CN116164851B

CN116164851B - Intelligent greenhouse alarm device

Info

Publication number: CN116164851B
Application number: CN202310446550.5A
Authority: CN
Inventors: 董春燕; 董文明; 王春玲; 兰治香
Original assignee: Qingzhou Yatai Agricultural Technology Co ltd
Current assignee: Qingzhou Yatai Agricultural Technology Co ltd
Priority date: 2023-04-24
Filing date: 2023-04-24
Publication date: 2023-06-23
Anticipated expiration: 2043-04-24
Also published as: CN116164851A

Abstract

The invention belongs to the technical field of alarm devices, in particular to an intelligent greenhouse alarm device which comprises a heat insulation plate and a rotary door, wherein two sides of the middle part of an inner cavity of the heat insulation plate are both connected with a rolling rotary drum in a sliding manner through side sliding grooves, two ends of the rolling rotary drum are both connected with friction rollers through rotor motors in a rotating manner, and one side, far away from the rotary door, of the middle part of the surface of the rolling rotary drum is connected with a limiting pull rope in a rotating manner. The device can be through running through the control by temperature change part of heat insulating board both sides, simultaneously carry out temperature monitoring work to the both sides environmental area greenhouse of heat insulating board partition, open the through-hole of heat insulating board and allow relevant personnel to pass through, two adjacent areas are unlikely to lead to two places temperature to be different completely because of separating, the phenomenon of different temperature exchange can appear because of the clearance that separates, the device can be through sliding closing cap and roll the rotary drum and all seal up the clearance that reserves between revolving door and the heat insulating board, and then avoid appearing the problem that the regional temperature difference of adjacent position reduces.

Description

Intelligent greenhouse alarm device

Technical Field

The invention belongs to the technical field of alarm devices, and particularly relates to an intelligent greenhouse alarm device.

Background

Vegetables, fruits and flowers are indispensable articles in daily life of people, and with the gradual improvement of urban construction and people's life quality, the quantity and variety of vegetables, fruits and flowers demand are also gradually increased, and the quality requirement is also gradually improved. In addition, vegetables, fruits and flowers are produced under the out-of-season condition of market demand, and the traditional cultivation mode cannot meet the requirements under the current social demands, so that the crop growth needs to be controlled more accurately.

The suitable growth temperatures of different plants are also different, so that the plants of the same type need to be concentrated in the same area for planting and cultivating, the plants of different areas need to be isolated, then a temperature monitoring device is arranged in each area to monitor the temperature of the area, but in reality, two adjacent areas cannot be completely different in temperature due to separation, different temperature exchange phenomena can occur due to a separated gap, the temperature difference of the adjacent areas is further reduced, and a temperature control device for monitoring the whole environment area cannot monitor the area at the moment, so that the plants of the area cannot develop in the environment suitable for growth, and improvement is needed.

Disclosure of Invention

Aiming at the defects of the prior art, the invention solves the technical problems by adopting the following technical scheme: the utility model provides an intelligent greenhouse alarm device, includes heat insulating board and revolving door, the both sides at heat insulating board inner chamber middle part all have the rolling rotary drum through side position spout sliding connection, the both ends of rolling rotary drum all are connected with friction gyro wheel through the rotation of rotor motor, one side that the revolving door was kept away from to rolling rotary drum surface middle part rotates and is connected with spacing stay cord, the one end that the rolling rotary drum was kept away from to spacing stay cord is fixedly connected with a rollback section of thick bamboo, the device is after plant cultivation district is erect, carry out the subregion through the heat insulating board with the plant in different district, guarantee the inside ambient temperature in different districts, and the revolving door can rotate along the axle center department of heat insulating board, so when relevant personnel need pass different plant districts, the revolving door rotates along the axle center department of heat insulating board through the control bull stick at both ends, open the opening at revolving door middle part, and then allow to pass, including the sliding closing cap, this upper closing cap can shutoff heat insulating board and revolving door joint, the both sides at inner chamber top all are connected with the meshing through the indent rotation, the axle center department of meshing runner has fixed rotor, fixed rotor is pegged graft in the axle center of fixed rotor, fixed rotor surface middle part and the indent fixedly connects.

