CN113403176B

CN113403176B - Synchronous positioning type carbon-neutralization microalgae cultivation device

Info

Publication number: CN113403176B
Application number: CN202110683305.7A
Authority: CN
Inventors: 高志刚; 程军; 何跃; 冯小伟; 高楠; 黄建科; 成守斌; 高志峰; 宣卫华; 辛凯; 郭王彪
Original assignee: Dongtai City Spirulina Bio Engineering Co ltd
Current assignee: Dongtai City Spirulina Bio Engineering Co ltd
Priority date: 2021-06-21
Filing date: 2021-06-21
Publication date: 2023-05-23
Anticipated expiration: 2041-06-21
Also published as: CN113403176A

Abstract

The invention discloses a synchronous positioning type carbon-neutralization microalgae cultivation device, which comprises a synchronous positioning mechanism; according to the invention, the synchronous positioning mechanism is additionally arranged, the longitudinal expansion plate is driven to move upwards through the rotation of the adjusting screw, so that the abutting rod and the abutting block are driven to move upwards, and the abutting block is abutted upwards to the lower side of the sliding clamping block at the lower end of the sliding rod, so that the sliding rod is positioned, the whole carbon neutralization mechanism is positioned, and the carbon neutralization mechanism is more stable in operation.

Description

Synchronous positioning type carbon-neutralization microalgae cultivation device

Technical Field

The invention relates to a synchronous positioning type carbon-neutralization microalgae cultivation device.

Background

At present, microalgae are autotrophic, have heterotrophic or mixed culture capacity in a small part, have the advantages of high photosynthetic rate, rapid propagation and extremely strong environment adaptation, and have important development and utilization values in the fields of renewable energy sources, health care products, cosmetics, sewage treatment and the like; the existing microalgae cultivation device generally breeds microalgae cultivation liquid through a runway type track groove, light sources are needed for microalgae cultivation to improve illumination, oxygen is released to enable growth through absorbing carbon dioxide, the existing microalgae cultivation device generally breeds microalgae cultivation liquid in a cultivation groove through sunlight, carbon dioxide needed by microalgae is generally provided through carbon dioxide in air, the increasing of the carbon dioxide is needed to be utilized and solved, carbon dioxide intake is also an essential element for microalgae cultivation, so that uniform and rapid carbon dioxide release in the microalgae cultivation liquid becomes a protection key point of the device, and structural connection stability is needed to be ensured.

Disclosure of Invention

Aiming at the defects of the prior art, the invention solves the problems that: the synchronous positioning type carbon neutralization microalgae cultivation device is stable in structure, and carbon dioxide can be uniformly and rapidly input for carbon neutralization.

In order to solve the problems, the invention adopts the following technical scheme:

