CN205755703U - A kind of edible fungus culturing is with solar powered energy-conservation booth - Google Patents

Abstract

This utility model relates to a kind of planting greenhouse, discloses a kind of solar powered energy-conservation booth of edible fungus culturing.Described edible fungus culturing includes booth, cold water source device, water pump, blower fan cascade, back pool, solar photovoltaic generation system with solar powered energy-conservation booth；Described blower fan cascade is arranged in booth；Described cold water source device, water pump are connected with blower fan cascade by water-supply-pipe；It is provided with the first valve between described cold water source device and water pump；Described back pool is connected by drain pipe with blower fan cascade；Described back pool is connected with water feeding of water pump water-supply-pipe, is provided with the second valve between described back pool and water feeding of water pump water-supply-pipe；Described solar photovoltaic generation system is arranged on booth ceiling, and described solar photovoltaic generation system is connected with the blower fan in water pump, blower fan cascade, the first valve, the second valve.Described edible fungus culturing achieves photovoltaic generation with solar powered energy-conservation booth and planting edible mushroom combines, and improves land utilization ratio.

Description

A kind of edible fungus culturing is with solar powered energy-conservation booth

Technical field

This utility model relates to a kind of planting greenhouse, more particularly, to a kind of edible fungus culturing with solar powered energy-conservation booth.

Background technology

At present, the production of China's most area edible fungi is generally concentrated at spring autumn and winter these three low temperature season season, and high temperature season seldom fruiting in summer, this with edible fungi growth required for environmental condition be inseparable.The environmental condition affecting edible fungi growth mainly includes the conditions such as temperature, humidity, illumination, air and ventilation.Temperature is one of topmost environmental condition of edible fungi growth growth, and different kinds is in different growth and development stages, the most different to temperature requirement.General mycelial growth demands temperature is higher, and at 20～26 DEG C, the temperature of sporophore growth demands is relatively low, typically at 13～18 DEG C.The time of bacterium, the time of fruiting and quality are sent out in the height impact of temperature, and therefore temperature decides success or failure and the economic benefit of production.Additionally, humidity is also one of key factor affecting edible fungi growth.In the mycelial growth stage, relative air humidity to be advisable below 75%；In the fruiting stage, it is desirable to relative air humidity is more than 90%.In summer, China's most area sweltering heat is dried, and temperature is general all more than 30 DEG C, and there will be " burning spore " phenomenon when edible fungi grows at this temperature, causes the yield underproduction even to be had no harvest.As used the refrigeration plants such as air-conditioning to force to cool to air in booth, work capacity consumes relatively big, and production cost is high.

Summary of the invention

The purpose of this utility model is to solve problem of the prior art, it is provided that a kind of edible fungus culturing is with solar powered energy-conservation booth.

This utility model is achieved by following technical solution:

A kind of edible fungus culturing is with solar powered energy-conservation booth, including booth, cold water source device, water pump, blower fan cascade, back pool, solar photovoltaic generation system；

Described blower fan cascade is arranged in booth；

Described cold water source device, water pump are connected with blower fan cascade entrance by water-supply-pipe；

It is provided with the first valve between described cold water source device and water pump；

Described back pool is connected by drain pipe with the outlet of blower fan cascade；

Described back pool is connected with water feeding of water pump water-supply-pipe, is provided with the second valve between described back pool and water feeding of water pump water-supply-pipe；

Described solar photovoltaic generation system is arranged on booth ceiling, and described solar photovoltaic generation system is connected with the blower fan in water pump, blower fan cascade, the first valve, the second valve.

Further, one or more during the blower fan in described blower fan cascade uses axial flow blower, centrifugal blower, diagonal flow fan.

For realizing the detection in real time of canopy temperature and humidity and controlling, further, the first temperature sensor, humidity sensor it is provided with in described booth, booth wall is provided with exhaust fan, described first temperature sensor, humidity sensor, exhaust fan are connected with solar photovoltaic generation system, and described exhaust fan uses one or more in axial flow blower, centrifugal blower, diagonal flow fan.

For getting rid of miscellaneous bacteria interference, the living contaminants being strictly on guard against in water, further, between described back pool and blower fan cascade or in back pool, it is provided with sterilizer, described sterilizer uses one or more in ozone sterilization, chlorbenside bacterium, ultraviolet sterilization.