Preferably, the temperature control part can carry out temperature monitoring work simultaneously to the both sides area of revolving door, the middle part of temperature control part surface and the inner chamber fixed connection of revolving door, the both sides of temperature control part all extend to the outside of revolving door, the both sides of temperature control part surface all fixedly connected with temperature sensing board, one side fixedly connected with control panel of revolving door is kept away from to the temperature control part, one side fixedly connected with buffer structure that the control panel surface is close to the revolving door, the both sides of temperature control part inner chamber all fixedly connected with convection current structure. Because the clearance needs to be reserved between the rotating door and the heat insulation plate, the rotating door can be guaranteed to rotate smoothly, but the phenomenon of different temperature exchange can occur in two adjacent areas due to the clearance between the rotating door and the heat insulation plate, at the moment, a device for starting an inner cavity of the heat insulation plate is needed, the rolling drums at two sides roll along side grooves of the heat insulation plate under the rolling action of friction rollers at two ends, and then a limit pull rope is pulled, so that the surfaces of the rolling drums are gradually inserted into the adapting grooves at two sides of the inner cavity of the rotating door to clamp the rotating door, then the meshing rotating wheel above the rotating door clamps the rotating door under the rotating action of the fixed rotor, the sliding sealing cover is pulled downwards along the sliding groove at the top of the heat insulation plate through the meshing biting teeth, the top of the rotating door is clamped by the sliding sealing cover, and then the clearance reserved between the rotating door and the heat insulation plate is sealed by the sliding sealing cover and the rolling drums. The device can be through running through the control by temperature change part of heat insulating board both sides, simultaneously carry out temperature monitoring work to the both sides environmental area greenhouse of heat insulating board partition to the revolving door can rotate round the axle center department of heat insulating board, opens the through-hole of heat insulating board and allows relevant personnel to pass through, but in reality, two adjacent areas are unlikely to lead to two places temperature to be different totally because of separating, the phenomenon that different temperature exchanges can appear because of the clearance that separates, the device can be through slip closing cap and roll the rotary drum and all seal up the clearance that reserves between revolving door and the heat insulating board, and then avoid appearing the problem that the regional temperature difference of adjacent position reduces.

Preferably, the axle center department fixedly connected with of control by temperature change part inner chamber separates the power supply case, the both sides that separate the power supply case inner chamber all are through removing spout sliding connection's insulating inner shell, the middle part fixedly connected with battery of insulating inner shell inner chamber, the both ends of battery all are fixedly connected with and remove the guide arm, one side on insulating inner shell surface is through arc spring plate and the inner chamber fixed connection who separates the power supply case. The top of heat insulating board inner chamber has seted up the expansion grooving, the surface of sliding closure passes through expansion grooving and the top sliding connection of heat insulating board inner chamber, the surface of meshing runner passes through embedded groove and is connected with the surface meshing of sliding closure, the bottom of sliding closure surface and the top sliding connection of revolving door surface. When the rotary door rotates to open the through hole of the heat insulation board, the inner insulating inner shells at the two sides of the inner cavity are relatively slid and separated along the sliding grooves at the two sides of the separation power supply box under the action of centrifugal force, then the ends of the movable guide rods at the two sides are controlled to be misplaced with the inner cavity joints of the temperature control part, then the temperature control part is powered off, after the rotation is stopped, the compressed arc-shaped spring plate is slowly restored, the insulating inner shells are pushed back to the original position again, so that the temperature control part is restarted to perform temperature control work

Preferably, both sides of the inner cavity of the rotary door are rotationally connected with the axle center of the inner cavity of the heat insulation plate through a control rotating rod, the two sides of the surface of the rotary door are symmetrically provided with the adapting grooves, the surface of the rolling rotary drum is clamped with one side of the surface of the rotary door through the adapting grooves, and the surface of the friction roller is in rolling connection with the inner cavity of the heat insulation plate. The two ends of the separation power supply box are fixedly connected with the middle part of the inner cavity of the temperature control component through the inserting connection rod, the two ends of the storage battery are slidably connected with the joints on the two sides of the inner cavity of the temperature control component through the movable guide rod, and the concave surface of the arc-shaped spring plate is clamped with the surface of the insulating inner shell. When the door rotates to open the through hole of the heat insulation board, because the temperature sensing plates on two sides can all receive the temperature mutation, and the temperature control part still normally works at this moment, so the monitored data can mutation, and then result in the work data abnormality, so the separation power box at this moment can separate the insulating inner shell on two sides of the inner cavity because of centrifugal force, stop the power supply to the temperature control part, on the one hand can keep normal data information, on the other hand can keep the power supply allowance when the temperature control part does not need to work, and the cruising effect of the device is prolonged.