a synchronous positioning type carbon neutralization microalgae cultivation device comprises a base, side baffles, a lower bottom plate, a carbon neutralization mechanism, a sliding rod and a synchronous positioning mechanism; a lower bottom plate is arranged in the middle of the upper end of the base; side baffles are arranged on two sides of the lower bottom plate; a microalgae cultivation runway is enclosed between the lower bottom plate and the side baffle; a plurality of carbon neutralization mechanisms are slidably arranged in the middle of the upper end of the microalgae cultivation runway; the carbon neutralization mechanism comprises a storage box, an on-off pump, a conveying pipe, a connecting pipe, a cavity ring column, a connecting plate, an exhaust hood, a driving motor and a connecting shaft; the storage box is arranged above the middle of the microalgae cultivation runway, and two sides of the storage box are respectively clamped at the upper ends of the side baffles in a sliding way through sliding rods; the bottom of the storage box is connected with a conveying pipe; an opening and closing pump is arranged on the conveying pipe; a plurality of connecting pipes are arranged around the lower end of the conveying pipe; an annular ventilation cavity is formed in the cavity ring column; the outer ends of the connecting pipes are respectively communicated with the periphery of the inner side of the upper end of the cavity ring column, and the connecting pipes are communicated with the annular ventilation cavity; the lower end of the cavity ring column is rotationally clamped with the mounting connecting plate; an exhaust hood is arranged at the lower end of the connecting plate; the exhaust hood is of an annular structure, the upper end of the exhaust hood is opened, the bottom of the exhaust hood is closed, and a plurality of exhaust holes are uniformly formed in the periphery of the exhaust hood; the lower end of the annular ventilation cavity is communicated with the inside of the exhaust hood; the driving motor is arranged in the middle of the cavity ring column through a connecting rod; the lower end of the driving motor is provided with a connecting shaft; the lower end of the connecting shaft is connected with the middle of the upper end of the connecting plate; the upper ends of the side baffles are respectively provided with a sliding clamping groove; the lower end of the sliding rod is respectively provided with a sliding clamping block; the sliding rod is in sliding clamping connection with the sliding clamping groove at the upper end of the side baffle through the sliding clamping block at the lower end; the middle outer sides of the side baffles are respectively provided with a driving slot; the upper end of the driving slot is communicated with the lower end of the sliding clamping groove; a synchronous positioning mechanism is respectively arranged on the driving grooves of the side baffle plates; the synchronous positioning mechanism comprises a longitudinal expansion plate, a supporting rod, a supporting block, a positioning block and an adjusting screw; a longitudinal expansion plate is respectively arranged in the driving slot in a vertically sliding clamping way; the upper end of the longitudinal expansion plate is provided with a supporting rod; the upper end of the abutting rod is provided with an abutting block; the abutting block is positioned right below the sliding clamping block; the outer end of the longitudinal expansion plate is provided with a threaded hole; the threaded holes are respectively threaded with an adjusting screw rod; the outer sides of the side baffles are respectively provided with a positioning block; the upper end of the adjusting screw is rotatably clamped and mounted on the positioning block.

Further, a floating chute is respectively arranged on the inner side of the driving slot; the inner end of the longitudinal expansion plate is clamped on the floating chute in an up-and-down sliding way; a rotary clamping ring is arranged on the outer side of the periphery of the adjusting screw; the positioning block is provided with a clamping rotating groove; the adjusting screw is rotationally clamped on the clamping rotary groove on the positioning block through the peripheral outer rotary clamping ring.

Further, two sides of the lower end of the cavity ring column are respectively communicated with a clamping exhaust head; a rotary clamping ring groove is formed in the periphery of the upper end of the connecting plate; the cavity ring column is rotationally clamped with the rotary clamping ring grooves around the upper end of the connecting plate through clamping exhaust heads on two sides of the lower end; annular grooves are formed in the periphery of the lower end of the rotary clamping ring groove; an annular porous plate is fixedly arranged in the annular groove; the lower end of the annular groove is communicated with the inside of the exhaust hood.

Further, the device also comprises a transverse adjusting mechanism; two sides of the storage box are respectively connected with a sliding rod through a transverse adjusting mechanism; the transverse adjusting mechanism comprises a positioning cylinder, a transverse moving screw, a moving block and a positioning clamping rod; two sides of the storage box are respectively provided with a positioning cylinder, and the outer end of the positioning cylinder is provided with an internal thread groove; the inner thread groove is respectively connected with a transverse moving screw rod in a threaded manner; the outer end of the transverse moving screw is rotatably clamped with a moving block; the outer ends of the moving blocks are respectively connected to the upper ends of the sliding rods; a positioning clamping rod is respectively arranged below the positioning cylinder; one end of the positioning clamping connection rod is fixed on the lower side of the outer end of the positioning cylinder, and the other end of the positioning clamping connection rod is in sliding clamping connection with the lower side of the moving block.

Further, a clamping chute is arranged on the lower side of the moving block; the other end of the positioning clamping connection rod is in sliding clamping connection with a clamping connection chute at the lower side of the moving block.

Further, a rotary clamping joint is arranged at the outer end of the transverse moving screw; the inner end of the moving block is provided with a clamping rotating groove; the transverse moving screw rod is rotationally clamped with the clamping rotating groove at the inner end of the moving block through the rotating clamping joint at the outer end.

