CN213602640U - Remote control data debugger - Google Patents

Abstract

The utility model discloses a remote control data debugger, which comprises a shell, wherein a data debugging device and a mainboard are arranged in the shell, and the data debugging device and the mainboard are both fixedly arranged in the shell; the mainboard is internally provided with a signal receiving module, a signal conversion module, a signal transmitting module, a storage module and an MCU; a mounting seat is arranged behind the shell, the mounting seat is fixedly mounted behind the shell, a signal antenna capable of receiving and sending signals is fixedly mounted on the mounting seat, and the signal antenna is connected with the main board through a data line; lie in data debugging device and mainboard in the casing on symmetry parallel arrangement have two air pipe, air pipe's tip link up around the casing both ends fixed mounting on the lateral wall at both ends around the casing, the inside air pipe's that sets up of casing bottom butt is installed in data debugging device and mainboard top, is convenient for lead out data debugging device and mainboard through air pipe because of the temperature that work produced.

Description

Remote control data debugger

Technical Field

The utility model relates to a data debugger specifically is a remote control data debugger.

Background

A data debugger refers to an instrument that can condition stray data information into a regular data stream. The data debugger in the prior art does not have a remote control function, but in practical application, a large amount of data debugged by the data debugger needs to be remotely controlled and transmitted, for example, the data debugging in a high-risk environment needs to be remotely controlled, but the data debugger in the prior art adopts an external signal transmitting device to achieve the functions of remotely controlling and transmitting data, so that the operation is troublesome, and a connected data interface has a risk of falling off; in addition, a large amount of heat is generated when the data debugger performs remote control and data debugging, and the data debugger needing to work frequently has high internal temperature due to long-time work and signal exchange; under the condition, if the heat dissipation is not carried out in time, the data debugger can burn out important electronic components in the internal circuit when working in a high-temperature environment for a long time, so that the whole data debugger is scrapped and damaged, and certain economic loss is caused.

Therefore, the inventor provides a remote control data debugger by combining various factors.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a remote control data debugger to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

a remote control data debugger comprises a shell, wherein a data debugging device and a mainboard are arranged in the shell, and the data debugging device and the mainboard are fixedly installed in the shell; the mainboard is internally provided with a signal receiving module, a signal conversion module, a signal transmitting module, a storage module and an MCU; a mounting seat is arranged behind the shell, the mounting seat is fixedly mounted behind the shell, a signal antenna capable of receiving and sending signals is fixedly mounted on the mounting seat, and the signal antenna is connected with the main board through a data line; lie in data debugging device and mainboard in the casing on symmetry parallel arrangement have two air pipe, air pipe's tip link up around the casing both ends fixed mounting on the lateral wall at both ends around the casing, the inside air pipe's that sets up of casing bottom butt is installed in data debugging device and mainboard top, is convenient for lead out data debugging device and mainboard through air pipe because of the temperature that work produced.

When in work: when the data debugger starts to work, the mainboard arranged in the shell of the data debugger can receive a remote working instruction through the signal antenna, and can convert data debugged by the data debugging device into an electric signal and send the electric signal through the signal antenna, so that the functions of remote data exchange and remote control of the data debugger are realized; at data debugging during operation, its inside mainboard and data debugging device can produce a large amount of heats at the during operation, install the air pipe in mainboard top through the butt, with the mainboard in the leading-in air pipe of a large amount of heats of during operation, because both ends around the casing are link up at the air pipe both ends, will make cold wind pass from air pipe both ends circulation like this, derive the heat in the air pipe, thereby reduce the temperature in the air pipe, and then reduce the operating temperature of mainboard and data debugging device, can effectively protect the inside electronic components of mainboard and data debugging device.

As a further aspect of the present invention: both ends are located the outside fixed mounting of casing around the air pipe and have a collection wind mouth that leaks hopper-shaped, are convenient for collect cold wind and make cold wind pass the air pipe from one end collection wind mouth in, wear out from other end collection wind mouth again, conveniently derive the high temperature in the air pipe, make its temperature reduce.

As a further aspect of the present invention: a plurality of bent intercommunicating pipelines are arranged between the data debugging device and the two symmetrically arranged ventilating pipelines above the main board, and the ventilating pipelines are communicated with each other through the intercommunicating pipelines, so that the ventilating pipelines are communicated with each other, and the heat conducting performance of the ventilating pipelines is improved.

As a further aspect of the present invention: the ventilating pipeline and the intercommunicating pipeline are in a flat strip shape, so that the contact area between the ventilating pipeline and the main board is increased, and the heat conducting property of the ventilating pipeline and the intercommunicating pipeline is improved; the ventilating pipeline and the intercommunicating pipeline are both made of metal copper pipe materials with good heat conducting performance, and the heat conducting performance of the ventilating pipeline and the intercommunicating pipeline is further improved conveniently.