For making full use of the cold energy in cold water source device water, further, described back pool is connected with cold water source device, is provided with the 3rd valve between described back pool and cold water source device, and described 3rd valve is connected with solar photovoltaic generation system

Further, being provided with the second temperature sensor in described cold water source device, described second temperature sensor is connected with solar photovoltaic generation system.

In order to detect the water temperature being back in back pool in real time, so that water temperature makes full use of the cold energy in cold water time relatively low in back pool, it is to detect the liquid level in back pool in real time simultaneously, ensure that water pump can continue to draw water for fan cascade and water injector in back pool, further, being provided with three-temperature sensor and liquid level sensor in described back pool, described three-temperature sensor, liquid level sensor are connected with solar photovoltaic generation system.

For preventing the water temperature in cold water source device from raising after running a period of time because of system, exceed design temperature scope and affect blower fan cascade working effect, further, described back pool is connected with refrigeration plant, described refrigeration plant is connected with solar photovoltaic generation system, and described refrigeration plant uses one or more in compression refrigerating machine, Absorption Refrigerator, steam jet refrigerator and semiconductor refrigerator.

For realizing the real-time detection of temperature, the above first temperature sensor, the second temperature sensor, three-temperature sensor use one or more in thermocouple sensor, thermal resistance sensor, infrared temperature-test sensor.

For realizing the regulation to piping flow, the above first valve, the second valve, the 3rd valve, the 4th valve, the 5th valve use one or more in electrodynamic valve, pneumatic operated valve, hydraulic operated valve.

For realizing the real-time detection to booth humidity, described humidity sensor uses one or more in lithium chloride humidity sensor, carbon dew cell, aluminium oxide drimeter, Ceramic Humidity Sensor.

For realizing the real-time detection of liquid level in back pool, described liquid level sensor uses one or more in float-type liquid level sensor, floating ball type liquid level sensor, static pressure type liquid level sensor.

In order to realize the regulation of discharge of pump, described water pump is provided with flow regulator, described pump capacity adjusting means use be connected with frequency conversion motor, one or more in bypass line.

Further, described booth is provided with the blower fan in controller, described controller and the first temperature sensor, the second temperature sensor, three-temperature sensor, humidity sensor, liquid level sensor, the first valve, the second valve, the 3rd valve, water pump, refrigeration plant, exhaust fan, blower fan cascade, solar photovoltaic generation system by wirelessly or non-wirelessly communicating to connect.

Described edible fungus culturing uses solar photovoltaic generation system to power with solar powered energy-conservation booth, by the first temperature sensor, humidity sensor, the second temperature sensor, the real-time detection of the measurement apparatus such as three-temperature sensor and liquid level sensor, controller receives the detection signal that measurement apparatus detects, control executor's actions such as the blower fan in water pump, blower fan cascade, exhaust fan, the first valve, the second valve, the 3rd valve, refrigeration plant, it is achieved the control to the temperature and humidity in booth.

The electricity consumption requirement of each electrical equipment can be met by ensureing that solar photovoltaic generation system is generated electricity, simultaneously, guarantee solar photovoltaic generation system can give the accessible power supply of each electrical equipment at night and overcast and rainy energy, further, described solar photovoltaic generation system includes solaode, photovoltaic controller, accumulator, inverter.Described solaode uses one or more in monocrystaline silicon solar cell, polysilicon solar cell, amorphous silicon thin-film solar cell and compound film solaode.In order to control accumulator when charging not by overcharge, and not to load over-discharge during electric discharge, regulation solar panel electricity can flow to DC load and AC load simultaneously, and unnecessary electric energy is sent to accumulator storage, described photovoltaic controller uses one or more in parallel connection type controller, tandem type controller, pulsewidth modulation type controller, multi-channel control controller, intelligent controller and MPPT maximum power point tracking type controller.For ensureing the operation steady in a long-term of solar photovoltaic generation system, meeting the good deeper cavity ability of solar energy power generating accumulator and overcharge, cross and put the requirements such as performance, described accumulator uses one or more in plumbic acid maintenance-free accumulator, common lead acid accumulator, colloid storage battery and alkaline nickel-cadmium storage battery.Unidirectional current in order to realize being sent out by solaode is converted into the alternating current of specification needed for the AC load equipment such as water pump, induced draft fans, and described inverter uses one or more in square-wave inverter, ladder inverter, sinewave inverter and Three-Phase Inverter.