Further, the lower bottom plate is made of a transparent glass material; the lower end of the side baffle is fixed on the base, and a light source cavity is enclosed among the lower part of the side baffle, the lower part of the lower bottom plate and the upper part of the base; a light source plate is arranged in the light source cavity; the upper end of the light source plate is uniformly provided with a plurality of luminous light sources.

The beneficial effects of the invention are that

1. According to the invention, the synchronous positioning mechanism is additionally arranged, the longitudinal expansion plate is driven to move upwards through the rotation of the adjusting screw, so that the abutting rod and the abutting block are driven to move upwards, and the abutting block is abutted upwards to the lower side of the sliding clamping block at the lower end of the sliding rod, so that the sliding rod is positioned, the whole carbon neutralization mechanism is positioned, and the carbon neutralization mechanism is more stable in operation.

2. According to the invention, a plurality of carbon neutralization mechanisms are slidably arranged in the middle of the upper end of a microalgae cultivation runway, so that uniform distribution of the carbon neutralization mechanisms is realized, carbon dioxide is downwards conveyed from a storage box through control of an on-off pump, gas enters an annular ventilation cavity of a cavity ring column through a connecting pipe, then enters an annular slot through a clamping exhaust head at the bottom of the annular ventilation cavity, is discharged from an annular porous plate of the annular slot into an exhaust hood, then a driving motor drives the exhaust hood to rotate through a connecting shaft, and gas is uniformly dispersed and thrown out to the outer side around the exhaust hood through inertia, so that the gas is uniformly and rapidly dispersed, and meanwhile, the microalgae cultivation area is stirred and dispersed through rotation of the exhaust hood, so that the contact area of liquid and gas is increased, and the cultivation speed is increased.

Drawings

Fig. 1 is a schematic structural view of the present invention.

FIG. 2 is an enlarged schematic view of the carbon neutralization mechanism of the present invention.

Fig. 3 is an enlarged schematic view of the lateral adjustment mechanism of the present invention.

Fig. 4 is an enlarged schematic view of the synchronous positioning mechanism of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 4, a synchronous positioning type carbon-neutralization microalgae cultivation device comprises a base 1, side baffles 3, a lower bottom plate 2, a carbon neutralization mechanism 4, a sliding rod 6 and a synchronous positioning mechanism 7; a lower bottom plate 3 is arranged in the middle of the upper end of the base 1; side baffles 3 are arranged on two sides of the lower bottom plate 2; a microalgae cultivation runway 23 is enclosed between the lower bottom plate 2 and the side baffle 3; a plurality of carbon neutralization mechanisms 4 are slidably arranged in the middle of the upper end of the microalgae cultivation runway 23; the carbon neutralization mechanism 4 comprises a storage box 41, an on-off pump 43, a conveying pipe 42, a connecting pipe 46, a cavity ring column 44, a connecting plate 45, an exhaust hood 47, a driving motor 48 and a connecting shaft 49; the storage box 41 is arranged above the middle of the microalgae cultivation runway 23, and two sides of the storage box 41 are respectively and slidably clamped at the upper ends of the side baffles 3 through sliding rods 6; the bottom of the storage box 41 is connected with a conveying pipe 42; an on-off pump 43 is arranged on the conveying pipe 42; a plurality of connecting pipes 46 are arranged around the lower end of the conveying pipe 42; an annular ventilation cavity 442 is arranged in the cavity ring column 44; the outer ends of the connecting pipes 46 are respectively communicated with the periphery of the inner side of the upper end of the cavity ring column 44, and the connecting pipes 46 are communicated with the annular ventilation cavity 442; the lower end of the cavity ring column 44 is rotatably clamped with a mounting connecting plate 45; an exhaust hood 47 is arranged at the lower end of the connecting plate 45; the exhaust hood 47 is in an annular structure, the upper end of the exhaust hood 47 is opened, the bottom of the exhaust hood is closed, and a plurality of exhaust holes are uniformly formed in the periphery of the exhaust hood 47; the lower end of the annular ventilation cavity 442 is communicated with the interior of the exhaust hood 47; the driving motor 48 is installed in the middle of the cavity ring column 44 through a connecting rod 481; a connecting shaft 49 is arranged at the lower end of the driving motor 48; the lower end of the connecting shaft 49 is connected to the middle of the upper end of the connecting plate 45; the upper ends of the side baffles 3 are respectively provided with a sliding clamping groove 31; the lower ends of the sliding rods 6 are respectively provided with a sliding clamping block 61; the sliding rod 6 is in sliding clamping connection with the sliding clamping groove 31 at the upper end of the side baffle 3 through the sliding clamping block 61 at the lower end; the middle outer sides of the side baffles 3 are respectively provided with a driving slot 32; the upper end of the driving slot 32 is communicated with the lower end of the sliding clamping groove 31; the driving grooves 32 of the side baffles 3 are respectively provided with a synchronous positioning mechanism 7; the synchronous positioning mechanism 7 comprises a longitudinal expansion plate 71, a joint rod 72, a joint block, a positioning block 73 and an adjusting screw 74; a longitudinal expansion plate 71 is respectively arranged in the driving slot 32 in a vertically sliding and clamping way; the upper end of the longitudinal expansion plate 71 is provided with a supporting rod 72; an abutting block 73 is mounted at the upper end of the abutting rod 72; the abutting block 73 is located right below the sliding clamping block 61; the outer end of the longitudinal expansion plate 71 is provided with a threaded hole 711; the threaded holes 711 are respectively threaded with an adjusting screw 74; the outer sides of the side baffles 3 are respectively provided with a positioning block 75; the upper end of the adjusting screw 74 is rotatably and fixedly connected to the positioning block 75.

