CN212404107U - Intelligent strain generator - Google Patents

Abstract

The utility model belongs to the technical field of strain cultivation equipment, in particular to an intelligent strain generator, which comprises a strain generating box body, a first box body and a second box body, a constant temperature component for maintaining the constant temperature in the strain generating box and a water level constant component for maintaining the constant water level in the strain generating box are arranged in the strain generating box, the upper surface of the strain generating box body is provided with a brown sugar feeding hole and a strain feeding hole, the constant temperature part comprises a heating component and a temperature detecting component, the water level constant component comprises a water inlet control component and a water level detection component, a controller is arranged in the first box body, the movable material plate is arranged in the second box body, and a brown sugar feeding control assembly used for controlling the amount of brown sugar entering the strain generation box body and a strain feeding control assembly used for controlling the amount of strain entering the strain generation box body are arranged on the movable material plate.

Description

Intelligent strain generator

Technical Field

The utility model belongs to the technical field of the bacterial cultivation equipment, especially, relate to an intelligent bacterial generator.

Background

The strains are microorganisms used as live cell catalysts in the fermentation process and comprise four major groups of bacteria, actinomycetes, yeasts and molds. With the development of science and technology, special strain generators for culturing strains are already on the market. However, the existing strain generator has low intelligent degree, still needs a lot of manpower to participate in the strain generator, and greatly reduces the production efficiency.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an intelligent bacterial generator aims at solving the bacterial generator intelligent degree among the prior art and is low, leads to technical problem such as production efficiency is low.

In order to achieve the above object, an embodiment of the present invention provides an intelligent strain generator, which includes a strain generating box, a first box and a second box, wherein the first box and the second box are respectively and fixedly installed on two sides of the upper surface of the strain generating box;

a constant temperature component for maintaining the constant temperature in the strain generating box body and a water level constant component for maintaining the constant water level in the strain generating box body are arranged in the strain generating box body, and a brown sugar feeding hole and a strain feeding hole are formed in the upper surface of the strain generating box body;

the constant temperature part comprises a heating component and a temperature detection component, the heating component is fixedly arranged at the upper end of the strain generation box body, and the temperature detection component is fixedly arranged on the side wall surface of the strain generation box body;

the water level constant component comprises a water inlet control component and a water level detection component, the water inlet control component is fixedly arranged on the lower half part of the side wall surface of the strain generation box body, and the water level detection component is fixedly arranged on the side wall surface of the strain generation box body;

a controller is arranged in the first box body, a display screen is further arranged on the surface of the first box body, and the display screen, the heating assembly, the temperature detection assembly, the water inlet control assembly and the water level detection assembly are all connected with the controller;

the utility model discloses a mushroom growing device, including second box, removal flitch, strain feeding control assembly, controller, brown sugar feeding control assembly, brown sugar.

Optionally, the heating element drives actuating cylinder, with rotatory first connecting plate, the second connecting plate, two removal that drive actuating cylinder connects drive actuating cylinder, third connecting plate and hot plate, two rotatory drive actuating cylinder fixed mounting respectively in the upper end of two relative lateral wall faces of box takes place for the bacterial, the second connecting plate with first connecting plate fixed connection, two the removal drives actuating cylinder fixed mounting respectively in the both ends of second connecting plate, the both ends of third connecting plate respectively with two the removal drives actuating cylinder and connects, the hot plate with third connecting plate fixed connection, rotatory drive actuating cylinder the removal drive actuating cylinder with the hot plate all with the controller is connected.

Optionally, the temperature detection assembly comprises a temperature sensor, the temperature sensor is fixedly mounted on the inner wall surface of the strain generation box body, and the temperature sensor is connected with the controller.

Optionally, be provided with the inlet opening on the box lateral wall face is taken place to the bacterial, the control assembly that intakes including with inlet opening assorted inlet channel, first inlet tube and first flowmeter, the inlet channel with inlet opening fixed connection, first inlet tube fixed mounting be in the inlet channel, first flowmeter fixed mounting be in the delivery end department of first inlet tube, be provided with first solenoid valve on the first inlet tube.

Optionally, the water level detection assembly comprises a water level detection sensor, the water level detection sensor is fixedly mounted on the inner wall surface of the strain generation box body, and the water level detection sensor is connected with the controller.