Preferably, the buffer structure comprises a data processing box, the two ends of the data processing box are fixedly connected with a bundling disc, an inner cavity of the bundling disc is fixedly connected with a transfer rod through a connecting wire, one side, close to the rolling rotary drum, of the surface of the control screen is slidably connected with a hinged sliding plate, one end, far away from the control screen, of the hinged sliding plate is rotatably connected with a guiding rotary drum, and one side, far away from the hinged sliding plate, of the inner cavity of the guiding rotary drum is slidably connected with an adherence spring belt. After the surface of control screen receives great impact force, the control screen can slide inwards along the inner chamber of data processing case, and the control screen can slide into the inside of revolving door completely this moment, and can't carry out the contact operation, and the articulated slide of both sides can lead to its contained angle increase because of the extrusion effect this moment to make the other end of articulated slide when rotating along the inner chamber of guide rotary drum, extrude inside arc spring, thereby play the cushioning effect to the control screen.

Preferably, one end of the transfer rod far away from the cluster plate is fixedly connected with the inner cavity of the temperature sensing plate, the surface of the control screen is in sliding connection with the inner cavity of the data processing box, the surface of the data processing box is fixedly connected with one side of the inner cavity of the temperature control part, one side of the surface of the hinged sliding plate is fixedly connected with one end of the wall-attached spring belt, and two ends of the guide rotary drum are fixedly connected with the inner cavity of the data processing box. The control screen of the device extends to the outside of revolving door to easily carry out external operation and observe, but revolving door itself possesses the barrier function, so when the outside receives the impact, bellied control screen is very easy to be impacted and damage, so set up buffer structure, after the surface of control screen receives great impact force, the control screen absorbs the impact force through inside guide rotary drum, reduce the damage that the control screen received, and the control screen can shrink to the inside of data processing case, avoid receiving secondary damage, thereby extension device life.

Preferably, the convection structure comprises a side empty shell, one side of the side empty shell inner cavity, which is close to the control screen, is fixedly connected with a bundling air box, both sides of an air outlet of the bundling air box are respectively inserted with a drainage plate, one side of the side empty shell inner cavity, which is far away from the bundling air box, is fixedly connected with an exhaust pipe through a socket, one end of the exhaust pipe inner cavity, which is close to the bundling air box, is rotationally connected with an inflation threaded rod, an axle center of the inflation threaded rod is fixedly connected with a rotation motor, and a surface fixedly connected with a clamping plate of the rotation motor. The convection structure can play the cooling effect of dispelling the heat to the control screen, rotates the motor control and aerifys the threaded rod and rotate this moment, then aerify the threaded rod and get into the inside of blast pipe with the gas extraction of side position empty shell inner chamber, under the drainage effect of drainage board this moment, the bellows of tied in a bundle is through the unilateral air inlet and is taken out the work of bleeding to the region that the data processing case is located to make the data processing case dispel the heat. The convection structure can play the cooling effect of dispelling the heat to the control panel, under the drainage effect of drainage board, the bellows of tied in a bundle is through the unidirectional air inlet of side to the regional work of bleeding that is located to the data processing case to make the data processing case dispel the heat, can increase the exhaust through the blast pipe moreover, judge the sealing connection effect of rolling rotary drum to the revolving door, from avoiding appearing not sealed rigorous between revolving door and the heat insulating board, and can't observe the problem that leads to the thermal-insulated performance variation.

Preferably, one side of the inner cavity of the bundling bellows, which is close to the buffer structure, is uniformly provided with one-way air inlets, the number of the convection structures is two, one end of the exhaust pipe, which is far away from the side empty shell, is mutually extruded with the surface of the rolling rotary drum, and one side of the inner cavity of the exhaust pipe, which is far away from the side empty shell, is spliced with a reflux switch. The outside that can follow blast pipe spun steam and discharge the control by temperature change part from the end of blast pipe under, after the roll rotary drum of both sides and the side groove joint of revolving door, the roll rotary drum can block up the gas outlet of blast pipe, and the inside pressure of blast pipe increase this moment can lead to gas emission to the backflow switch in, extrudees the backflow switch to stop convection structure's work, thereby represent revolving door and heat insulating board shutoff completely. Convection structure can be opened because the end of blast pipe after the revolving door rotates, and the reposition of redundant personnel effect to the backward flow switch is interrupted, and automatic start, makes the data processing case cool down, when the blast pipe end was plugged up, and the rotation motor can improve the rotation power because the threaded rod that aerifies rotates difficulty, under the effect of backward flow switch this moment, lets in the current of rotation motor and is consumed in the resistance block of reposition of redundant personnel both sides, and the rotation motor can not work because the power supply is not enough, and then avoids appearing the overload problem of rotation motor.