For avoiding heat exchange quick with atmospheric environment in water course of conveying, water temperature is raised too fast, affect cascade working effect, further, described booth, water-supply-pipe, drain pipe, sterilizer, back pool appearance are all enclosed with heat-insulation layer, and described heat-insulation layer uses one or more in glass cotton, rock wool, polyurethane.

Compared with prior art, this utility model has the advantages that

Edible fungus culturing described in the utility model with solar powered energy-conservation booth booth top install solar photovoltaic generation system, on the one hand, electricity can be supplied relevant electrical equipment by solar photovoltaic generation system, reduces electric cost, meanwhile, improve the reliability that booth is powered；On the other hand, it is achieved that ground light overhead utility operation and planting edible mushroom combine, and improve land utilization ratio.

Accompanying drawing explanation

Fig. 1 is the solar powered energy-conservation booth solar photovoltaic generation system structural representation of edible fungus culturing；

Fig. 2 is the solar powered energy-conservation greenhouse structure schematic diagram of edible fungus culturing.

Detailed description of the invention

Below in conjunction with detailed description of the invention, this utility model is further described.Wherein, being merely cited for property of accompanying drawing illustrates, expression is only schematic diagram, rather than pictorial diagram, it is impossible to it is interpreted as the restriction to this patent；In order to of the present utility model embodiment is better described, some parts of accompanying drawing have omission, zoom in or out, and do not represent the size of actual product；It will be understood by those skilled in the art that some known features and explanation thereof may will be understood by omission in accompanying drawing.

Embodiment 1

As it is shown in figure 1, edible fungus culturing is with solar powered energy-conservation booth solar photovoltaic generation system, including solaode 141, photovoltaic controller 142, accumulator 143, inverter 144；Solaode 141, photovoltaic controller 142, accumulator 143, inverter 144 are sequentially connected with by wire.

As in figure 2 it is shown, edible fungus culturing is with solar powered energy-conservation booth, including the blower fan 601 in booth 1, cold water source device 4, water pump 5, blower fan cascade 6, blower fan cascade, back pool 9, solar photovoltaic generation system 14；Blower fan cascade 6 is arranged in booth；Cold water source device 4, water pump 5 are connected with blower fan cascade 6 entrance by water-supply-pipe 15；The first valve 401 it is provided with between cold water source device 4 and water pump 5；Back pool 9 is exported with blower fan cascade 6 and is connected by drain pipe 16；It is provided with sterilizer 8 between back pool 9 and blower fan cascade 6 outlet；Back pool 9 water-supply-pipe of intaking with water pump 5 is connected, and back pool 9 and water pump 5 are intake and be provided with the second valve 901 between water-supply-pipe；Back pool 9 is connected with cold water source device 4, is provided with the 3rd valve 902 between back pool 9 and cold water source device 4；Detection greenhouse temperature and the first temperature sensor 2 of humidity and humidity sensor 3 it is provided with in booth 1；Booth 1 wall is provided with exhaust fan 7；The second temperature sensor 402 for detecting water temperature it is provided with in cold water source device 4；Water temperature and the three-temperature sensor 10 of liquid level and liquid level sensor 11 in detecting back pool it is provided with in back pool 9；Solar photovoltaic generation system 14 is arranged on booth ceiling, and described solar photovoltaic generation system 14 is connected by wire with the blower fan 601 in the first temperature sensor 2, humidity sensor the 3, first valve the 401, second temperature sensor 402, water pump 5, blower fan cascade, exhaust fan the 7, second valve the 901, the 3rd valve 902, three-temperature sensor 10, liquid level sensor 11, refrigeration plant 12, controller 13.

In the present embodiment, the second temperature sensor 402 in the first temperature sensor 2 of controller 13 and booth 1, humidity sensor 3, cold water source device 4, three-temperature sensor 10, liquid level sensor 11, refrigeration plant 12, exhaust fan 7, water pump 10 and first valve the 401, second valve the 901, the 3rd valve 902 in back pool use radio communication to be connected.