Optionally, the brown sugar feeding control subassembly is including first storage tank, first ejection of compact pipeline and first discharging pipe, first storage tank fixed mounting be in on the removal flitch, the one end of first ejection of compact pipeline with first storage tank intercommunication, the one end of first discharging pipe with the other end intercommunication of first ejection of compact pipeline, the other end of first discharging pipe is located brown sugar feed port top, be provided with the second solenoid valve on the first ejection of compact pipeline, be provided with the second flowmeter on the first discharging pipe, the second solenoid valve with the second flowmeter all with the controller is connected.

Optionally, the water inlet control assembly further comprises an L-shaped water inlet pipeline, one end of the L-shaped water inlet pipeline is communicated with the water inlet pipeline, a second water inlet pipe is arranged in the L-shaped water inlet pipeline, the second water inlet pipe is communicated with the first water inlet pipe, a third electromagnetic valve is arranged on the second water inlet pipe, a water spray pipe is arranged at the other end of the L-shaped water inlet pipeline and is communicated with the second water inlet pipe, the water spray pipe is located above the bottom of the strain generation box body, and the third electromagnetic valve is connected with the controller.

Optionally, a conductivity sensor is arranged in the strain generating box, a sodium hydroxide feeding hole is formed in the upper surface of the strain generating box, a sodium hydroxide adding component is further arranged on the movable material plate and located above the sodium hydroxide feeding hole, and the conductivity sensor and the sodium hydroxide adding component are connected with the controller.

Optionally, the sodium hydroxide adding assembly comprises a second storage tank, a second discharging pipeline and a second discharging pipe, the second storage tank is fixedly mounted on the movable material plate, one end of the second discharging pipeline is communicated with the second storage tank, one end of the second discharging pipe is communicated with the second discharging pipeline, the other end of the second discharging pipe is located above the sodium hydroxide feeding hole, a fourth electromagnetic valve is arranged on the second discharging pipeline, a third flow meter is arranged on the second discharging pipe, and the fourth electromagnetic valve and the third flow meter are connected with the controller.

The embodiment of the utility model provides an above-mentioned one or more technical scheme in the intelligent bacterial generator have one of following technological effect at least: when the device is used, corresponding parameters are preset by a worker through a display screen, water is injected into the strain generating box body through the water inlet control component, the water level detection component detects the water level height in the strain generating box body in real time and transmits detection data to the controller, when the water level height in the strain generating box body reaches a preset value, the controller sends a corresponding signal to the water inlet control component, the water inlet control component cuts off water supply to the strain generating box body, the brown sugar feeding control component feeds corresponding brown sugar into the strain generating box body according to the preset value, the strain feeding control component feeds corresponding strains into the strain generating box body according to the preset value, the brown sugar is dissolved in the water in the strain generating box body to provide corresponding growing environments for the strains, meanwhile, the temperature detection component monitors the temperature in the strain generating box body in real time and transmits the detection data to the controller, when the temperature in the strain generating box body is lower than the preset value, the controller transmits a corresponding signal to the heating assembly, the heating assembly starts to heat so as to improve the temperature in the strain generating box body, when the temperature in the strain generating box body reaches the preset value, the heating assembly stops working, the temperature in the strain generating box body is kept unchanged, the automation degree of the strain generator is improved, the manual participation degree is low, the intelligent degree of the strain generator is improved, and the production efficiency is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic structural diagram of an intelligent strain generator provided by an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of an intelligent strain generator provided by the embodiment of the present invention.

Fig. 3 is a schematic structural diagram of an intelligent bacterial species generator provided by the embodiment of the present invention.

Fig. 4 is a schematic structural diagram of an intelligent strain generator provided in the embodiment of the present invention.

Fig. 5 is a schematic structural diagram of an intelligent bacterial species generator provided by the embodiment of the present invention.

Fig. 6 is a schematic structural diagram of an intelligent bacterial species generator provided by the embodiment of the present invention.