Preferably, the reflux switch comprises a lateral branch pipe, one end fixedly connected with hollow strip shell of blast pipe is kept away from to the lateral branch pipe, the middle part sliding connection of hollow strip shell inner chamber has the division board, the middle part fixedly connected with concave surface shell of division board inner chamber, the equal fixedly connected with resistance block in both ends of division board inner chamber, one side fixedly connected with switching pipe of division board is kept away from to hollow strip shell inner chamber, the inner chamber fixedly connected with of switching pipe and side position hollow shell, the other end fixedly connected with extrusion gasket of switching pipe. After the gas in the inner cavity of the exhaust pipe is introduced into the inner cavity of the hollow strip shell through the lateral branch pipe, the isolation plate starts to slide towards one side close to the extrusion gasket under the stress action of the concave surface shell, so that the concave surface shell is in butt joint with the extrusion gasket, then under the drainage action of the switching guide pipe, the current introduced into the rotating motor is shunted into the resistance blocks at two sides for consumption, and the rotating motor cannot work due to insufficient power supply.

The beneficial effects of the invention are as follows:

1. the device can be through running through the control by temperature change part of heat insulating board both sides, simultaneously carry out temperature monitoring work to the both sides environmental area greenhouse of heat insulating board partition to the revolving door can rotate round the axle center department of heat insulating board, opens the through-hole of heat insulating board and allows relevant personnel to pass through, but in reality, two adjacent areas are unlikely to lead to two places temperature to be different totally because of separating, the phenomenon that different temperature exchanges can appear because of the clearance that separates, the device can be through slip closing cap and roll the rotary drum and all seal up the clearance that reserves between revolving door and the heat insulating board, and then avoid appearing the problem that the regional temperature difference of adjacent position reduces.

2. When the door rotates to open the through hole of the heat insulation board, because the temperature sensing plates on two sides can all receive the temperature mutation, and the temperature control part still normally works at this moment, so the monitored data can mutation, and then result in the work data abnormality, so the separation power box at this moment can separate the insulating inner shell on two sides of the inner cavity because of centrifugal force, stop the power supply to the temperature control part, on the one hand can keep normal data information, on the other hand can keep the power supply allowance when the temperature control part does not need to work, and the cruising effect of the device is prolonged.

3. The control screen of the device extends to the outside of revolving door to easily carry out external operation and observe, but revolving door itself possesses the barrier function, so when the outside receives the impact, bellied control screen is very easy to be impacted and damage, so set up buffer structure, after the surface of control screen receives great impact force, the control screen absorbs the impact force through inside guide rotary drum, reduce the damage that the control screen received, and the control screen can shrink to the inside of data processing case, avoid receiving secondary damage, thereby extension device life.

4. The convection structure can play the cooling effect of dispelling the heat to the control panel, under the drainage effect of drainage board, the bellows of tied in a bundle is through the unidirectional air inlet of side to the regional work of bleeding that is located to the data processing case to make the data processing case dispel the heat, can increase the exhaust through the blast pipe moreover, judge the sealing connection effect of rolling rotary drum to the revolving door, from avoiding appearing not sealed rigorous between revolving door and the heat insulating board, and can't observe the problem that leads to the thermal-insulated performance variation.

5. Convection structure can be opened because the end of blast pipe after the revolving door rotates, and the reposition of redundant personnel effect to the backward flow switch is interrupted, and automatic start, makes the data processing case cool down, when the blast pipe end was plugged up, and the rotation motor can improve the rotation power because the threaded rod that aerifies rotates difficulty, under the effect of backward flow switch this moment, lets in the current of rotation motor and is consumed in the resistance block of reposition of redundant personnel both sides, and the rotation motor can not work because the power supply is not enough, and then avoids appearing the overload problem of rotation motor.

Drawings

FIG. 1 is a front view of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

FIG. 3 is a cross-sectional view of a heat shield of the present invention;

FIG. 4 is a cross-sectional view of a temperature control member of the present invention;

FIG. 5 is a cross-sectional view of a partitioned power supply box of the present invention;

FIG. 6 is a cross-sectional view of a cushioning structure of the present invention;

FIG. 7 is a cross-sectional view of a convection structure of the present invention;

fig. 8 is a cross-sectional view of the return switch of the present invention.

