Detailed Description
In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the detailed description thereof.
Introduction of integrated indigenous probiotic propagation system convenient to move
According to one aspect of the present invention, the present invention provides an integrated type indigenous probiotic propagation system which is convenient to move, wherein fig. 1 to 7 show the structure of the indigenous probiotic propagation system of the present invention.
As shown in fig. 1 to 7, the indigenous probiotic propagation system at least comprises a propagation container 10, a heating device 20 and an aeration device 30. Wherein:
the propagation container 10 is used to contain a propagation solution, namely: the propagation solution is contained in the inner cavity of the propagation container 10, and the indigenous probiotic strains are put into the propagation solution in the propagation container 10 and grow and propagate in the propagation solution.
The propagation solution is generally prepared by mixing water and various nutrients according to a predetermined component ratio. Common nutrients for expanding propagation of indigenous probiotics comprise organic carbon, organic nitrogen, amino acid, trace elements, biological enzyme, acid-base regulator and the like. Specifically, which kinds of nutrients are used and how to control the ratio of water and various kinds of nutrients can be flexibly adjusted according to the actual propagation goal, and the invention is not particularly limited. Of course, in order to ensure that the indigenous probiotics achieve the predetermined propagation effect, the environmental parameters such as the temperature and the dissolved oxygen of the propagation solution need to be adjusted to the appropriate range, so that the indigenous probiotics are in the predetermined propagation environment.
As shown in fig. 1, a feed port 11 is provided at the top of the propagation container 10, and water, various nutrients and other materials, and indigenous probiotic strains can be fed into the propagation container 10 through the feed port 11. Optionally, in order to prevent the propagation solution in the propagation container 10 from overflowing from the feed opening 11, an overflow box assembly is disposed at the periphery of the feed opening 11.
As shown in fig. 4, a discharge port 16 is disposed at the bottom of the propagation container 10, after the propagation of the indigenous probiotics is completed, the discharge port 16 is opened, so that the propagation solution containing a large amount of indigenous probiotics can be led out from the propagation container 10, and the led propagation solution can be directly and nearby put to an application target or can be put into a storage vessel for storage and standby.
Optionally, as shown in fig. 1, an upper manhole 12 is further provided at the top of the propagation expanding container 10, and an inspector can enter the propagation expanding container 10 through the upper manhole 12 to facilitate the inspection of each functional component provided in the propagation expanding container 10. Optionally, the upper manhole 12 is further provided with a light guide plate, and natural light can be guided into the propagation expanding container 10 through the light guide plate, so that the illumination requirement of some indigenous probiotic strains in the propagation expanding process is met. Also, in order to prevent the propagation solution in the propagation container 10 from overflowing the upper manhole 12, an overflow box assembly is provided at the periphery of the upper manhole 12.
In order to ensure the safe walking, a pedestrian grille 13 is laid on the top of the propagation container 10, and a folding safety fence 14 is arranged on the periphery of the top of the propagation container 10. The heating device 20 is arranged on the propagation container 10, and the heating device 20 is used for heating and preserving the temperature of the propagation solution contained in the propagation container 10, so that the temperature of the propagation solution is always kept in a preset temperature range, and the temperature condition required by the survival and propagation of indigenous probiotics is met.
The aeration device 30 is arranged on the propagation expanding container 10, and the aeration device 30 is used for realizing the aeration of the propagation expanding solution contained in the propagation expanding container 10 so as to increase and maintain the dissolved oxygen in the propagation expanding solution, so that the dissolved oxygen of the propagation expanding solution is always kept in a preset dissolved oxygen range, and the dissolved oxygen condition required by the survival and propagation of the indigenous probiotics is met.
It can be seen that the indigenous probiotic propagation system, the heating device and the aeration device of the present invention are integrated on the propagation container. The integrated type indigenous probiotic propagation system is equivalent to a movable and small-sized indigenous probiotic production factory, and can be conveniently and quickly transported to different indigenous probiotic application destinations, particularly to the indigenous probiotic application destinations where large-sized and fixed indigenous probiotic propagation factories cannot be built on site, such as the field, remote mountain areas, gobi and the like.