As a further aspect of the present invention: the heat-conducting silicone grease which is uniformly smeared and has good heat-conducting property is arranged between the data debugging device and the upper part of the main board and between the ventilating pipeline and the intercommunicating pipeline, has good heat-conducting, temperature-resistant and insulating properties, is an ideal medium material for heat-resistant devices, has stable performance, can not generate corrosive gas in use, can not influence the contacted material, and is convenient for heat conduction.

As a further aspect of the present invention: the signal receiving module, the signal conversion module, the signal transmitting module and the storage module are all connected with the MCU through circuits, so that data information debugged by the data debugging device can be stored conveniently by using the storage module, a remote instruction signal is received through the signal receiving module to remotely control the data debugger, the data debugged by the data debugging device is converted into an electric signal through the signal conversion module, and the electric signal is transmitted through the signal transmitting module, so that signal receiving and data transmitting are realized.

Compared with the prior art, the utility model discloses the beneficial effect of following several aspects has:

1. the utility model provides a remote control data debugger, the structure sets up ingenious and arrange rationally, the utility model discloses the mainboard that sets up in the well data debugging casing can receive long-range work instruction through signal antenna, can also be transformed into the signal of telecommunication with the data conversion that the debugging of data debugging device was accomplished and send away through signal antenna, has realized the function of remote data exchange and remote control data debugger.

2. The utility model discloses the data debugging ware during operation of further design, its inside mainboard and data debugging device can produce a large amount of heats at the during operation, install the air pipe in the mainboard top through the butt, with the mainboard in the leading-in air pipe of a large amount of heats of during operation production, because air pipe both ends link up both ends around the casing, will make cold wind pass from air pipe both ends circulation like this, derive the heat in the air pipe, thereby reduce the temperature in the air pipe, and then reduce the operating temperature of mainboard, can effectively protect mainboard and the inside electronic components of data debugging device.

3. The utility model discloses the data information storage of further design's storage module with the debugging of data debugging device gets up, receives remote instruction signal with remote control data debugger through signal reception module, and the signal conversion module converts the data conversion of data debugging device debugging to the signal of telecommunication, and rethread signal emission module sends away the signal of telecommunication, has realized the sending of signal reception and data.

Drawings

Fig. 1 is a schematic structural diagram of a remote control data debugger.

Fig. 2 is a sectional view of a remote control data debugger.

FIG. 3 is a circuit system control block diagram of a remote control data debugger.

In the figure: 1. a housing; 2. a ventilation duct; 3. a mounting seat; 4. a signal antenna; 5. a main board; 6. an intercommunicating conduit; 7. an air collecting opening; 8. a data debugging device; 9. a signal receiving module; 10. a signal conversion module; 11. a signal transmitting module; 12. a storage module; 13. and (6) an MCU.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Referring to fig. 1-3, a remote control data debugger includes a housing 1, a data debugging device 8 and a motherboard 5 are disposed in the housing 1, and the data debugging device 8 and the motherboard 5 are both fixedly mounted in the housing 1; a signal receiving module 9, a signal conversion module 10, a signal transmitting module 11, a storage module 12 and an MCU13 are arranged in the mainboard 5; a mounting seat 3 is arranged behind the shell 1, the mounting seat 3 is fixedly mounted behind the shell 1, a signal antenna 4 capable of receiving and sending signals is fixedly mounted on the mounting seat 3, and the signal antenna 4 is connected with a main board 5 through a data line; two ventilation pipelines 2 are symmetrically arranged in parallel on the data debugging device 8 and the main board 5 in the shell 1, the end parts of the ventilation pipelines 2 penetrate through the front end and the rear end of the shell 1 and are fixedly arranged on the side walls of the front end and the rear end of the shell 1, the bottom of the ventilation pipeline 2 arranged in the shell 1 is abutted and arranged above the data debugging device 8 and the main board 5, and the temperature generated by the data debugging device 8 and the main board 5 due to work can be conveniently led out through the ventilation pipelines 2; the front end and the rear end of the ventilation pipeline 2 are positioned outside the shell 1 and fixedly provided with funnel-shaped air collecting ports 7, so that cold air can be conveniently collected to enable the cold air to pass through the ventilation pipeline 2 from the air collecting port 7 at one end and then pass out from the air collecting port 7 at the other end, and high temperature in the ventilation pipeline 2 can be conveniently led out, so that the temperature of the ventilation pipeline is reduced; a plurality of bent intercommunicating pipelines 6 are arranged between the two symmetrically arranged ventilating pipelines 2 above the data debugging device 8 and the main board 5, and the ventilating pipelines 2 are communicated together by the intercommunicating pipelines 6, so that the ventilating pipelines 2 and the intercommunicating pipelines 6 are communicated with each other, and the heat conductivity of the ventilating pipelines is improved; the ventilating duct 2 and the intercommunicating duct 6 are in a flat strip shape, so that the contact area between the ventilating duct 2 and the main board 5 is increased, and the heat conducting performance of the ventilating duct is improved; the ventilating pipeline 2 and the intercommunicating pipeline 6 are both made of metal copper pipe materials with good heat conductivity, so that the heat conductivity of the ventilating pipeline is further improved; heat-conducting silicone grease which is uniformly coated and has good heat-conducting property is arranged between the upper parts of the data debugging device 8 and the main board 5 and between the ventilating duct 2 and the intercommunicating duct 6, the silicone grease has good heat-conducting, temperature-resistant and insulating properties, is an ideal medium material for heat-resistant devices, has stable performance, cannot generate corrosive gas in use, cannot influence the contacted materials, and is convenient for heat conduction; the signal receiving module 9, the signal conversion module 10, the signal transmitting module 11 and the storage module 12 are all connected with the MCU13 through circuits, so that the data information debugged by the data debugging device 8 is stored by the storage module 12, the signal receiving module 9 receives a remote instruction signal to remotely control the data debugger, the signal conversion module 10 converts the data debugged by the data debugging device 8 into an electrical signal, and then the signal transmitting module 11 transmits the electrical signal, thereby realizing signal receiving and data transmitting.