As shown in fig. 1 to 4, it is further preferable that a floating runner 321 is provided at the inner side of the driving slot 32, respectively; the inner end of the longitudinal expansion plate 71 is clamped on the floating chute 321 in an up-and-down sliding way; a rotary clamping ring 741 is arranged on the outer side of the periphery of the adjusting screw 74; the positioning block 75 is provided with a clamping rotary groove 751; the adjusting screw 74 is rotationally clamped on the clamping rotary groove 751 on the positioning block 75 through the peripheral outer rotary clamping ring 741. Further preferably, two sides of the lower end of the cavity ring column 44 are respectively provided with a clamping exhaust head 441 in a communicating manner; a rotary clamping ring groove 451 is arranged around the upper end of the connecting plate 45; the cavity ring column 44 is rotationally clamped with the rotary clamping ring grooves 451 around the upper end of the connecting plate 45 through clamping exhaust heads 441 at two sides of the lower end; annular grooves 452 are formed in the periphery of the lower end of the rotary clamping ring groove 451; an annular porous plate 453 is fixedly arranged in the annular groove 452; the lower end of the annular slot 452 communicates with the interior of the exhaust hood 47. Further preferably, the device also comprises a transverse adjusting mechanism 5; both sides of the storage box 41 are respectively connected with a sliding rod 6 through a transverse adjusting mechanism 5; the transverse adjusting mechanism 5 comprises a positioning cylinder 51, a transverse moving screw 52, a moving block 53 and a positioning clamping rod 54; two sides of the storage box 41 are respectively provided with a positioning cylinder 51, and the outer end of the positioning cylinder 51 is provided with an internal thread groove 511; the inner thread groove 511 is respectively connected with a transverse moving screw 52 in a threaded manner; the outer end of the transverse moving screw 52 is rotatably clamped with a moving block 53; the outer ends of the moving blocks 53 are respectively connected to the upper ends of the sliding rods 6; a positioning clamping rod 54 is respectively arranged below the positioning cylinder 51; one end of the positioning clamping rod 54 is fixed to the lower side of the outer end of the positioning cylinder 51, and the other end of the positioning clamping rod 54 is in sliding clamping connection with the lower side of the moving block 53. Further preferably, a clamping chute 532 is provided on the lower side of the moving block 53; the other end of the positioning clamping rod 54 is slidably clamped with a clamping chute 532 at the lower side of the moving block 53. Further preferably, a rotary clamping joint 521 is arranged at the outer end of the transverse moving screw 52; the inner end of the moving block 53 is provided with a clamping rotary groove 531; the lateral moving screw 52 is rotationally clamped with the clamping rotating groove 531 at the inner end of the moving block 53 through the rotating clamping joint 521 at the outer end. Further, the lower base plate 2 is made of a light-transmitting glass material; the lower end of the side baffle plate 3 is fixed on the base 1, and a light source cavity 11 is formed by enclosing the space among the lower part 3 of the side baffle plate, the lower part of the lower bottom plate 2 and the upper part of the base 1; a light source plate 12 is arranged in the light source cavity 11; the upper end of the light source plate 12 is uniformly provided with a plurality of light emitting sources 13.