The method can directly supply the expanded and bred indigenous probiotics to an application destination of the indigenous probiotics, can reduce the storage cost of the indigenous probiotics, and can ensure the activity of the indigenous probiotics.
In addition, the method can realize continuous propagation of the indigenous probiotics in the transportation process, thereby improving the propagation yield of the indigenous probiotics.
During transportation, the propagation container 10 is mounted on a transportation vehicle such as a truck, and in order to reduce the fluctuation and impact of the propagation solution in the propagation container 10, improve the running stability of the transportation vehicle, and reduce the impact of the fluctuation of the propagation solution on each functional module in the propagation container 10. Optionally, the inner wall of the propagation container 10 is provided with a wave-preventing plate 15. In addition, the outer wall of the expanding propagation container can be also provided with an anti-collision sensing device, and when the distance between the expanding propagation container and an obstacle (such as a front vehicle) is smaller than a preset value in the transportation process, the anti-collision sensing device can send out an alarm signal.
The propagation expanding container 10 may be formed by modifying various metal or plastic tanks, such as an oil tank for transporting oil or a plastic tank for transporting chemicals. The propagation expanding container 10 may be modified from a container, and a waterproof layer is laid on the inner wall of the container. Of course, a dedicated pot-type or box-type propagation container 10 may be customized. A mobile, small-sized plant for producing indigenous probiotics can be constructed by mounting the tank-type or box-type propagation container 10 on a transport vehicle such as a truck.
Since the indigenous probiotics need to be propagated under a relatively stable temperature condition, the thermal insulation of the propagation container 10 needs to be ensured. In addition, the chemical components of the propagation solution are complex and have certain corrosiveness, so that optionally, an anticorrosive material layer is laid on the inner wall of the propagation container 10, and a heat-insulating material layer is laid on the outer wall of the propagation container 10.
After the propagation of the indigenous probiotics of the current batch is completed, the inner cavity of the propagation container 10 needs to be deeply cleaned, so as to prevent the residual propagation solution from causing cross influence on the propagation of the indigenous probiotics of the next batch. In view of this, in order to achieve automatic cleaning of the inner cavity of the propagation expanding container 10, as shown in fig. 2, optionally, the integrated indigenous probiotic propagation system of the invention further comprises a spray cleaning device 40 disposed on the propagation expanding container 10, wherein the spray cleaning device 40 is used for achieving automatic spray cleaning of the inner cavity of the propagation expanding container 10 to remove residual propagation solution in the propagation expanding container 10.
As mentioned above, the integrated type indigenous probiotic propagation system of the present invention may be installed in the field, remote mountainous areas, gobi and other indigenous probiotic application destinations, and the present invention needs to realize continuous propagation of indigenous probiotics during transportation. Therefore, it is necessary to automatically monitor various environmental parameters of the propagation solution in the propagation container 10, especially critical environmental parameters such as temperature and dissolved oxygen, so as to ensure that the indigenous probiotics are always in a proper propagation environment.
In view of this, as shown in fig. 2 and fig. 6, the integrated type indigenous probiotic propagation system of the present invention further includes a propagation expansion thing-link monitoring device 50 disposed on the propagation expansion container 10, where the propagation expansion thing-link monitoring device 50 can automatically collect environmental parameters such as temperature value and oxygen content of the propagation solution in the propagation expansion container 10, and can automatically control functional modules such as the heating device 20 and the aeration device 30 based on the obtained environmental parameters to trigger the functional modules such as the heating device 20 and the aeration device 30 to operate, so as to adjust various environmental parameters of the propagation solution within a predetermined range.
Optionally, a wireless communication module is integrated in the propagation expansion internet of things monitoring device 50, the propagation expansion internet of things monitoring device 50 is in signal connection with a remote control terminal (such as a mobile phone of a user, a computer, etc.) through the wireless communication module, and the propagation expansion internet of things monitoring device 50 sends the acquired environmental parameter information such as temperature, oxygen, etc. to the remote control terminal.