In the present embodiment, first temperature sensor the 2, second temperature sensor 402 and three-temperature sensor 10 all use thermocouple temperature sensor；Cold water source device 4 is well；Water pump 5 uses frequency conversion motor to regulate flow；Blower fan in cascade blower fan 6 uses axial flow blower；First valve the 401, second valve the 901, the 3rd valve 902 all uses electrodynamic valve；Humidity sensor 3 uses lithium chloride humidity sensor；Exhaust fan 7 uses axial flow blower；Sterilizer 8 uses ultraviolet sterilization；Liquid level sensor 11 uses float-type liquid level sensor；Refrigeration plant 12 uses semiconductor refrigerator；Heat-insulation layer uses glass cotton；Solaode 141 uses monocrystaline silicon solar cell；Photovoltaic controller 142 uses MPPT maximum power point tracking type controller；Accumulator 143 uses plumbic acid maintenance-free accumulator；Inverter 144 uses sinewave inverter.

During work, solar irradiation is mapped on solaode 141, the luminous energy received is directly translated into electric energy by solaode 141, photovoltaic controller 142 regulates and a part of electric energy flows to the edible fungus culturing DC load with solar powered energy-conservation booth, regulation another part electric energy is converted into alternating current is sent to the edible fungus culturing AC load equipment with solar powered energy-conservation booth by inverter 144, regulates remaining electric energy and is sent to accumulator 143 and stores.

The signal instruction that the photovoltaic controller 142 of solar photovoltaic generation system 14 is sent out according to controller 13, powers to the first temperature sensor 2, humidity sensor the 3, first valve the 401, second temperature sensor 402, water pump 5, cascade blower fan 601, exhaust fan the 7, second valve the 901, the 3rd valve 902, three-temperature sensor 10, liquid level sensor 11, refrigeration plant 12, controller 13 by wire；First temperature sensor 2 and humidity sensor 3 detect the temperature and humidity in booth 1, second temperature sensor 402 detects the water temperature in cold water source device 4, and the first temperature signal detected, moisture signal the second temperature signal are flowed to controller 13, the first temperature range a, humidity range b and second temperature range c of the first temperature signal received, moisture signal and the second temperature signal with setting are compared by controller 13；The first temperature signal received when controller 13 is more than temperature range a set, and the second temperature signal less than set the second temperature range c time, controller 13 is signaled to the first valve 401 and water pump 5, first valve 401 is opened, water pump 5 starts to extract cold water from cold water source device 4, come to booth 1 cooling humidification for fan cascade 6, until the temperature in booth 1 is reduced to temperature range a set；When the moisture signal that controller 13 receives is more than the humidity range b set, controller 13 is signaled to exhaust fan 7, and exhaust fan 7 starts toward the outer air draft of booth to reduce the humidity in booth 1, until the humidity in booth 1 drops to the humidity range b of setting；Cold water is by being admitted to sterilizing in sterilizer 8 after blower fan cascade 6, and the water after sterilizing is sent to back pool 9 again；Water temperature in back pool 9 and liquid level are detected by three-temperature sensor 10 and liquid level sensor 11, and the 3rd temperature signal detected and liquid level signal are passed to controller 13, the 3rd temperature range d and liquid level scope e of the 3rd temperature signal detected and liquid level signal with setting are compared by controller 13；When the 3rd temperature signal that controller 13 receives is more than three temperature range d set, controller 13 is signaled to the 3rd valve 902,3rd valve 902 is opened, water in back pool 9 flows to cold water source device 4 by back of pipeline, supplies fan cascade 6 by water pump 5 again in cold water source device 4 after cooling；The 3rd temperature signal received when controller 13 is positioned at temperature range d of setting, and liquid level signal less than set liquid level scope e time, water pump 5 continues to draw water from cold water source device 4 for fan cascade 6, until the liquid level signal that controller 13 receives is positioned at liquid level scope d of setting；The 3rd temperature signal received when controller 13 is positioned at temperature range d of setting, and liquid level signal is when being positioned at liquid level scope e of setting, controller 13 is signaled to the first valve 401 and the second valve 901, first valve 401 is closed after receiving signal, second valve 901 is opened after receiving signal, and water pump 5 starts to draw water from back pool 9 for fan cascade 6；The second temperature signal received when controller 13 and the 3rd temperature signal are all higher than the temperature range set, and liquid level signal is positioned at liquid level scope e of setting, controller 13 is signaled to the first valve the 401, second valve the 901, the 3rd valve 902 and refrigeration plant 12, now, first valve 401 and the 3rd valve 902 are closed, second valve 901 is opened, refrigeration plant 12 starts the water cooled back in pond 9 that freezes, making the water temperature in back pool 9 be reduced to set point, water pump 5 extracts the water after being cooled down by refrigeration plant 12 again for fan cascade 6 from back pool 9.

