CN116215396B - Multifunctional data acquisition and transmission device - Google Patents

Abstract

The invention relates to the technical field of signal data acquisition, in particular to a multifunctional data acquisition and transmission device, which comprises an acquisition shell and a sliding rail, wherein a mounting plate is connected inside the acquisition shell, a penetrating opening for the sliding rail to penetrate is formed between the mounting plate and the inner wall of the acquisition shell, a driving assembly is arranged in the acquisition shell, the acquisition shell slides reciprocally along the sliding rail through the driving assembly, two groups of data acquisition assemblies are respectively arranged at the upper end and the lower end of the acquisition shell, each data acquisition assembly comprises a temperature sensing probe and a humidity sensing probe, two groups of moving assemblies are symmetrically arranged inside the acquisition shell up and down, and each group of moving assemblies drives the corresponding data acquisition assembly to reciprocate on the acquisition shell in a straight line. The invention realizes the mobile data acquisition and transmission process, and simultaneously realizes the reciprocating movement of data acquisition by utilizing the mobile component, thereby increasing the signal data acquisition range and improving the coverage comprehensiveness of the signal data acquisition.

Description

Multifunctional data acquisition and transmission device

Technical Field

The invention relates to the technical field of signal data, in particular to a multifunctional data acquisition and transmission device.

Background

At present, the quality of agricultural products is the focus of national attention, is closely related to national health, is more and more valued, and the position and environmental factors in regional characteristic agricultural product transportation are one of important factors influencing the quality of the agricultural products, so that the quality of the agricultural products can be ensured and the whole process of agricultural products can be traced to the source by monitoring the agricultural product transportation process in real time, and the benefits of consumers are effectively ensured.

The development of cold chain logistics solves the limitation of agricultural product seasons and regions, can effectively reduce the loss of agricultural products and the reduction of quality in the transportation process, the detection element needs to be configured in the transportation carriage to acquire and transmit the environmental data in the carriage, at present, the data acquisition terminal in the transportation carriage is often installed at a certain fixed position, and because of the huge quantity of agricultural product transportation, the container size of the transportation carriage is large and the size is long, the acquisition and transmission of signal data at fixed points are limited, and the transportation environment in the carriage cannot be accurately fed back.

Disclosure of Invention

The invention aims to provide a multifunctional data acquisition and transmission device and aims to solve the technical problems.

The aim of the invention can be achieved by the following technical scheme:

the utility model provides a multi-functional data acquisition transmission device, includes gathers casing and slide rail, the internally connected of gathering the casing has the mounting panel, form the interlude mouth that supplies the slide rail to pass between mounting panel and the inner wall of gathering the casing, be provided with drive assembly in the gathering the casing, it slides reciprocally through drive assembly along the slide rail to gather the casing, the upper and lower both ends of gathering the casing are provided with two sets of data acquisition components respectively, data acquisition component includes temperature sensing probe and humidity sensing probe, the inside symmetry of gathering the casing is provided with two sets of moving assembly from top to bottom, every group moving assembly drives corresponding data acquisition component and reciprocates rectilinear movement on gathering the casing, the preceding terminal surface of gathering the casing rotates and installs the apron, be provided with monitor probe on the apron, control main board is installed to the rear end face of gathering the casing, control main board outside cladding is provided with sealed housing;

every group remove the subassembly including rotating motor, eccentric block, lifter plate and piston cylinder, the rotating motor sets up in the mounting panel outside, the rotating motor output is connected with the eccentric block, the lifter plate symmetry sets up in the upper and lower both ends of eccentric block, just the lifter plate is supported all the time in the outward flange of eccentric block under the extrusion spring effect, the piston cylinder has two and sets up the both ends at the lifter plate, be provided with lift piston rod and sideslip piston rod in the piston cylinder, the lift piston rod is connected with the lifter plate, the sideslip piston rod is connected with the installation base, temperature-sensing probe and humidity-sensing probe set up respectively on corresponding installation base.

As a further scheme of the invention: the driving assembly comprises a first motor connected to the top end of the mounting plate and a second motor connected to the bottom end of the mounting plate, a first gear and a second gear are respectively arranged on the upper side and the lower side in the penetrating socket, an output shaft of the first motor is connected with the first gear, an output shaft of the second motor is connected with the second gear, and the first gear and the second gear are respectively matched with racks on the side walls of the sliding rail in a toothed manner.