According to the obtained environmental parameter information such as temperature and oxygen, a user edits an environmental parameter control instruction and sends the environmental parameter control instruction to the propagation expansion thing union monitoring device 50 through a control terminal, and the propagation expansion thing union monitoring device 50 triggers the functional modules such as the heating device 20 and the aeration device 30 to act based on the received environmental parameter control instruction, so that various environmental parameters of the propagation expansion solution are adjusted to be within a preset range.
The integrated type indigenous probiotic propagation system comprises the electric components such as the heating device 20 and the aeration device 30, which consume a large amount of electric power, however, as mentioned above, the integrated type indigenous probiotic propagation system may be arranged in the field, remote mountain areas, gobi and other application destinations, which are not provided with a perfect electric power supply network, and moreover, the integrated type indigenous probiotic propagation system needs to ensure the continuous propagation of the indigenous probiotics during transportation, and the power supply of a fixed power supply and a common storage battery is difficult to meet the electric power consumption requirement of the integrated type indigenous probiotic propagation system. In view of this, optionally, the integrated indigenous probiotic propagation system of the present invention further comprises a power supply device, as shown in fig. 9, which comprises at least a folding solar power generation device 60 disposed at the top of the propagation container 10. The folding solar power generation device 60 can realize continuous power supply of the power utilization components in the integrated type indigenous probiotic propagation system, so that the autonomous supply of electric power is met.
Optionally, the power supply device further includes a power connector, and the power connector is connected to an external power supply facility (such as a 220V mains supply), so that direct power supply to the integrated indigenous probiotic propagation system of the present invention can also be achieved.
Optionally, in order to fix the propagation container 10 and prevent the propagation container 10 from accidentally slipping during transportation, as shown in fig. 1, the integrated type indigenous probiotic propagation system of the present invention further comprises a fixing frame 80, and the propagation container 10 is fixed and placed in the fixing frame 80. Alternatively, the fixed frame 80 is formed by welding section steel.
Optionally, the integrated indigenous probiotic propagation system of the present invention further comprises a GPS positioning device and an anti-intrusion electronic fence disposed on the outer wall of the propagation container 10. The remote positioning of the invention can be realized by arranging the GPS positioning device, and human or animal intrusion can be prevented by arranging the anti-intrusion electronic fence.
Introduction to heating devices
While only a brief description of the heating device has been provided above, one or more detailed embodiments of the heating device 20 are illustrated in fig. 3-5, and the heating device 20 will be described in further detail below in conjunction with fig. 3-5. According to an aspect of the present invention, the present invention also provides an improved heating device 20, and the heating device 20 is particularly suitable for heating the propagation solution in the propagation container 10 to raise the temperature, so as to ensure that the temperature of the propagation solution in the propagation container 10 is always kept within a predetermined temperature range.
As shown in fig. 3 and 5, the heating device 20 includes at least an electric heating mechanism including an electric heating control box 21 and heating wires 22, wherein: the electric heating control box 21 is connected to the outer wall of the propagation expanding container 10, and a power supply connecting wire is arranged on the electric heating control box 21. Heating wires 22 are arranged on the side wall of the propagation container 10, and the heating wires 22 are electrically connected to the electric heating control box 21 via a cable 23 penetrating the side wall of the propagation container 10. In use, the power connection line is connected to a power supply (such as the output end of the storage battery of the foldable solar power generation device 60), the electric heating control box 21 transmits the current supplied by the power supply to the heating wires 22 through the cable 23, and the heating wires 22 are powered to generate heat, so as to heat the propagation solution in the propagation container 10. The electric heating control box 21 can realize the on-off of the electric heating wire 22 and the heating power, thereby realizing the adjustment of the temperature of the propagation solution.
In order to realize automatic control or remote control of the heating device 20, optionally, the electrical heating control box 21 is electrically connected to the propagation expansion instrumented monitoring device 50, the propagation expansion instrumented monitoring device 50 sends the heating control command to the electrical heating control box 21, and the electrical heating control box 21 controls the on-off and heating power of the heating wires 22 based on the received control command, so as to realize automatic and accurate adjustment of the temperature of the propagation solution.
