CN220254898U - Self-adaptive signal conversion equipment - Google Patents

Abstract

The utility model provides self-adaptive signal conversion equipment, which comprises a conversion equipment outer shell, wherein Z-shaped raised pieces are respectively embedded in four corners of the bottom of the box body of the conversion equipment outer shell, a rubber inner side layer is arranged on the inner wall of the conversion equipment outer shell, the outer shell of the self-adaptive signal conversion equipment adopts a multiple structure and comprises the Z-shaped raised pieces, the rubber inner side layer, a fiber filling inner layer and a moisture-proof sealing rubber layer, so that the moisture-proof sealing effect is realized, and dust and pollutants are prevented from entering the signal conversion equipment by the dust-proof sealing cover. The fiber-filled inner layer increases the density of the internal structure of the device, and improves the stability of the signal conversion device. The moisture-proof seal rubber layer prevents moisture and humidity from entering the inside of the signal conversion apparatus. Preventing the equipment from being corroded and damaged by moisture, humidity and other liquids during long-term placement. This may lead to problems with the device not functioning properly, or with data loss and transmission errors.

Description

Self-adaptive signal conversion equipment

Technical Field

The utility model relates to the field of signal conversion, in particular to an adaptive signal conversion device.

Background

In the field of electronic devices, signal conversion devices are widely used in various fields as an important signal processing device. However, as it is often required to be applied in humid or rainy environments, the requirements in regard to moisture-tight sealing are also increasing. Existing signal conversion devices are already quite mature in terms of signal conversion.

However, the existing conversion equipment has some defects in the using process, and firstly, the signal conversion equipment has poor dampproof sealing effect in the using process. The device may be subject to attack and damage from moisture, humidity and other liquids during prolonged periods of time. This may result in the device not functioning properly or in data loss and transmission errors. Meanwhile, moisture can rust and corrode circuit boards and electronic components inside the device, and the service life of the device is shortened, so that improvement is made, and an adaptive signal conversion device is provided.

Disclosure of Invention

The utility model aims at: aiming at the problems of the prior art. In order to achieve the above object, the present utility model provides the following technical solutions: the utility model provides a self-adaptation signal conversion equipment, includes the conversion equipment shell body, it has Z type to block up the piece respectively to inlay on the four corners of conversion equipment shell body bottom of the case portion, be provided with the rubber inlayer on the conversion equipment shell body inner wall, power supply area electric installation has the conversion equipment power supply battery on the conversion equipment shell body bottom circuit board, signal converter is installed to one side of conversion equipment power supply battery, and signal converter is located the bottom circuit board.

As a preferable technical scheme of the utility model, the top of the signal converter is connected with a signal input port, and a conductive copper wire is arranged in the signal input port.

As a preferable technical scheme of the utility model, a signal conversion input port, a signal conversion output port and a signal conversion tapping port are respectively and electrically connected in a groove on a circuit board at the bottom of the outer shell of the conversion equipment.

As the preferable technical scheme of the utility model, a dustproof sealing cover is arranged on the hinge shaft on the outer edge of the top of the outer shell of the conversion equipment.

As the preferable technical scheme of the utility model, a fiber filling inner layer is arranged in the dustproof sealing cover, a dampproof sealing rubber layer is covered on the inner wall of the dustproof sealing cover, and an inner frame is inlaid on the inner edge of the dustproof sealing cover.

As the preferable technical scheme of the utility model, the side wall of the inner part of the outer shell of the conversion equipment is embedded with an installation square plate, and the outer plate of the installation square plate is embedded with a linkage rotating shaft.

As the preferable technical scheme of the utility model, the surface of the dustproof sealing cover plate cover is embedded with a movable shaft, a pneumatic cylinder is embedded in a groove of the movable shaft, a telescopic pneumatic rod is arranged in the pneumatic cylinder, a push rod of the telescopic pneumatic rod is connected with the linkage rotating shaft, four corners of the outer part of the shell of the conversion equipment are embedded with mounting fixing buckles, and the surface of the mounting fixing buckles is embedded with fixing holes.

As a preferred solution of the present utility model, the signal conversion circuit includes a signal conversion processor U1, where the signal conversion processor U1 is electrically connected to the first signal conversion receiver M1, the second signal conversion receiver M2, the third signal conversion receiver M3, and the fourth signal conversion receiver M4, the DC source S is electrically connected to the diode D and the first capacitor C1, the third capacitor, and the-IN pin of the DC-DC converter N1, and the diode D is electrically connected to the first capacitor C1, the first signal conversion receiver M1, the DC-DC converter N1, and the third capacitor C3.

As a preferred embodiment of the present utility model, the pin 1 of the signal conversion processor U1 is connected to the pin 1 of the first signal conversion receiver M1, the pin 2 of the signal conversion processor U1 is connected to the pin 1 of the second signal conversion receiver M2, the pin 3 of the signal conversion processor U1 is connected to the pin 1 of the third signal conversion receiver M3, and the pin 4 of the signal conversion processor U1 is connected to the pin 1 of the fourth signal conversion receiver M4.

As a preferable technical scheme of the utility model, the positive pin of the DC source S is connected to the 1 pin of the diode D, and the negative pin of the DC source S is connected to the 2 pin of the first capacitor C1, the 2 pin of the third capacitor C3, and the-IN pin of the DC-DC converter N1.