The invention adds the synchronous positioning mechanism 7, and drives the longitudinal expansion plate 71 to move upwards through the rotation of the adjusting screw 74, so as to drive the abutting rod 72 and the abutting block 73 to move upwards, so that the abutting block 73 is abutted upwards on the lower side of the sliding clamping block 61 at the lower end of the sliding rod 6, thus realizing the positioning of the sliding rod 6, positioning the whole carbon neutralization mechanism 4, and ensuring that the carbon neutralization mechanism 4 is more stable during operation.

According to the invention, a plurality of carbon neutralization mechanisms 4 are slidably arranged in the middle of the upper end of the microalgae cultivation runway 23, so that the carbon neutralization mechanisms 4 are uniformly distributed, carbon dioxide is downwards conveyed from the storage box 41 through control of the on-off pump 43, gas enters the annular ventilation cavity 442 of the cavity ring column 44 through the connecting pipe 42, then enters the annular slot 452 through the clamping exhaust head 441 at the bottom of the annular ventilation cavity 442, is discharged from the annular porous plate 453 of the annular slot 452 into the exhaust hood 47, then the driving motor 48 drives the exhaust hood 47 to rotate through the connecting shaft 49, and the gas is uniformly dispersed and thrown out to the outer side of the periphery of the exhaust hood 47 through inertia, so that the gas is uniformly and rapidly dispersed, and meanwhile, the microalgae cultivation area is stirred and dispersed through rotation of the exhaust hood 47, so that the contact area of liquid and gas is increased, and the cultivation speed is improved.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims

1. The synchronous positioning type carbon-neutralization microalgae cultivation device is characterized by comprising a base, side baffles, a lower bottom plate, a carbon neutralization mechanism, a sliding rod and a synchronous positioning mechanism; a lower bottom plate is arranged in the middle of the upper end of the base; side baffles are arranged on two sides of the lower bottom plate; a microalgae cultivation runway is enclosed between the lower bottom plate and the side baffle; a plurality of carbon neutralization mechanisms are slidably arranged in the middle of the upper end of the microalgae cultivation runway; the carbon neutralization mechanism comprises a storage box, an on-off pump, a conveying pipe, a connecting pipe, a cavity ring column, a connecting plate, an exhaust hood, a driving motor and a connecting shaft; the storage box is arranged above the middle of the microalgae cultivation runway, and two sides of the storage box are respectively clamped at the upper ends of the side baffles in a sliding way through sliding rods; the bottom of the storage box is connected with a conveying pipe; an opening and closing pump is arranged on the conveying pipe; a plurality of connecting pipes are arranged around the lower end of the conveying pipe; an annular ventilation cavity is formed in the cavity ring column; the outer ends of the connecting pipes are respectively communicated with the periphery of the inner side of the upper end of the cavity ring column, and the connecting pipes are communicated with the annular ventilation cavity; the lower end of the cavity ring column is rotationally clamped with the mounting connecting plate; an exhaust hood is arranged at the lower end of the connecting plate; the exhaust hood is of an annular structure, the upper end of the exhaust hood is opened, the bottom of the exhaust hood is closed, and a plurality of exhaust holes are uniformly formed in the periphery of the exhaust hood; the lower end of the annular ventilation cavity is communicated with the inside of the exhaust hood; the driving motor is arranged in the middle of the cavity ring column through a connecting rod; the lower end of the driving motor is provided with a connecting shaft; the lower end of the connecting shaft is connected with the middle of the upper end of the connecting plate; the upper ends of the side baffles are respectively provided with a sliding clamping groove; the lower end of the sliding rod is respectively provided with a sliding clamping block; the sliding rod is in sliding clamping connection with the sliding clamping groove at the upper end of the side baffle through the sliding clamping block at the lower end; the middle outer sides of the side baffles are respectively provided with a driving slot; the upper end of the driving slot is communicated with the lower end of the sliding clamping groove; a synchronous positioning mechanism is respectively arranged on the driving grooves of the side baffle plates; the synchronous positioning mechanism comprises a longitudinal expansion plate, a supporting rod, a supporting block, a positioning block and an adjusting screw; a longitudinal expansion plate is respectively arranged in the driving slot in a vertically sliding clamping way; the upper end of the longitudinal expansion plate is provided with a supporting rod; the upper end of the abutting rod is provided with an abutting block; the abutting block is positioned right below the sliding clamping block; the outer end of the longitudinal expansion plate is provided with a threaded hole; the threaded holes are respectively threaded with an adjusting screw rod; the outer sides of the side baffles are respectively provided with a positioning block; the upper end of the adjusting screw is rotatably clamped and mounted on the positioning block.