As a further scheme of the invention: the piston cylinder is L-shaped, and is integrally formed by a vertical cylinder and a horizontal cylinder, the vertical cylinder is fixedly connected with the mounting plate through a connecting block, the lifting piston rod is slidably arranged in the vertical cylinder, and the transverse moving piston cylinder is arranged in the horizontal cylinder.

As a further scheme of the invention: and a reset spring is arranged between the transverse piston rod and the horizontal cylinder.

As a further scheme of the invention: the apron top is through pivot and collection casing normal running fit, the apron bottom is provided with the buckle, the apron bottom is through the buckle with gather the casing and can dismantle the connection.

As a further scheme of the invention: the collecting shell is provided with a chute through which the temperature sensing probe and the humidity sensing probe are adapted to pass.

As a further scheme of the invention: the control mainboard is respectively and electrically connected with the temperature sensing probe, the humidity sensing probe and the monitoring probe, and is provided with a control chip, a wireless communication module, a memory and a socket.

As a further scheme of the invention: the collecting shell is characterized in that a power module is arranged on the rear end face of the collecting shell, and a heat insulation protection layer is arranged on the inner wall of the sealing shell.

The invention has the beneficial effects that:

according to the invention, the through socket is formed between the mounting plate and the acquisition shell, the acquisition shell is driven by the driving assembly to reciprocate along the sliding rail, so that the traditional fixed point data acquisition mode is abandoned, the movable data acquisition and transmission process is realized, the coverage comprehensiveness of signal data acquisition is effectively improved, and meanwhile, in the moving process, each group of temperature sensing probes and humidity sensing probes can reciprocate on the acquisition shell by the moving assembly, so that the signal data acquisition range is effectively increased, and the accuracy of signal data is improved.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the exterior structure of the acquisition housing of the present invention;

FIG. 3 is a schematic view of the internal structure of the acquisition housing of the present invention;

FIG. 4 is a schematic diagram of a control motherboard according to the present invention;

FIG. 5 is a schematic view of a moving assembly of the present invention;

fig. 6 is a schematic view of the structure of the piston cylinder in the present invention.

In the figure: 1. a collecting shell; 2. a slide rail; 3. a mounting plate; 4. a through socket; 5. a temperature sensing probe; 6. a humidity sensing probe; 7. a cover plate; 71. a rotating shaft; 72. a buckle; 8. monitoring a probe; 9. a control main board; 10. a sealed enclosure; 11. a rotating motor; 12. an eccentric block; 13. a lifting plate; 14. a piston cylinder; 141. a vertical cylinder; 142. a horizontal cylinder; 15. extruding a spring; 16. lifting a piston rod; 17. a lateral sliding piston rod; 18. a mounting base; 19. a return spring; 20. a first motor; 21. a second motor; 22. a first gear; 23. a second gear; 24. a control chip; 25. a wireless communication module; 26. a memory; 27. a socket; 28. a power module; 29. and a heat insulation protective layer.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, the invention discloses a multifunctional data acquisition and transmission device, which comprises an acquisition shell 1 and a sliding rail 2, wherein a mounting plate 3 is connected inside the acquisition shell 1, a penetrating opening 4 for the sliding rail 2 to penetrate is formed between the mounting plate 3 and the inner wall of the acquisition shell 1, a driving assembly is arranged in the acquisition shell 1, the acquisition shell 1 slides reciprocally along the sliding rail 2 through the driving assembly, two groups of data acquisition assemblies are respectively arranged at the upper end and the lower end of the acquisition shell 1, each data acquisition assembly comprises a temperature sensing probe 5 and a humidity sensing probe 6, two groups of moving assemblies are symmetrically arranged inside the acquisition shell 1, each group of moving assemblies drives the corresponding data acquisition assembly to reciprocate on the acquisition shell 1 in a straight line, a cover plate 7 is rotatably arranged on the front end face of the acquisition shell 1, a monitoring probe 8 is arranged on the cover plate 7, a control main plate 9 is arranged on the rear end face of the acquisition shell 1, and a sealing cover shell 10 is arranged outside the control main plate 9 in a cladding manner.