The device comprises a strain generation box body 1, a constant temperature part 11, a water level constant part 12, a brown sugar feed hole 13, a strain feed hole 14, a conductivity sensor 16, a sodium hydroxide feed hole 17, a heating component 111, a temperature detection component 112, a water inlet control component 121, a water level detection component 122, a rotary driving cylinder 1111, a first connecting plate 1112, a second connecting plate 1113, two movable driving cylinders 1114, a third connecting plate 1115, a heating plate 1116, a temperature sensor 1121, a water inlet pipeline 1211, a first water inlet pipe 1212, an L-shaped water inlet pipeline 1214, a water spray pipe 1215 and a water level detection sensor 1221;

a first box 2, a display screen 21;

the second box body 3, the movable material plate 31, the brown sugar feeding control component 32, the strain feeding control component 33, the sodium hydroxide adding component 34, the first material storage tank 321, the first material discharge pipeline 322, the first material discharge pipe 323, the second flowmeter 324, the second material storage tank 341, the second material discharge pipeline 342, the second material discharge pipe 343, the fourth electromagnetic valve 344, and the third flowmeter 345.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below by referring to the drawings are exemplary and intended to explain the embodiments of the present invention and are not to be construed as limiting the present invention.

In the description of the embodiments of the present invention, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings, which is only for convenience in describing the embodiments of the present invention and simplifying the description, and do not indicate or imply that the device or element so indicated must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the embodiments of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the embodiments of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly, e.g., as fixed or detachable connections or as an integral part; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the embodiments of the present invention can be understood by those skilled in the art according to specific situations.

In an embodiment of the present invention, as shown in fig. 1, fig. 2 and fig. 3, an intelligent seed generator is provided, which includes a seed generating box 1, a first box 2 and a second box 3, wherein the first box 2 and the second box 3 are respectively fixedly installed at two sides of an upper surface of the seed generating box 1;

a constant temperature part 11 for maintaining the temperature in the strain generating box body 1 constant and a water level constant part 12 for maintaining the water level in the strain generating box body 1 constant are arranged in the strain generating box body 1, and a brown sugar feeding hole 13 and a strain feeding hole 14 are arranged on the upper surface of the strain generating box body 1;

the constant temperature component 11 comprises a heating component 111 and a temperature detection component 112, the heating component 111 is fixedly installed at the upper end of the strain generation box body 1, and the temperature detection component 112 is fixedly installed on the side wall surface of the strain generation box body 1;

the water level constant part 12 comprises a water inlet control component 121 and a water level detection component 122, the water inlet control component 121 is fixedly installed on the lower half part of the side wall surface of the strain generation box body 1, and the water level detection component 122 is fixedly installed on the side wall surface of the strain generation box body 1;

a controller (not shown in the figure) is arranged in the first box body 2, a display screen 21 is further arranged on the surface of the first box body 2, and the display screen 21, the heating component 111, the temperature detection component 112, the water inlet control component 121 and the water level detection component 122 are all connected with the controller;

be provided with in the second box 3 and remove flitch 31, remove flitch 31 with the lateral wall face lower extreme sliding connection of second box 3, it is used for control to get into to be provided with on the removal flitch 31 brown sugar feeding control subassembly 32 of the amount of brown sugar of box 1 is taken place to the bacterial and is used for control to get into the bacterial feeding control subassembly 33 of the amount of bacterial of box 1 is taken place to the bacterial, brown sugar feeding control subassembly 32 is located brown sugar feed port 13 top, bacterial feeding control subassembly 33 is located bacterial feed port 14 top, brown sugar feeding control subassembly 32 with bacterial feeding control subassembly 33 all with the controller is connected.

In the utility model, when in use, the staff sets corresponding parameters in advance through the display screen 21, and then injects water into the strain generation box 1 through the water inlet control component 121, the water level detection component 122 detects the water level height in the strain generation box 1 in real time and transmits the detection data to the controller, when the water level height in the strain generation box 1 reaches a preset value, the controller sends corresponding signals to the water inlet control component 121, the water inlet control component 121 cuts off the water supply to the strain generation box 1, the brown sugar feeding control component 32 feeds corresponding brown sugar into the strain generation box 1 according to the preset value, the strain feeding control component 33 feeds corresponding strains into the strain generation box 1 according to the preset value, and the brown sugar is dissolved in the water in the strain generation box 1, the corresponding growth environment is provided for strains, meanwhile, the temperature detection component 112 monitors the temperature in the strain generation box body 1 in real time and transmits detection data to the controller, when the temperature in the strain generation box body 1 is lower than a preset value, the controller transmits corresponding signals to the heating component 111, the heating component 111 starts to heat so as to improve the temperature in the strain generation box body 1, when the temperature in the strain generation box body 1 reaches the preset value, the heating component 111 stops working, the temperature in the strain generation box body 1 is guaranteed to be kept unchanged, the automation degree of the strain generator is improved, the artificial participation degree is low, the intelligence degree of the strain generator is improved, and the production efficiency is improved.