As shown in fig. 4, the heating device 20 further includes a steam heating mechanism including a steam inlet mechanism 24 and a steam heat exchange coil (not shown). Wherein: the steam inlet mechanism 24 is connected to the outer wall of the propagation expanding container 10, and a steam inlet interface is arranged on the steam inlet mechanism 24. The steam heat exchange coil is arranged on the inner wall of the propagation expanding container 10, and the air inlet end of the steam heat exchange coil is communicated with the steam air inlet mechanism through an air inlet pipeline penetrating through the side wall of the propagation expanding container 10. When the device is used, the steam inlet interface of the steam inlet mechanism 24 is connected with an external steam supply device, and high-temperature steam enters the steam heat exchange coil pipe through the steam outlet mechanism 24 and flows in the steam heat exchange coil pipe, so that heat exchange is generated between the high-temperature steam and the propagation expanding solution in the propagation expanding container 10, and the heating and the temperature rise of the propagation expanding solution in the propagation expanding container 10 are realized. The steam after heat exchange is discharged through the air outlet end of the steam heat exchange coil.
By arranging the electric heating mechanism and the steam heating mechanism at the same time, the heating device 20 can selectively realize electric heating and high-temperature steam heat exchange heating of the propagation solution, so that the heating requirements under different scenes are met.
Introduction to aeration apparatus
While only brief descriptions of the aeration apparatus have been provided above, one or more detailed embodiments of the aeration apparatus are illustrated in fig. 1, 5, and 6, and will be described in further detail below in connection with fig. 1, 5, and 6. According to an aspect of the present invention, the present invention also provides an improved aeration apparatus which is particularly suitable for achieving aeration and oxygen dissolution of the propagation solution in the propagation container 10 to ensure that the content of the propagation solution in the propagation container 10 is always kept within a predetermined appropriate range.
As shown in fig. 1 and 6, the aeration apparatus 30 includes an air compressor 31, an aeration connection pipe 32, and an aeration pipe 33. Wherein an air compressor 31 is provided at the top of the propagation container 10, which draws air from the surrounding environment and pressurizes the drawn air. The aeration connecting pipe 32 is vertically arranged, the upper end of the aeration connecting pipe 32 is connected to the output port of the air compressor 31, and the lower end of the aeration connecting pipe 32 penetrates downwards into the propagation container 10. The aeration pipe 33 is arranged in the propagation container 10 and laid on the bottom of the propagation container 10, and the aeration pipe 33 is communicated with the lower end of the aeration connecting pipe 32.
When the oxygen dissolution by aeration is required for the propagation solution, the air compressor 31 is started. The high pressure air in the air compressor 31 is pressed into the aeration pipe 33 through the aeration connection pipe 32 and finally exposed from the aeration holes on the aeration pipe 33.
As shown in fig. 5, in order to enhance the aeration effect of the aeration device 30, the aeration pipeline 33 is optionally a spiral-bent coil structure laid at the bottom of the propagation expanding container 10. In this way, the aeration pipe 33 can cover as many areas as possible of the bottom of the propagation container 10, and thereby a large area and uniform aeration can be achieved.
In order to realize automatic control or remote control of the aeration device 30, optionally, the controller of the air compressor 31 is electrically connected to the propagation expansion instrumented monitoring device 50, the propagation expansion instrumented monitoring device 50 sends an aeration control instruction to the controller of the air compressor 31, and the controller of the air compressor 31 controls start-stop and power of the air compressor 31 based on the received aeration control instruction, so as to realize automatic adjustment of the dissolved oxygen amount of the propagation solution.
Introduction to spray cleaning device
While only a brief description of the aeration device has been provided above, fig. 2 shows one or more detailed embodiments of the spray cleaning device, which will be described in further detail below in conjunction with fig. 2. According to one aspect of the present invention, the present invention also provides an improved spray cleaning device which is particularly suitable for performing spray cleaning of the inner cavity of the propagation containers 10 to rinse away residual propagation solution from the inner cavity of the propagation containers 10.