In the figure: 1. a rotating door; 2. a heat insulating plate; 21. rewinding the reel; 22. limiting pull ropes; 23. a rolling drum; 24. friction roller; 25. sliding the cover; 26. engaging the wheel; 27. fixing the rotor; 3. a temperature control component; 31. a temperature sensing plate; 32. a control screen; 33. an adaptation groove; 34. separating the power supply box; 35. an insulating inner housing; 36. moving the guide rod; 37. a storage battery; 38. an arc spring plate; 4. a buffer structure; 41. a data processing box; 42. a cluster plate; 43. a transfer rod; 44. a hinged sliding plate; 45. guiding the rotary drum; 5. a convection structure; 51. a side empty shell; 52. a cluster bellows; 53. a one-way air inlet; 54. a clamping plate; 55. a drainage plate; 56. a rotating motor; 57. an exhaust pipe; 58. an inflatable threaded rod; 6. a reflux switch; 61. a lateral branch pipe; 62. a partition plate; 63. a concave shell; 64. a resistor block; 65. a transfer conduit; 66. extruding the gasket; 67. hollow bar shell.

Detailed Description

The invention will be described in further detail with reference to the drawings and the detailed description. The embodiments of the invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

In embodiment 1, referring to fig. 1 to 5, the present invention provides a technical solution: an intelligent greenhouse alarm device comprises a heat insulation plate 2 and a rotary door 1, wherein both sides of the middle part of an inner cavity of the heat insulation plate 2 are slidably connected with a rolling rotary drum 23 through side sliding grooves, both ends of the rolling rotary drum 23 are rotatably connected with friction rollers 24 through rotor motors, one side of the middle part of the surface of the rolling rotary drum 23 far away from the rotary door 1 is rotatably connected with a limit pull rope 22, one end of the limit pull rope 22 far away from the rolling rotary drum 23 is fixedly connected with a rewinding drum 21,

the sliding sealing cover 25 can seal the gap between the heat insulation plate 2 and the rotary door 1 and clamp the heat insulation plate 2 and the rotary door 1, both sides of the top of the inner cavity of the heat insulation plate 2 are rotationally connected with the meshing rotating wheel 26 through the embedded groove, the axle center of the meshing rotating wheel 26 is inserted with the fixed rotor 27, and the middle part of the surface of the fixed rotor 27 is fixedly connected with the embedded groove;

the temperature control part 3, this temperature control part 3 can carry out temperature monitoring work simultaneously to the both sides region of revolving door 1, the middle part on temperature control part 3 surface and the inner chamber fixed connection of revolving door 1, the both sides of temperature control part 3 all extend to the outside of revolving door 1, the both sides on temperature control part 3 surface are all fixedly connected with temperature sensing board 31, one side fixedly connected with control screen 32 of revolving door 1 is kept away from to temperature control part 3, one side fixedly connected with buffer structure 4 of being close to revolving door 1 is close to on control screen 32 surface, the both sides of temperature control part 3 inner chamber are all fixedly connected with convection current structure 5.

The axle center department fixedly connected with of control by temperature change part 3 inner chamber separates power supply case 34, and the both sides that separate power supply case 34 inner chamber all are through removing spout sliding connection to have insulating inner shell 35, and the middle part fixedly connected with battery 37 of insulating inner shell 35 inner chamber, the both ends of battery 37 all are fixedly connected with and remove guide arm 36, and one side on insulating inner shell 35 surface is through arc spring plate 38 and the inner chamber fixed connection who separates power supply case 34.

The top of the inner cavity of the heat insulation plate 2 is provided with an expansion cutting groove, the surface of the sliding sealing cover 25 is in sliding connection with the top of the inner cavity of the heat insulation plate 2 through the expansion cutting groove, the surface of the engagement rotating wheel 26 is in engagement connection with the surface of the sliding sealing cover 25 through an embedded groove, and the bottom of the surface of the sliding sealing cover 25 is in sliding connection with the top of the surface of the rotating door 1.

The two sides of the inner cavity of the rotary door 1 are rotationally connected with the axis of the inner cavity of the heat insulation plate 2 through control rotating rods, the two sides of the surface of the rotary door 1 are symmetrically provided with the adapting grooves 33, the surface of the rolling rotary drum 23 is clamped with one side of the surface of the rotary door 1 through the adapting grooves 33, and the surface of the friction roller 24 is in rolling connection with the inner cavity of the heat insulation plate 2.