In another embodiment of the present invention, as shown in fig. 4, the heating assembly 111 comprises two rotary driving cylinders 1111, a first connecting plate 1112 connected to the rotary driving cylinders 1111, a second connecting plate 1113, two movable driving cylinders 1114, a third connecting plate 1115 and a heating plate 1116, the two rotary driving cylinders 1111 are respectively fixedly installed at the upper ends of two opposite side wall surfaces of the seed culture generation case 1, the second connecting plate 1113 is fixedly connected with the first connecting plate 1112, two movable driving cylinders 1114 are respectively and fixedly arranged at two ends of the second connecting plate 1113, both ends of the third connecting plate 1115 are connected to the two movement driving cylinders 1114, the heating plate 1116 is fixedly connected to the third connecting plate 1115, and the rotary driving cylinder 1111, the movable driving cylinder 1114 and the heating plate 1116 are connected to the controller.

In the utility model, when the temperature detecting component 112 detects that the temperature in the spawn generation box 1 is lower than the preset value, the controller sends a corresponding signal to the heating component 111, the rotation driving cylinder 1111 drives the first connecting plate 1112 to rotate vertically, the first connecting plate 1112 drives the second connecting plate 1113 to rotate, the second connecting plate 1113 drives the movement driving cylinder 1114 to rotate, the movement driving cylinder 1114 drives the third connecting plate 1115 to rotate, the third connecting plate 1115 drives the heating plate 1116 to rotate, so that the heating plate 1116 rotates from vertical to horizontal, then the movement driving cylinder 1114 starts to work, the third connecting plate 1115 is driven by the movement driving cylinder 1114 to move to the middle position of the spawn generation box 1, the heating plate 1116 is driven by the third connecting plate 1115 to move to the middle position of the spawn generation box 1, then the heating plate 1116 begins to work and generate heat, the heat that the heating plate 1116 sent can be followed the intermediate position of bacterial emergence box 1 upper portion is towards spreading all around, has avoided traditional bacterial generator directly to be in the local heat that the inside corner installation heating rod of bacterial emergence box 1 heated and bring is very high, causes near the heating rod easily because of the high temperature death.

In another embodiment of the present invention, as shown in fig. 2, fig. 4 and fig. 5, the temperature detecting assembly 112 includes a temperature sensor 1121, the temperature sensor 1121 is fixedly installed on the inner wall surface of the spawn generating box 1, and the temperature sensor 1121 is connected to the controller. When the temperature sensor 1121 is used, the temperature sensor 1121 detects the temperature in the spawn generation box body 1 in real time and transmits detection data to the controller, when the temperature in the spawn generation box body 1 is lower than a preset value, the controller sends a corresponding signal to the heating component 111, the heating component 111 starts to work and heat so as to increase the temperature in the spawn generation box body 1, and when the temperature sensor 1121 detects that the temperature in the spawn generation box body 1 is recovered to a normal value, the heating component 111 stops heating, so that the temperature in the spawn generation box body 1 is constant.

In another embodiment of the present invention, as shown in fig. 5, a water inlet is disposed on a side wall surface of the strain generating box 1, the water inlet control assembly 121 includes a water inlet pipe 1211, a first water inlet pipe 1212, and a first flowmeter, the water inlet pipe 1211 is fixedly connected to the water inlet, the first water inlet pipe 1212 is fixedly installed in the water inlet pipe 1211, the first flowmeter is fixedly installed at a water outlet of the first water inlet pipe 1212, and a first electromagnetic valve (not shown) is disposed on the first water inlet pipe 1212.