As shown in fig. 2, the spray cleaning device 40 includes a main water pipe 41, a plurality of spray branch pipes 42, and a plurality of high-pressure spray heads 43 corresponding to the spray branch pipes 42 one by one. Wherein, the main water pipe 41 is arranged on the outer wall of the propagation expanding container 10, the main water pipe 41 is connected with a high pressure water pump (not shown), the first end of each spray branch pipe 42 is connected on the main water pipe 41 and communicated with the main water pipe 41, the second end of each spray branch pipe 42 penetrates into the propagation expanding container 10, and each spray branch pipe 42 is connected on the second end of the corresponding spray branch pipe 42.
When the propagation container 10 needs to be cleaned, the main water pipe 41 is communicated with an external water supply container, then the high-pressure water pump is started, water in the water supply container flows into the main water pipe 41 under the driving of the high-pressure water pump, is divided into the spraying branch pipes 42, and is finally sprayed out through the high-pressure spray nozzles 43, and therefore the spraying cleaning of the propagation container is achieved.
As shown in fig. 2, in order to uniformly clean the internal space of the propagation container 10, no dead space is left as much as possible. The main water pipe 41 is horizontally disposed on one side wall of the propagation expanding container 1 and near the top of the propagation expanding container 1, and a plurality of shower branch pipes 42 (four in fig. 2) are connected to the main water pipe 41 at equal intervals along the extending direction of the main water pipe 41.
In order to realize automatic control or remote control of spray cleaning, optionally, the controller of the high-pressure water pump is electrically connected with the expanded complex thing networking monitoring device 50, the expanded complex thing networking monitoring device 50 sends a spray cleaning control instruction to the controller of the high-pressure water pump, and the controller of the high-pressure water pump controls the start, stop and power of the high-pressure water pump based on the received spray cleaning control instruction, so that automatic control of spray cleaning is realized.
Introduction of complex expansion thing connection monitoring device
While only a brief description of the augmented reality monitoring apparatus has been provided above, fig. 3 and 6 show one or more detailed embodiments of the augmented reality monitoring apparatus, which will be described in further detail below with reference to fig. 2 and 6. According to an aspect of the present invention, the present invention further provides a propagation expansion thing-link monitoring device, which can, on one hand, realize real-time detection of important environmental parameters such as temperature and oxygen of the propagation solution in the propagation expansion container 10, and on the other hand, can realize automatic control of the heating device 20 and the aeration device 30, etc. to trigger the heating device 20 and the aeration device 30 to complete automatic heating and automatic aeration, so as to adjust the temperature and the dissolved oxygen amount of the propagation solution to be within a predetermined range.
As shown in fig. 2 and 6, the complex expansion monitoring apparatus 50 at least includes a main controller 51 and a sensing module 52. Wherein: the main controller 51 is disposed on the outer wall of the propagation container 10, the main controller 51 is in signal connection with the sensor module 52, and the main controller 51 is also in signal connection with the functional modules such as the heating device 20 and the aeration device 30. The sensing module 52 is disposed in the propagation container 10, and the sensing module 52 is configured to collect environmental parameter information of the propagation solution and send the environmental parameter information to the main controller 51.
Optionally, the sensing module 52 includes a temperature sensor, an oxygen concentration sensor, a pH sensor, and the like, wherein the temperature sensor is used for collecting a temperature value of the propagation solution, the oxygen concentration sensor is used for collecting a dissolved oxygen value of the propagation solution, and the pH value is used for collecting a pH value of the propagation solution.
Sensor parts such as a temperature sensor, an oxygen concentration sensor, and a pH sensor are precision electronic parts, and are intended to reduce the impact of the fluctuation of the propagation solution in the propagation container 10 on the sensor parts during transportation. Optionally, the propagation monitoring device 50 further includes a sensor anti-surge installation mechanism 54 connected to the inner wall of the propagation container 10, and the sensing module 52 is installed on the sensor anti-surge installation mechanism 54.