Obviously, above-described embodiment is only for clearly demonstrating the technical solution of the utility model example, and is not the restriction to embodiment of the present utility model.For those of ordinary skill in the field, can also make other changes in different forms on the basis of the above description.All any amendment, equivalent and improvement etc. made within spirit of the present utility model and principle, within should be included in this utility model scope of the claims.

Claims (10)

1. an edible fungus culturing is with solar powered energy-conservation booth, it is characterised in that include booth, cold water source device, water pump, blower fan cascade, back pool, solar photovoltaic generation system；

Described blower fan cascade is arranged in booth；

Described cold water source device, water pump are connected with blower fan cascade entrance by water-supply-pipe；

It is provided with the first valve between described cold water source device and water pump；

Described back pool is connected by drain pipe with the outlet of blower fan cascade；

Described back pool is connected with water feeding of water pump water-supply-pipe, is provided with the second valve between described back pool and water feeding of water pump water-supply-pipe；

Described solar photovoltaic generation system is arranged on booth ceiling, and described solar photovoltaic generation system is connected with the blower fan in water pump, blower fan cascade, the first valve, the second valve.

The most according to claim 1, edible fungus culturing is with solar powered energy-conservation booth, it is characterized in that, the first temperature sensor, humidity sensor it is provided with in described booth, booth wall is provided with exhaust fan, and described first temperature sensor, humidity sensor, exhaust fan are connected with solar photovoltaic generation system.

The most according to claim 2, edible fungus culturing is with solar powered energy-conservation booth, it is characterised in that be provided with sterilizer between described back pool and blower fan cascade or in back pool.

The most according to claim 3, edible fungus culturing is with solar powered energy-conservation booth, it is characterized in that, described back pool is connected with cold water source device, is provided with the 3rd valve between described back pool and cold water source device, and described 3rd valve is connected with solar photovoltaic generation system.

The most according to claim 4, edible fungus culturing is with solar powered energy-conservation booth, it is characterised in that being provided with the second temperature sensor in described cold water source device, described second temperature sensor is connected with solar photovoltaic generation system.

The most according to claim 5, edible fungus culturing is with solar powered energy-conservation booth, it is characterised in that being provided with three-temperature sensor and liquid level sensor in described back pool, described three-temperature sensor, liquid level sensor are connected with solar photovoltaic generation system.

The most according to claim 6, edible fungus culturing is with solar powered energy-conservation booth, it is characterised in that described back pool is connected with refrigeration plant, and described refrigeration plant is connected with solar photovoltaic generation system.

The most according to claim 7, edible fungus culturing is with solar powered energy-conservation booth, it is characterized in that, described booth is provided with the blower fan in controller, described controller and the first temperature sensor, the second temperature sensor, three-temperature sensor, humidity sensor, liquid level sensor, the first valve, the second valve, the 3rd valve, water pump, refrigeration plant, exhaust fan, blower fan cascade, solar photovoltaic generation system by wirelessly or non-wirelessly communicating to connect.

The most according to claim 8, edible fungus culturing is with solar powered energy-conservation booth, it is characterised in that described solar photovoltaic generation system includes solaode, photovoltaic controller, accumulator, inverter.

The most according to claim 9, edible fungus culturing is with solar powered energy-conservation booth, it is characterised in that described booth, water-supply-pipe, drain pipe, sterilizer, back pool appearance are all enclosed with heat-insulation layer.