In this embodiment, when in use, the first electromagnetic valve is opened, water enters the spawn generation tank 1 through the first water inlet pipe 1212, the first flow meter calculates the flow rate of the water entering the spawn generation tank 1 in real time and transmits the flow rate to the controller, the water level height inside the spawn generation tank 1 can be known through calculating the flow rate of the water entering the spawn generation tank 1, the water level detection assembly 122 detects the water level height inside the spawn generation tank 1 in real time, when the water level height inside the spawn generation tank 1 reaches a preset value, the controller sends a corresponding signal to the first electromagnetic valve, the first electromagnetic valve is closed, the water supply to the spawn generation tank 1 through the first water inlet pipe 1212 is cut off, and the first flow meter and the water level detection assembly 122 cooperate to fully ensure that the water level height inside the spawn generation tank 1 meets the requirement, the problem that the water level is too high due to the fact that the water level in the strain generation box body 1 cannot be accurately measured when the first flowmeter or the water level detection assembly 122 is damaged is solved.

In another embodiment of the present invention, as shown in fig. 5, the water level detecting assembly 122 includes a water level detecting sensor 1221, the water level detecting sensor 1221 is fixedly installed on the inner wall surface of the spawn generating box 1, and the water level detecting sensor 1221 is connected to the controller. When the water level sensor is used, the water level sensor detects the water level height of the strain generation box body 1 in real time, when the water level height in the strain generation box body 1 reaches a preset value, the water level detection sensor 1221 sends a corresponding signal to the controller, the controller sends a corresponding signal to the water inlet control assembly 121, and the water supply to the strain generation box body 1 through the water inlet control assembly 121 is cut off, so that the water level height of the strain generation box body 1 meets the requirement, the automation degree of the strain generator is improved, and the intelligence of the strain generator is realized.

In another embodiment of the present invention, as shown in fig. 6, the brown sugar feeding control assembly 32 includes a first storage tank 321, a first discharging pipe 322 and a first discharging pipe 323, the first storage tank 321 is fixedly mounted on the movable material plate 31, one end of the first discharging pipe 322 is communicated with the first storage tank 321, one end of the first discharging pipe 323 is communicated with the other end of the first discharging pipe 322, the other end of the first discharging pipe 323 is located above the brown sugar feeding hole 13, a second electromagnetic valve is disposed on the first discharging pipe 322, a second flow meter 324 is disposed on the first discharging pipe 323, and the second electromagnetic valve and the second flow meter 324 are both connected to the controller.

Wherein, the structure of the strain feed control component 33 is the same as that of the brown sugar feed control component 32, and will not be described here.

In this embodiment, in use, the controller sends a signal to the second solenoid valve, which opens, the brown sugar in the first storage tank 321 flows to the first discharging pipe 323 through the first discharging pipe 322, then, brown sugar enters the spawn generating box body 1 through the brown sugar feeding hole 13, the second flowmeter 324 detects the amount of the brown sugar passing through the first discharging pipe 323 in real time, when the second flow meter 324 detects that the amount of brown sugar entering the spawn running box 1 through the first feed pipe reaches a preset value, the second flow meter 324 sends a corresponding signal to the controller, which sends a corresponding signal to the second solenoid valve, the second solenoid valve is closed for brown sugar in the first storage tank 321 can not get into again in the box 1 takes place for the bacterial, has guaranteed that the brown sugar quantity of box 1 takes place for the bacterial meets the requirements. The strain feeding control component 33 injects a certain amount of strain into the strain generation box 1 by the same principle as the brown sugar feeding control component 32. The intellectualization of the strain generator is realized, the manual participation is reduced, and the production efficiency is improved.

In another embodiment of the present invention, as shown in fig. 5, the water inlet control assembly 121 further includes an "L" type water inlet pipe 1214, one end of the "L" type water inlet pipe 1214 is communicated with the water inlet pipe 1211, a second water inlet pipe is disposed in the "L" type water inlet pipe 1214, the second water inlet pipe is communicated with the first water inlet pipe 1212, a third electromagnetic valve is disposed on the second water inlet pipe, a water spray pipe 1215 is disposed at the other end of the "L" type water inlet pipe 1214, the water spray pipe 1215 is communicated with the second water inlet pipe, the water spray pipe 1215 is located above the bottom of the spawn generating box 1, and the third electromagnetic valve is connected with the controller. When the device is used, the third electromagnetic valve is closed, water flows into the strain generation box body 1 through the first water inlet pipe 1212, when the strain generation box body 1 needs to be cleaned, the first electromagnetic valve is closed, the third electromagnetic valve is opened, water flows to the second water inlet pipe and is sprayed out through the water spraying pipe 1215 to clean the strain generation box body 1, and the problem that the conventional strain generator is not clean due to the fact that water is directly injected into the strain generation box body through the water inlet pipe for cleaning is solved.