The utility model discloses a theory of operation is: when the data debugger starts to work, a mainboard 5 arranged in the data debugger shell 1 can receive a remote work instruction through the signal antenna 4, and can convert data debugged by the data debugging device 8 into an electric signal and send the electric signal out through the signal antenna 4, so that the functions of remote data exchange and remote control of the data debugger are realized; when the data debugger works, the mainboard 5 and the data debugging device 8 inside the mainboard can generate a large amount of heat when working, the ventilating duct 2 and the intercommunication pipeline 6 above the mainboard 5 are installed through the butt, the mainboard 5 is led into the ventilating duct 2 and the intercommunication pipeline 6 by generating a large amount of heat when working, because the two ends of the ventilating duct 2 penetrate through the front end and the rear end of the shell 1, so that cold air can pass through the inner circulation of the ventilating duct 2 and the intercommunication pipeline 6, the heat in the ventilating duct 2 and the intercommunication pipeline 6 is led out, the temperature in the ventilating duct 2 and the intercommunication pipeline 6 is reduced, the working temperature of the mainboard 5 and the data debugging device 8 is reduced, and the electronic components inside the mainboard 5 and the data debugging device 8 can be effectively.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

Although the preferred embodiments of the present patent have been described in detail, the present patent is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present patent within the knowledge of those skilled in the art.

Claims (6)

1. A remote control data debugger comprises a shell (1), wherein a data debugging device (8) and a main board (5) are arranged in the shell (1), and the data debugging device (8) and the main board (5) are fixedly installed in the shell (1); the intelligent monitoring system is characterized in that a signal receiving module (9), a signal conversion module (10), a signal transmitting module (11), a storage module (12) and an MCU (13) are arranged in the mainboard (5); a mounting seat (3) is arranged behind the shell (1), the mounting seat (3) is fixedly mounted behind the shell (1), a signal antenna (4) capable of receiving and sending signals is fixedly mounted on the mounting seat (3), and the signal antenna (4) is connected with the main board (5) through a data line; lie in casing (1) data debugging device (8) and mainboard (5) on symmetrical parallel arrangement have two air pipe (2), both ends fixed mounting is on the lateral wall at both ends around casing (1) around the tip of air pipe (2) link up casing (1), the bottom butt of the inside air pipe (2) that sets up of casing (1) is installed in data debugging device (8) and mainboard (5) top.

2. The remote control data debugger according to claim 1, wherein funnel-shaped air collection ports (7) are fixedly mounted at the front end and the rear end of the ventilation pipeline (2) and located outside the shell (1), so that cold air can be collected conveniently and made to pass through the ventilation pipeline (2) from the air collection port (7) at one end and then pass out from the air collection port (7) at the other end.

3. The remote control data debugger according to claim 2, wherein a plurality of curved intercommunicating ducts (6) are arranged between two symmetrically arranged ventilating ducts (2) above the data debugging device (8) and the main board (5), and the intercommunicating ducts (6) connect the ventilating ducts (2) together in a penetrating manner.

4. A remote control data debugger according to claim 3, wherein the ventilation duct (2) and the intercommunication duct (6) are in the shape of a flat strip; the ventilation pipeline (2) and the intercommunicating pipeline (6) are both made of metal copper pipe materials with good heat conductivity.

5. The remote control data debugger according to claim 4, wherein a heat-conducting silicone grease with uniform heat-conducting property is applied between the upper part of the data debugging device (8) and the main board (5) and between the upper part of the ventilation duct (2) and the intercommunication duct (6).

6. The remote control data debugger according to any of claims 1-5, wherein the signal receiving module (9), the signal converting module (10), the signal transmitting module (11) and the storage module (12) are all connected with the MCU (13) through a circuit.

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