2. The synchronous positioning type carbon-neutral microalgae cultivation device of claim 1, wherein a floating chute is respectively arranged on the inner side of the driving slot; the inner end of the longitudinal expansion plate is clamped on the floating chute in an up-and-down sliding way; a rotary clamping ring is arranged on the outer side of the periphery of the adjusting screw; the positioning block is provided with a clamping rotating groove; the adjusting screw is rotationally clamped on the clamping rotary groove on the positioning block through the peripheral outer rotary clamping ring.

3. The synchronous positioning type carbon-neutral microalgae cultivation device according to claim 1, wherein two sides of the lower end of the cavity ring column are respectively communicated with a clamping exhaust head; a rotary clamping ring groove is formed in the periphery of the upper end of the connecting plate; the cavity ring column is rotationally clamped with the rotary clamping ring grooves around the upper end of the connecting plate through clamping exhaust heads on two sides of the lower end; annular grooves are formed in the periphery of the lower end of the rotary clamping ring groove; an annular porous plate is fixedly arranged in the annular groove; the lower end of the annular groove is communicated with the inside of the exhaust hood.

4. The synchronized positioning carbon neutral microalgae culture device of claim 1, further comprising a lateral adjustment mechanism; two sides of the storage box are respectively connected with a sliding rod through a transverse adjusting mechanism; the transverse adjusting mechanism comprises a positioning cylinder, a transverse moving screw, a moving block and a positioning clamping rod; two sides of the storage box are respectively provided with a positioning cylinder, and the outer end of the positioning cylinder is provided with an internal thread groove; the inner thread groove is respectively connected with a transverse moving screw rod in a threaded manner; the outer end of the transverse moving screw is rotatably clamped with a moving block; the outer ends of the moving blocks are respectively connected to the upper ends of the sliding rods; a positioning clamping rod is respectively arranged below the positioning cylinder; one end of the positioning clamping connection rod is fixed on the lower side of the outer end of the positioning cylinder, and the other end of the positioning clamping connection rod is in sliding clamping connection with the lower side of the moving block.

5. The synchronous positioning type carbon-neutral microalgae cultivation device of claim 4, wherein a clamping chute is arranged on the lower side of the moving block; the other end of the positioning clamping connection rod is in sliding clamping connection with a clamping connection chute at the lower side of the moving block.

6. The synchronous positioning type carbon-neutral microalgae cultivation device of claim 4, wherein a rotary clamping joint is arranged at the outer end of the transverse moving screw; the inner end of the moving block is provided with a clamping rotating groove; the transverse moving screw rod is rotationally clamped with the clamping rotating groove at the inner end of the moving block through the rotating clamping joint at the outer end.

7. The synchronized positioning type carbon neutral microalgae cultivation device of claim 1, wherein the lower bottom plate is made of a transparent glass material; the lower end of the side baffle is fixed on the base, and a light source cavity is enclosed among the lower part of the side baffle, the lower part of the lower bottom plate and the upper part of the base; a light source plate is arranged in the light source cavity; the upper end of the light source plate is uniformly provided with a plurality of luminous light sources.