In another embodiment of the present invention, as shown in fig. 5 and fig. 6, a conductivity sensor 16 is disposed in the strain generating box 1, the upper surface of the strain generating box 1 is provided with a sodium hydroxide feeding hole 17, a sodium hydroxide adding component 34 is further disposed on the movable material plate 31, the sodium hydroxide adding component 34 is located above the sodium hydroxide feeding hole 17, and the conductivity sensor 16 and the sodium hydroxide adding component 34 are both connected to the controller. When the device is used, the conductivity detects the conductivity of the liquid in the strain generation box body 1 in real time, when the detected conductivity is lower than a preset value, the controller sends a corresponding signal to the sodium hydroxide adding component 34, and the sodium hydroxide adding component 34 adds a certain amount of sodium hydroxide into the strain generation box body 1 through the sodium hydroxide feeding hole 17 so as to improve the conductivity of the liquid in the strain generation box body 1 and promote the growth of strains.

In another embodiment of the present invention, as shown in fig. 6, the sodium hydroxide adding assembly 34 includes a second storage tank 341, a second discharging pipe 342 and a second discharging pipe 343, the second storage tank 341 is fixedly mounted on the movable material plate 31, one end of the second discharging pipe 342 is communicated with the second storage tank 341, one end of the second discharging pipe 343 is communicated with the second discharging pipe 342, the other end of the second discharging pipe 343 is located above the sodium hydroxide feeding hole 17, the second discharging pipe 342 is provided with a fourth electromagnetic valve 344, the second discharging pipe 343 is provided with a third flow meter 345, and the fourth electromagnetic valve 344 and the third flow meter 345 are both connected to the controller. In use, when the conductivity sensor 16 senses that the conductivity in the spawn running box 1 is lower than a preset value, the controller sends a corresponding signal to the fourth solenoid valve 344, the sodium hydroxide in the second storage tank 341 flows to the second discharge pipe 343 through the second discharge pipe 342, then enters the strain generation box body 1 through the sodium hydroxide inlet hole 17, the third flow meter 345 detects the amount of the sodium hydroxide entering the strain generation box body 1 through the second discharge pipe 343 in real time, when the amount of sodium hydroxide dosed is sufficient, the controller sends a corresponding signal to the fourth solenoid valve 344, the fourth electromagnetic valve 344 is closed, so that the sodium hydroxide in the second storage tank 341 cannot enter the spawn generation tank 1, and the automatic adjustment of the liquid conductivity in the spawn generation tank 1 is realized.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (9)

1. An intelligent strain generator is characterized by comprising a strain generating box body, a first box body and a second box body, wherein the first box body and the second box body are respectively and fixedly arranged on two sides of the upper surface of the strain generating box body;

a constant temperature component for maintaining the constant temperature in the strain generating box body and a water level constant component for maintaining the constant water level in the strain generating box body are arranged in the strain generating box body, and a brown sugar feeding hole and a strain feeding hole are formed in the upper surface of the strain generating box body;

the constant temperature part comprises a heating component and a temperature detection component, the heating component is fixedly arranged at the upper end of the strain generation box body, and the temperature detection component is fixedly arranged on the side wall surface of the strain generation box body;

the water level constant component comprises a water inlet control component and a water level detection component, the water inlet control component is fixedly arranged on the lower half part of the side wall surface of the strain generation box body, and the water level detection component is fixedly arranged on the side wall surface of the strain generation box body;

a controller is arranged in the first box body, a display screen is further arranged on the surface of the first box body, and the display screen, the heating assembly, the temperature detection assembly, the water inlet control assembly and the water level detection assembly are all connected with the controller;

the utility model discloses a mushroom growing device, including second box, removal flitch, strain feeding control assembly, controller, brown sugar feeding control assembly, brown sugar.