As shown in fig. 5 and 6, each group of moving components comprises a rotating motor 11, an eccentric block 12, a lifting plate 13 and a piston cylinder 14, wherein the rotating motor 11 is arranged outside the mounting plate 3, the output end of the rotating motor 11 is connected with the eccentric block 12, the lifting plate 13 is symmetrically arranged at the upper end and the lower end of the eccentric block 12, the lifting plate 13 is always abutted against the outer edge of the eccentric block 12 under the action of an extrusion spring 15, two piston cylinders 14 are arranged at the two ends of the lifting plate 13, lifting piston rods 16 and transverse piston rods 17 are arranged in the piston cylinders 14, the lifting piston rods 16 are connected with the lifting plate 13, the transverse piston rods 17 are connected with the mounting bases 18, and the temperature sensing probes 5 and the humidity sensing probes 6 are respectively arranged on the corresponding mounting bases 18.

Specifically, the whole device of the invention is composed of the acquisition shell 1 and the sliding rail 2, wherein the sliding rail 2 is fixedly arranged in a transportation carriage through connecting ends at two ends, a certain gap is reserved between the sliding rail 2 and the side wall of the carriage, the sliding rail 2 passes through a penetration opening 4 in the acquisition shell 1, the acquisition shell 1 is driven by a driving component to slide back and forth along the sliding rail 2, and in the sliding process, the temperature sensing probe 5, the humidity sensing probe 6 and the monitoring probe 8 can respectively acquire temperature signals, humidity signals and image signals in the transportation carriage, so that the traditional data acquisition mode of fixed points is abandoned, the movable data acquisition and transmission process is realized, and the coverage comprehensiveness of signal data acquisition is effectively improved.

Moreover, the collecting shell 1 is in the moving process, the rotating motor 11 drives the eccentric block 12 to continuously rotate, so that the lifting plates 13 at the upper end and the lower end can carry out reciprocating lifting motion, the lifting piston rod 16 is driven to carry out vertical drawing motion in the piston cylinder 14, the air pressure in the piston cylinder 14 is changed, the air pressure difference is utilized to drive the transverse moving piston rod 17 to move back and forth, and further, each group of temperature sensing probes 5 and humidity sensing probes 6 can realize reciprocating motion on the collecting shell 1, thereby effectively increasing the signal data collecting range and being beneficial to improving the accuracy of signal data.

As shown in fig. 2 and 5, the driving assembly includes a first motor 20 connected to the top end of the mounting plate 3 and a second motor 21 connected to the bottom end of the mounting plate 3, a first gear 22 and a second gear 23 are respectively disposed on the upper and lower sides in the insertion hole 4, an output shaft of the first motor 20 is connected to the first gear 22, an output shaft of the second motor 21 is connected to the second gear 23, and the first gear 22 and the second gear 23 are respectively engaged with racks on the side walls of the slide rail 2 in a toothed manner.

Specifically, the first motor 20 and the second motor 21 are utilized to drive the first gear 22 and the second gear 23 to rotate respectively, and are meshed with the racks to drive the collecting shell 1 to move, the collecting shell 1 can slide back and forth on the sliding rail 2 by controlling the steering of the first gear 22 and the second gear 23, and the first gear 22 and the second gear 23 are arranged symmetrically up and down, so that the stability of the transmission process can be effectively ensured.

As shown in fig. 6, the piston cylinder 14 is L-shaped, and is integrally formed by a vertical cylinder 141 and a horizontal cylinder 142, the vertical cylinder 141 is fixedly connected with the mounting plate 3 through a connecting block, the lifting piston rod 16 is slidably disposed in the vertical cylinder 141, and the traverse piston cylinder 14 is disposed in the horizontal cylinder 142.

Specifically, the lifting plate 13 can be reciprocally lifted to drive the lifting piston rod 16 to move up and down in the vertical cylinder 141, and the air pressure change in the vertical cylinder 141 is directly fed back into the horizontal cylinder 142 to drive the traverse piston rod 17 to move due to the communication between the vertical cylinder 141 and the horizontal cylinder 142.

Wherein a return spring 19 is provided between the traversing piston rod 17 and the horizontal cylinder 142. The movement of the transverse piston rod 17 in the horizontal cylinder 142 enables the reset spring 19 to be extruded and deformed, the elastic acting force of the reset spring 19 is utilized to facilitate the return and reset of the transverse piston rod 17, and the reciprocating movement process is easier to realize.