As shown in fig. 8, the sensor anti-surge mounting mechanism 54 may alternatively include a connection bracket 541 and a mounting plate 542. The connecting support 541 is formed by welding round steel, the upper end of the connecting support 541 is connected to the top wall of the propagation expanding container 10, the mounting plate 542 is welded at the lower end of the connecting support 541, a plurality of NPT threaded holes are formed in the mounting plate 542, various sensors in the sensing module 52 are all screwed in one NPT threaded hole, and signal cables of the sensors are fixed on the connecting support 541 through a binding tape.
The sensor anti-surge mounting mechanism 54 can significantly improve the mounting stability of the sensing module 52 and improve the anti-surge performance of the sensing module 52. Optionally, the contact position pad of sensor and mounting panel 542 is equipped with the rubber circle pad, through setting up the rubber circle pad, can cushion the collision between sensor and the mounting panel, further promotes sensing module 52's anti surge performance.
The sensing module 52 sends the collected environmental parameter information of the propagation solution to the main controller 51, and the main controller 51 generates an environmental parameter adjusting instruction based on the received environmental parameter information of the propagation solution to control the functional modules such as the heating device 20 and the aeration device 30 to execute corresponding adjusting actions, so as to adjust the corresponding environmental parameters of the propagation solution to a predetermined range. The environmental parameter adjusting instruction comprises a heating control instruction, an aeration control instruction and the like.
Optionally, a touch display panel is arranged on the main controller 51, the touch display panel can display various environmental parameter values collected by the sensing module 52, and a user can also manually adjust some environmental parameters according to a display result, for example, when the user finds that the pH value of the propagation expanding solution is too high, the user can manually input an acidic pH adjusting agent into the propagation expanding container 10 through the feed inlet 11, and when the user finds that the pH value of the propagation expanding solution is too low, the user can manually input an alkaline pH adjusting agent into the propagation expanding container 10 through the feed inlet 11. Also, for example, when the user finds that the temperature of the propagation solution is too low, the user may manually operate the electric heating control box 21 to turn on the heating wire 22 of the electric heating mechanism, or the like.
Further, in order to implement the remote control of the present invention, optionally, a wireless communication module is integrated on the main controller 51, and the main controller 51 implements signal connection with a remote terminal system (such as a mobile phone of a user, a computer, etc.) through the wireless communication module. The main controller 51 sends the acquired environmental parameter information such as temperature, oxygen content and the like to a remote control terminal, a user edits an environmental parameter control instruction based on the received environmental parameter information and sends the control instruction to the main controller 51 through the control terminal, and the main controller 51 finally triggers the functional modules such as the heating device 20 and the aeration device 30 to act based on the environmental parameter control instruction sent by the control terminal.
Optionally, the propagation monitoring device 50 further includes a liquid level sensor 52 disposed in the propagation container 10, and the liquid level sensor 52 is also in signal connection with the main controller 51. The liquid level sensor 52 is used for collecting the liquid level value in the propagation expanding container 10 and sending the collected liquid level value to the main controller 51, and the collected liquid level value is displayed by the main controller 51 so as to remind a user that water and various nutrients are put into the propagation expanding container 10 in time according to a proportion when the liquid level is too low.
Optionally, in order to realize the nearby material taking and feeding, as shown in fig. 1, a material storage box 70 is further disposed on the propagation expanding container 10, wherein the material storage box 70 includes a water storage tank and a medicine storage box, the water storage tank is used for storing pure water, and the medicine storage box is used for storing various nutrients.
Further, in order to realize automatic feeding, an automatic feeding mechanism can be further arranged on the propagation expanding container 10 and is in signal connection with the main controller 51, the main controller 51 sends a feeding instruction to the automatic feeding mechanism, and the automatic feeding mechanism puts water and various nutrients into the propagation expanding container 10 in proportion based on the feeding instruction so as to complete automatic feeding.