Both ends of the separation power supply box 34 are fixedly connected with the middle part of the inner cavity of the temperature control part 3 through inserting connection rods, both ends of the storage battery 37 are slidably connected with joints on both sides of the inner cavity of the temperature control part 3 through movable guide rods 36, and the concave surface of the arc-shaped spring plate 38 is clamped with the surface of the insulating inner shell 35.

After the plant cultivation area is erected, plants in different areas are partitioned and isolated through the heat insulation plate 2, the environment temperature in the different areas is guaranteed, the rotary door 1 can rotate along the axis of the heat insulation plate 2, so that when related personnel need to pass through different plant areas, the rotary door 1 rotates along the axis of the heat insulation plate 2 through control rotating rods at two ends, and a through hole in the middle of the rotary door 1 is opened to allow passage.

Because a gap is reserved between the rotary door 1 and the heat insulation plate 2, the rotary door 1 can be guaranteed to rotate smoothly, but different temperature exchange phenomena possibly occur in two adjacent areas due to the gap, at the moment, a device for starting the inner cavity of the heat insulation plate 2 is needed, the rolling drums 23 on two sides roll along the side grooves of the heat insulation plate 2 under the rolling action of the friction rollers 24 on two ends, and then the limiting pull ropes 22 are pulled, so that the surfaces of the rolling drums 23 are gradually inserted into the adapting grooves 33 on two sides of the inner cavity of the rotary door 1 to clamp the rotary door 1, then the meshing rotating wheels 26 above the rotating drums clamp the rotary door 1 under the rotating action of the fixed rotor 27, the sliding sealing cover 25 is pulled downwards along the sliding grooves on the top of the heat insulation plate 2 through the meshing biting teeth, the top of the rotary door 1 is clamped by the sliding sealing cover 25, and then the gap reserved between the rotary door 1 and the heat insulation plate 2 is sealed by the sliding sealing cover 25 and the rolling drums 23.

When the rotary door 1 rotates to open the through hole of the heat insulation plate 2, the inner insulating inner shells 35 at the two sides of the inner cavity are relatively slid and separated along the sliding grooves at the two sides of the separating power supply box 34 under the action of centrifugal force, then the ends of the movable guide rods 36 at the two sides are controlled to be misplaced with the inner cavity joints of the temperature control part 3, then the temperature control part 3 is powered off, after the rotation is stopped, the compressed arc-shaped spring plates 38 are slowly restored, the insulating inner shells 35 are pushed back to the original positions again, and the temperature control part 3 is restarted to perform temperature control work.

In embodiment 2, referring to fig. 1 to 8, the present invention provides a technical solution: on the basis of the first embodiment, the buffer structure 4 comprises a data processing box 41, both ends of the data processing box 41 are fixedly connected with a bundling disc 42, an inner cavity of the bundling disc 42 is fixedly connected with a switching rod 43 through a connecting wire, one side of the surface of the control screen 32, which is close to the rolling rotary drum 23, is slidably connected with a hinged sliding plate 44, one end, which is far away from the control screen 32, of the hinged sliding plate 44 is rotatably connected with a guide rotary drum 45, and one side, which is far away from the hinged sliding plate 44, of the inner cavity of the guide rotary drum 45 is slidably connected with an adherence spring band.

One end of the switching rod 43 far away from the cluster plate 42 is fixedly connected with the inner cavity of the temperature sensing plate 31, the surface of the control screen 32 is in sliding connection with the inner cavity of the data processing box 41, the surface of the data processing box 41 is fixedly connected with one side of the inner cavity of the temperature control component 3, one side of the surface of the hinged sliding plate 44 is fixedly connected with one end of the wall-attached spring belt, and two ends of the guiding rotary drum 45 are fixedly connected with the inner cavity of the data processing box 41.

The convection structure 5 comprises a side empty shell 51, a bundling air box 52 is fixedly connected to one side, close to the control screen 32, of an inner cavity of the side empty shell 51, drainage plates 55 are inserted into two sides of an air outlet of the bundling air box 52, an exhaust pipe 57 is fixedly connected to one side, far away from the bundling air box 52, of the inner cavity of the side empty shell 51 through a socket, an inflation threaded rod 58 is rotatably connected to one end, close to the bundling air box 52, of the inner cavity of the exhaust pipe 57, a rotating motor 56 is fixedly connected to an axle center of the inflation threaded rod 58, and a clamping plate 54 is fixedly connected to the surface of the rotating motor 56.

One side of the inner cavity of the bundling bellows 52, which is close to the buffer structure 4, is uniformly provided with one-way air inlets 53, the number of convection structures 5 is two, one end of the exhaust pipe 57, which is far away from the side empty shell 51, is mutually extruded with the surface of the rolling rotary drum 23, and one side of the inner cavity of the exhaust pipe 57, which is far away from the side empty shell 51, is inserted with a backflow switch 6.