As shown in fig. 2, the top end of the cover plate 7 is in running fit with the collecting housing 1 through a rotating shaft 71, a buckle 72 is arranged at the bottom of the cover plate 7, and the bottom end of the cover plate 7 is detachably connected with the collecting housing 1 through the buckle 72.

Specifically, during normal use, the cover plate 7 is closed with the collection shell 1 through the buckle 72, seals the protection to the internal structure part, and when needing maintenance and replacement, release the lock state of buckle 72 can open the cover plate 7, expose the inside structure part of collection shell 1, easy operation, easy dismounting is favorable to maintaining.

As shown in fig. 3, a chute through which the temperature sensing probe 5 and the humidity sensing probe 6 are adapted to pass is provided on the collection housing 1.

Specifically, temperature sensing probe 5 and humidity sensing probe 6 wear out in corresponding spout to temperature signal and humidity signal in the collection environment, temperature sensing probe 5 and humidity sensing probe 6 can slide along the spout simultaneously, thereby carry out spacing direction to reciprocating motion process, guarantee the mobility stability.

As shown in fig. 4, the control main board 9 is electrically connected to the temperature sensing probe 5, the humidity sensing probe 6 and the monitoring probe 8, and the control main board 9 is provided with a control chip 24, a wireless communication module 25, a memory 26 and a socket 27.

Specifically, the temperature sensing probe 5, the humidity sensing probe 6 and the monitoring probe 8 respectively collect temperature signals, humidity signals and image signals, the temperature signals, the humidity signals and the image signals are transmitted to the control main board 9, the memory 26 is used for storage and backup, and meanwhile, the wireless communication module 25 is used for transmitting signal data to a remote signal receiving module, so that a remote collection and transmission process of the signal data is realized.

As shown in fig. 3 and 4, a power module 28 is provided on the rear end face of the collecting housing 1, and a heat insulating protective layer 29 is provided on the inner wall of the sealed housing 10.

Specifically, the power module 28 provides power supply for the driving assembly, the moving assembly, and the control motherboard 9; the heat-insulating protection layer 29 is provided to keep a suitable constant temperature environment in the sealed housing 10, so that the influence of the high temperature or low temperature environment in the transportation carriage on the control main board 9 and the power module 28 can be avoided.

The working principle of the invention is as follows: when the intelligent monitoring system is used, the sliding rail 2 is fixedly arranged in a transportation carriage through connecting ends at two ends, the sliding rail 2 passes through the penetrating opening 4 in the collecting shell 1, the first gear 22 and the second gear 23 are respectively matched with racks on the side wall of the sliding rail 2 in a toothed manner, the first motor 20 and the second motor 21 respectively drive the first gear 22 and the second gear 23 to rotate, so that the collecting shell 1 is driven to slide back and forth on the sliding rail 2, the movable data collecting and transmitting process is realized, the collecting shell 1 is moved, the rotating motor 11 drives the eccentric block 12 to continuously rotate, the lifting plates 13 at the upper end and the lower end can carry out reciprocating lifting motion, the lifting piston rod 16 is driven to carry out up-down pulling motion in the piston cylinder 14, the air pressure in the piston cylinder 14 is changed, the air pressure difference is utilized to drive the traversing piston rod 17 to move back and forth, and further, the temperature sensing probes 5 and the humidity sensing probes 6 of each group can realize reciprocating motion on the collecting shell 1, the signal data collecting range is effectively increased, the accuracy of signal data is favorable, the temperature sensing probes 5, the humidity sensing probes 6 and the monitoring signal 8 are respectively, the temperature sensing probes are monitored by the temperature sensing probes and the monitoring module are controlled by the temperature sensing module, the temperature sensing module and the monitoring signal are controlled by the temperature sensing module, the temperature sensing module and the temperature sensing signals are stored by the temperature sensing module, the temperature sensing signals, and the temperature sensing signals are stored by the temperature sensing signals, and the temperature sensing signals are stored in the temperature sensing module, and the temperature sensing module is stored, and the temperature is a remote signal, and the temperature is a temperature signal, and a temperature is a temperature, and a temperature data, and a temperature is a temperature data, and a temperature data is.