Introduction of folding solar power generation device
While the above has been described for simplicity only, fig. 9-11 show one or more detailed embodiments of the foldable solar power plant, which will be described in further detail with reference to fig. 9-11. According to one aspect of the invention, the invention further provides a folding solar power generation device which can realize continuous power supply of power utilization components in the integrated type indigenous probiotic propagation system, so that the autonomous supply of power is met. As shown in fig. 9 to 11, the folding solar power generation device 60 includes a mounting bracket, a first photovoltaic panel 64, a second photovoltaic panel 65, and a third photovoltaic panel 66.
Wherein: the mounting bracket includes:
the support rod 61 is connected to the top of the propagation container 10, and the first photovoltaic panel 64 is fixedly connected to the support rod 61;
a first rail 62, the first rail 62 being connected above the support bar 61, the second photovoltaic panel 65 being slidably connected to the first rail 62, the second photovoltaic panel 65 being configured to slide along the first rail 62 between a first folded position and a first unfolded position, the first unfolded position being located on a first side (e.g., left side) of the first photovoltaic panel 64, the second photovoltaic panel 65 being folded up and down with respect to the first photovoltaic panel 64 when sliding to the first folded position, the second photovoltaic panel 65 being staggered with respect to the first photovoltaic panel 64 when sliding to the first unfolded position;
a second rail 63, the second rail 63 is connected above the first rail 62, the third photovoltaic panel 66 is slidably connected on the second rail 63, the third photovoltaic panel 66 is configured to slide along the second rail 63 between a second folded position and a second unfolded position, the second unfolded position is located on a second side (for example, the right side) of the first photovoltaic panel 64 opposite to the first side, when the third photovoltaic panel 66 slides to the second folded position, the third photovoltaic panel 66 is folded with the first photovoltaic panel 64 up and down, and when the third photovoltaic panel 66 slides to the second unfolded position, the third photovoltaic panel 66 is staggered with the first photovoltaic panel 64.
As shown in fig. 10 and 11, in the charging state, the second photovoltaic panel 65 slides to the first extended position on the first side of the first photovoltaic panel 64, and the third photovoltaic panel 66 slides to the second extended position on the second side of the first photovoltaic panel 64, at this time, the first photovoltaic panel 64, the second photovoltaic panel 65, and the third photovoltaic panel 66 are completely staggered, that is, the first photovoltaic panel 64, the second photovoltaic panel 65, and the third photovoltaic panel 66 are completely extended in the horizontal direction, and all three photovoltaic panels can receive the sunlight, so that the power generation efficiency of the solar power supply apparatus 60 can be maximized.
In a non-charging state, in the transportation process of the integrated type indigenous probiotic propagation system, the second photovoltaic panel 65 and the third photovoltaic panel 66 are moved toward the middle for interaction until the second photovoltaic panel 65 and the third photovoltaic panel 66 slide to the first overlapping position and the second overlapping position respectively, and at this time, the first photovoltaic panel 64, the second photovoltaic panel 65 and the third photovoltaic panel 66 are overlapped together.
The folding solar power generation device 60 further includes a photovoltaic battery electrically connected to the first photovoltaic panel 64, the second photovoltaic panel 65, and the third photovoltaic panel 66, and the electric energy generated by the first photovoltaic panel 64, the second photovoltaic panel 65, and the third photovoltaic panel 66 is stored in the photovoltaic battery. The output end of the photovoltaic storage battery is electrically connected with a power supply connecting wire of an electric heating control box 21 of the heating device 20, is electrically connected with an air compressor 31 of the aeration device 30, is electrically connected with a high-pressure water pump on a main water pipe 41 of the spraying and cleaning device 40, and is electrically connected with a main controller and a sensing module in the complex expansion thing-linked monitoring device 50, so that power supply for functional modules of the heating device 20, the aeration device 30, the spraying and cleaning device 40, the complex expansion thing-linked monitoring device 50 and the like is realized.
The invention has been described above with a certain degree of particularity. It will be understood by those of ordinary skill in the art that the description of the embodiments is merely exemplary and that all changes that come within the true spirit and scope of the invention are desired to be protected. The scope of the invention is defined by the appended claims rather than by the foregoing description of the embodiments.