When the surface of the control screen 32 receives a large impact force, the control screen 32 slides inwards along the inner cavity of the data processing box 41, at this time, the control screen 32 can completely slide into the inner part of the rotating door 1 and cannot be contacted, and at this time, the included angles of the hinged sliding plates 44 at two sides are increased due to extrusion, so that the other ends of the hinged sliding plates 44 extrude arc springs inside when rotating along the inner cavity of the guiding rotary drum 45, and the control screen 32 is buffered.

The convection structure 5 can play a role in heat dissipation and cooling on the control screen 32, at the moment, the motor 56 is rotated to control the air inflation threaded rod 58 to rotate, then the air inflation threaded rod 58 pumps the air in the inner cavity of the side empty shell 51 into the exhaust pipe 57, at the moment, under the drainage effect of the drainage plate 55, the cluster bellows 52 pumps air through the area where the side one-way air inlet 53 is located on the data processing box 41, so that the data processing box 41 dissipates heat.

The hot air sprayed from the exhaust pipe 57 is discharged to the outside of the temperature control part 3 from the end of the exhaust pipe 57, after the rolling drums 23 on two sides are clamped with the side grooves of the rotary door 1, the air outlet of the exhaust pipe 57 is blocked by the rolling drums 23, and at the moment, the internal pressure of the exhaust pipe 57 is increased, so that the air is discharged into the backflow switch 6, the backflow switch 6 is extruded, the operation of the convection structure 5 is stopped, and the rotary door 1 and the heat insulation plate 2 are completely blocked.

The reflux switch 6 comprises a lateral branch pipe 61, one end of the lateral branch pipe 61 far away from the exhaust pipe 57 is fixedly connected with a hollow strip shell 67, the middle part of the inner cavity of the hollow strip shell 67 is slidably connected with a partition plate 62, the middle part of the inner cavity of the partition plate 62 is fixedly connected with a concave surface shell 63, two ends of the inner cavity of the partition plate 62 are fixedly connected with a resistor block 64, one side of the inner cavity of the hollow strip shell 67 far away from the partition plate 62 is fixedly connected with a transfer conduit 65, one end of the transfer conduit 65 is fixedly connected with the inner cavity of the side hollow shell 51, and the other end of the transfer conduit 65 is fixedly connected with an extrusion gasket 66.

It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art and which are included in the embodiments of the present invention without the inventive step, are intended to be within the scope of the present invention. Structures, devices and methods of operation not specifically described and illustrated herein, unless otherwise indicated and limited, are implemented according to conventional means in the art.

Claims

1. An intelligent greenhouse alarm device, includes heat insulating board (2) and revolving door (1), its characterized in that: both sides in the middle of the inner cavity of the heat insulation plate (2) are respectively connected with a rolling rotary drum (23) in a sliding manner through side sliding grooves, both ends of the rolling rotary drum (23) are respectively connected with a friction roller (24) in a rotating manner through a rotor motor, one side, far away from the rotary door (1), of the middle of the surface of the rolling rotary drum (23) is rotationally connected with a limit pull rope (22), one end, far away from the rolling rotary drum (23), of the limit pull rope (22) is fixedly connected with a rewinding drum (21) and comprises,

the sliding sealing cover (25) can seal a gap between the heat insulation plate (2) and the rotary door (1) and clamp the heat insulation plate (2) and the rotary door (1), two sides of the top of the inner cavity of the heat insulation plate (2) are rotationally connected with the meshing rotating wheel (26) through the embedded groove, a fixed rotor (27) is inserted at the axle center of the meshing rotating wheel (26), and the middle part of the surface of the fixed rotor (27) is fixedly connected with the embedded groove;

temperature control part (3), this temperature control part (3) can carry out temperature monitoring work simultaneously to the both sides region of revolving door (1), the middle part on temperature control part (3) surface and the inner chamber fixed connection of revolving door (1), the both sides of temperature control part (3) all extend to the outside of revolving door (1), the both sides on temperature control part (3) surface are all fixedly connected with temperature sensing board (31), one side fixedly connected with control screen (32) of revolving door (1) is kept away from in temperature control part (3), one side fixedly connected with buffer structure (4) that is close to revolving door (1) on control screen (32) surface, the both sides of temperature control part (3) inner chamber are all fixedly connected with convection current structure (5).