The foregoing describes one embodiment of the present invention in detail, but the description is only a preferred embodiment of the present invention and should not be construed as limiting the scope of the invention. All equivalent changes and modifications within the scope of the present invention are intended to be covered by the present invention.

Claims (6)

1. The utility model provides a multi-functional data acquisition transmission device, its characterized in that, including gathering casing (1) and slide rail (2), the internally connected of gathering casing (1) has mounting panel (3), form between the inner wall of mounting panel (3) and gathering casing (1) and supply socket (4) that slide rail (2) passed, be provided with drive assembly in gathering casing (1), gather casing (1) and slide reciprocally along slide rail (2) through drive assembly, the upper and lower both ends of gathering casing (1) are provided with two sets of data acquisition components respectively, data acquisition component includes temperature sensing probe (5) and humidity sensing probe (6), the inside symmetry of gathering casing (1) is provided with two sets of moving component from top to bottom, every group moving component drives corresponding data acquisition component and reciprocates rectilinear movement on gathering casing (1), the front end face of gathering casing (1) rotates and installs apron (7), be provided with monitor probe (8) on apron (7), the rear end face of gathering casing (1) installs control housing (9), control housing (9) outside cladding is provided with sealed housing (10);

each group of moving components comprises a rotating motor (11), an eccentric block (12), a lifting plate (13) and a piston cylinder (14), wherein the rotating motor (11) is arranged on the outer side of a mounting plate (3), the output end of the rotating motor (11) is connected with the eccentric block (12), the lifting plate (13) is symmetrically arranged at the upper end and the lower end of the eccentric block (12), the lifting plate (13) is always propped against the outer edge of the eccentric block (12) under the action of an extrusion spring (15), two piston cylinders (14) are arranged at the two ends of the lifting plate (13), lifting piston rods (16) and transverse piston rods (17) are arranged in the piston cylinders (14), the lifting piston rods (16) are connected with the lifting plate (13), the transverse piston rods (17) are connected with mounting bases (18), and the temperature sensing probes (5) and the humidity sensing probes (6) are respectively arranged on the corresponding mounting bases (18).

The driving assembly comprises a first motor (20) connected to the top end of the mounting plate (3) and a second motor (21) connected to the bottom end of the mounting plate (3), a first gear (22) and a second gear (23) are respectively arranged on the upper side and the lower side in the penetrating socket (4), an output shaft of the first motor (20) is connected with the first gear (22), an output shaft of the second motor (21) is connected with the second gear (23), and the first gear (22) and the second gear (23) are respectively matched with racks on the side walls of the sliding rail (2) in a toothed manner;

the piston cylinder (14) is in an L-shaped arrangement and is integrally formed by a vertical cylinder (141) and a horizontal cylinder (142), the vertical cylinder (141) is fixedly connected with the mounting plate (3) through a connecting block, the lifting piston rod (16) is slidably arranged in the vertical cylinder (141), and the transverse piston rod (17) is arranged in the horizontal cylinder (142).

2. A multifunctional data acquisition and transmission device according to claim 1, characterized in that a return spring (19) is arranged between the traversing piston rod (17) and the horizontal cylinder (142).

3. The multifunctional data acquisition and transmission device according to claim 1, wherein the top end of the cover plate (7) is in running fit with the acquisition shell (1) through a rotating shaft (71), a buckle (72) is arranged at the bottom of the cover plate (7), and the bottom end of the cover plate (7) is detachably connected with the acquisition shell (1) through the buckle (72).

4. The multifunctional data acquisition and transmission device according to claim 1, wherein the acquisition shell (1) is provided with a chute for the temperature sensing probe (5) and the humidity sensing probe (6) to pass through in an adapting way.

5. The multifunctional data acquisition and transmission device according to claim 1, wherein the control main board (9) is electrically connected with the temperature sensing probe (5), the humidity sensing probe (6) and the monitoring probe (8), and the control main board (9) is provided with a control chip (24), a wireless communication module (25), a memory (26) and a socket (27).

6. The multifunctional data acquisition and transmission device according to claim 5, wherein a power module (28) is arranged on the rear end face of the acquisition housing (1), and a heat insulation protection layer (29) is arranged on the inner wall of the sealing housing (10).