air inlet, and a thermometer is arranged at the inner side of the heat preservation chamber housing.

3. The warmth-keeping greenhouse for edible fungi planting according to claim 2, wherein: the upper part of the water tank is provided with a water inlet, the lower part of the spray pipe is provided with a spray opening, and the spray opening is arranged at the upper position of the air inlet.

4. A warmth-keeping greenhouse for edible fungi planting according to claim 3, wherein: the ventilation mechanism is arranged at the side edge of the heat preservation chamber housing and comprises a ventilation fan, a sealing door and a ventilation opening, wherein the ventilation opening is arranged at the side edge of the heat preservation chamber housing and penetrates through the heat preservation chamber housing, the ventilation fan is arranged in the ventilation opening, and the sealing door is connected with the ventilation opening through a hinge in a rotating mode.

5. The warmth-keeping greenhouse for edible fungi planting according to claim 4, wherein: the upper portion of the inner side of the heat preservation chamber shell is provided with an illuminating lamp, and the left side and the right side of the heat preservation chamber shell are provided with the illuminating lamps.

6. The warmth-keeping greenhouse for edible fungi planting according to claim 5, wherein: the cultivation frame is arranged in the heat preservation housing, the cultivation frame is fixedly connected with the lower portion of the heat preservation housing, the cultivation frame is of a multi-layer structure, a plurality of groups of cultivation boxes are arranged on the cultivation frame, and the cultivation boxes are connected with the cultivation frame in a sliding mode.