2. The intelligent strain generator as claimed in claim 1, wherein the heating assembly comprises two rotary driving cylinders, a first connecting plate connected with the rotary driving cylinders, a second connecting plate, two movable driving cylinders, a third connecting plate and a heating plate, the two rotary driving cylinders are respectively fixedly installed at the upper ends of two opposite side wall surfaces of the strain generating box body, the second connecting plate is fixedly connected with the first connecting plate, the two movable driving cylinders are respectively fixedly installed at two ends of the second connecting plate, two ends of the third connecting plate are respectively connected with the two movable driving cylinders, the heating plate is fixedly connected with the third connecting plate, and the rotary driving cylinders, the movable driving cylinders and the heating plate are all connected with the controller.

3. The intelligent strain generator as claimed in claim 1 or 2, wherein the temperature detection assembly comprises a temperature sensor, the temperature sensor is fixedly mounted on an inner wall surface of the strain generation box body, and the temperature sensor is connected with the controller.

4. The intelligent strain generator as claimed in claim 1 or 2, wherein a water inlet is provided on a side wall surface of the strain generating box, the water inlet control assembly comprises a water inlet pipe, a first water inlet pipe and a first flow meter, the water inlet pipe is matched with the water inlet, the water inlet pipe is fixedly connected with the water inlet, the first water inlet pipe is fixedly installed in the water inlet pipe, the first flow meter is fixedly installed at a water outlet end of the first water inlet pipe, and a first electromagnetic valve is provided on the first water inlet pipe.

5. The intelligent strain generator as claimed in claim 1 or 2, wherein the water level detection assembly comprises a water level detection sensor, the water level detection sensor is fixedly mounted on an inner wall surface of the strain generation tank, and the water level detection sensor is connected with the controller.

6. The intelligent strain generator as claimed in claim 1 or 2, wherein the brown sugar feeding control assembly comprises a first storage tank, a first discharging pipe and a first discharging pipe, the first storage tank is fixedly mounted on the movable material plate, one end of the first discharging pipe is communicated with the first storage tank, one end of the first discharging pipe is communicated with the other end of the first discharging pipe, the other end of the first discharging pipe is located above the brown sugar feeding hole, a second electromagnetic valve is arranged on the first discharging pipe, a second flow meter is arranged on the first discharging pipe, and the second electromagnetic valve and the second flow meter are both connected with the controller.

7. The intelligent strain generator as claimed in claim 4, wherein the water inlet control assembly further comprises an "L" type water inlet pipe, one end of the "L" type water inlet pipe is communicated with the water inlet pipe, a second water inlet pipe is arranged in the "L" type water inlet pipe, the second water inlet pipe is communicated with the first water inlet pipe, a third electromagnetic valve is arranged on the second water inlet pipe, a water spray pipe is arranged at the other end of the "L" type water inlet pipe, the water spray pipe is communicated with the second water inlet pipe, the water spray pipe is located above the bottom of the strain generation box body, and the third electromagnetic valve is connected with the controller.

8. The intelligent strain generator as claimed in claim 1 or 2, wherein a conductivity sensor is arranged in the strain generation box body, a sodium hydroxide feeding hole is arranged on the upper surface of the strain generation box body, a sodium hydroxide adding component is further arranged on the movable material plate, the sodium hydroxide adding component is positioned above the sodium hydroxide feeding hole, and the conductivity sensor and the sodium hydroxide adding component are both connected with the controller.

9. The intelligent strain generator as claimed in claim 8, wherein the sodium hydroxide adding assembly comprises a second storage tank, a second discharging pipeline and a second discharging pipe, the second storage tank is fixedly mounted on the movable material plate, one end of the second discharging pipeline is communicated with the second storage tank, one end of the second discharging pipe is communicated with the second discharging pipeline, the other end of the second discharging pipe is located above the sodium hydroxide feeding hole, a fourth electromagnetic valve is arranged on the second discharging pipeline, a third flow meter is arranged on the second discharging pipe, and the fourth electromagnetic valve and the third flow meter are both connected with the controller.

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