2. An intelligent greenhouse warning apparatus in accordance with claim 1, wherein: the utility model discloses a temperature control device, including insulating inner shell (35), battery (37), arc spring board (38) and inner chamber fixed connection of separating power supply case (34) are passed through to the axle center department fixedly connected with of control by temperature change part (3) inner chamber, the both sides of separating power supply case (34) inner chamber all are through removing spout sliding connection, the middle part fixedly connected with battery (37) of insulating inner shell (35) inner chamber, the both ends of battery (37) all are fixedly connected with removal guide arm (36), one side on insulating inner shell (35) surface is through arc spring board (38) and the inner chamber fixed connection of separating power supply case (34).

3. An intelligent greenhouse warning apparatus in accordance with claim 2, wherein: the top of heat insulating board (2) inner chamber has seted up the expansion grooving, the top sliding connection of sliding closure (25) surface through expansion grooving and heat insulating board (2) inner chamber, the surface of meshing runner (26) is connected with the surface meshing of sliding closure (25) through the embedded groove, the bottom on sliding closure (25) surface and the top sliding connection of revolving door (1) surface.

4. An intelligent greenhouse warning apparatus in accordance with claim 3, wherein: the two sides of the inner cavity of the rotary door (1) are rotationally connected with the axle center of the inner cavity of the heat insulation plate (2) through control rotating rods, the two sides of the surface of the rotary door (1) are symmetrically provided with adapting grooves (33), the surface of the rolling rotary drum (23) is clamped with one side of the surface of the rotary door (1) through the adapting grooves (33), and the surface of the friction roller (24) is in rolling connection with the inner cavity of the heat insulation plate (2).

5. The intelligent greenhouse alarm device according to claim 4, wherein: the two ends of the separation power supply box (34) are fixedly connected with the middle part of the inner cavity of the temperature control component (3) through inserting connection rods, the two ends of the storage battery (37) are slidably connected with the joints on the two sides of the inner cavity of the temperature control component (3) through moving guide rods (36), and the concave surface of the arc-shaped spring plate (38) is clamped with the surface of the insulating inner shell (35).

6. An intelligent greenhouse warning apparatus in accordance with claim 1, wherein: buffer structure (4) are including data processing case (41), the equal fixedly connected with cluster plate (42) in both ends of data processing case (41), the inner chamber of cluster plate (42) is through connecting wire fixedly connected with changeover lever (43), one side sliding connection who is close to rolling rotary drum (23) on control screen (32) surface has articulated slide (44), one end rotation that control screen (32) was kept away from to articulated slide (44) is connected with guide rotary drum (45), one side sliding connection that articulated slide (44) was kept away from to guide rotary drum (45) inner chamber has adherence spring tape.

7. The intelligent greenhouse alarm device according to claim 6, wherein: one end that changeover rod (43) kept away from beam disc (42) and the inner chamber fixed connection of temperature sensing board (31), the surface of control screen (32) and the inner chamber sliding connection of data processing case (41), the surface of data processing case (41) and one side fixed connection of control by temperature change part (3) inner chamber, one side and the one end fixed connection of adherence spring area of articulated slide (44) surface, the both ends of guiding rotary drum (45) all with the inner chamber fixed connection of data processing case (41).

8. An intelligent greenhouse warning apparatus in accordance with claim 1, wherein: the convection structure (5) comprises a side empty shell (51), one side of an inner cavity of the side empty shell (51) close to a control screen (32) is fixedly connected with a bundling air box (52), two sides of an air outlet of the bundling air box (52) are respectively connected with a drainage plate (55) in an inserting mode, one side of the inner cavity of the side empty shell (51) away from the bundling air box (52) is fixedly connected with an exhaust pipe (57) through a socket, one end of the inner cavity of the exhaust pipe (57) close to the bundling air box (52) is rotationally connected with an inflation threaded rod (58), an axle center of the inflation threaded rod (58) is fixedly connected with a rotation motor (56), and a clamping plate (54) is fixedly connected with a surface of the rotation motor (56).

9. The intelligent greenhouse warning apparatus of claim 8, wherein: one side of the inner cavity of the bundling bellows (52) close to the buffer structure (4) is uniformly provided with one-way air inlets (53), the number of the convection structures (5) is two, one end of the exhaust pipe (57) away from the side empty shell (51) is extruded with the surface of the rolling rotary drum (23) mutually, and one side of the inner cavity of the exhaust pipe (57) away from the side empty shell (51) is spliced with a backflow switch (6).