Compared with the prior art, the utility model has the beneficial effects that:

in the scheme of the utility model: the outer shell of the self-adaptive signal conversion equipment adopts a multiple structure, and comprises a Z-shaped heightening sheet, a rubber inner side layer, a fiber filling inner layer and a dampproof sealing rubber layer, so that the dampproof sealing effect is realized, and dust and pollutants are prevented from entering the signal conversion equipment by the dustproof sealing cover. The fiber-filled inner layer increases the density of the internal structure of the device, and improves the stability of the signal conversion device. The moisture-proof seal rubber layer prevents moisture and humidity from entering the inside of the signal conversion apparatus. Preventing the equipment from being corroded and damaged by moisture, humidity and other liquids during long-term placement. This may lead to problems with the device not functioning properly, or with data loss and transmission errors.

Drawings

FIG. 1 is a schematic diagram of a structure provided by the present utility model;

FIG. 2 is a schematic view of a partial structure provided by the present utility model;

FIG. 3 is a schematic view of the structure of the moisture-proof sealing rubber layer provided by the utility model;

fig. 4 is a schematic diagram of a structure of an outer casing of a conversion device according to the present utility model;

FIG. 5 is a schematic view of an inner frame structure provided by the present utility model;

fig. 6 is a circuit diagram of an inner frame structure provided by the utility model.

The figures indicate:

1. a switching device housing; 2. z-shaped heightening sheets; 3. an inner rubber layer; 4. a switching device power supply battery; 5. a signal converter; 6. a signal input port; 7. a signal conversion input port; 8. a signal conversion output port; 9. a signal conversion tap port; 10. a dustproof sealing cover; 11. filling the inner layer with fibers; 12. a moisture-proof sealing rubber layer; 13. an inner frame; 14. installing a square plate; 15. a linkage rotating shaft; 16. a movable shaft; 17. a pneumatic cylinder; 18. a telescopic pneumatic rod; 19. installing a fixing buckle; 20. and a fixing hole.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model.

Thus, the following detailed description of the embodiments of the utility model is not intended to limit the scope of the utility model, as claimed, but is merely representative of some embodiments of the utility model. All other embodiments obtained by those skilled in the art without making any creative effort based on the embodiments of the present utility model are within the protection scope of the present utility model, and it should be noted that the embodiments of the present utility model and features and technical solutions of the embodiments of the present utility model may be combined with each other without collision: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

Example 1: referring to fig. 1-6, an adaptive signal conversion device includes a conversion device outer shell 1, Z-shaped raised pieces 2 are respectively embedded in four corners of a bottom of the box body of the conversion device outer shell 1, a rubber inner side layer 3 is disposed on an inner wall of the conversion device outer shell 1, a power supply area on a circuit board at the bottom of the conversion device outer shell 1 is electrically provided with a conversion device power supply battery 4, one side of the conversion device power supply battery 4 is provided with a signal converter 5, and the signal converter 5 is located on the circuit board at the bottom. The top of the signal converter 5 is connected with a signal input port 6, and a conductive copper wire is arranged inside the signal input port 6.

The groove on the bottom circuit board of the conversion equipment shell body 1 is electrically connected with a signal conversion input port 7, a signal conversion output port 8 and a signal conversion tapping port 9 respectively. A dustproof sealing cover 10 is arranged on the upper hinge shaft outside the top of the conversion equipment outer shell 1. The inside of the dustproof sealing cover 10 is provided with a fiber filling inner layer 11, the inner wall of the dustproof sealing cover 10 is covered with a dampproof sealing rubber layer 12, and an inner frame 13 is inlaid on the inner edge of the dustproof sealing cover 10. The side wall of the inside of the conversion equipment shell body 1 is embedded with a square installation plate 14, and the outer plate of the square installation plate 14 is embedded with a linkage rotating shaft 15. The movable shaft 16 is embedded on the surface of the plate cover of the dustproof sealing cover 10, the pneumatic cylinder 17 is embedded in a groove of the movable shaft 16, the telescopic pneumatic rod 18 is installed in the pneumatic cylinder 17, and a push rod of the telescopic pneumatic rod 18 is connected with the linkage rotating shaft 15. Mounting fixing buckles 19 are embedded in four corners of the outer casing 1 of the conversion equipment, and fixing holes 20 are embedded in the surfaces of the mounting fixing buckles 19.

The conversion device outer case 1 protects the internal circuits of the signal conversion device from the external environment. The Z-shaped elevating sheet 2 increases the stability of the device, so that the signal conversion device can be better adapted to different installation environments. The rubber inner side layer 3 buffers vibration of an internal circuit of the signal conversion equipment and protects stability of the equipment. The switching device power supply battery 4 provides a stable power supply for the device to ensure that the device is operating properly. The signal converter 5 converts an input signal into a desired output signal. The signal input port 6 receives a signal input that needs to be processed. The signal conversion input port 7 inputs the input signal to the signal converter 5 for conversion. The signal conversion output port 8 outputs the converted signal to a desired device. The signal conversion tap port 9 outputs the converted signals to a plurality of devices, respectively. The dust seal cover 10 prevents dust and contaminants from entering the inside of the signal conversion device. The fiber-filled inner layer 11 increases the density of the internal construction of the device, improving the stability of the signal conversion device. The moisture-proof seal rubber layer 12 prevents moisture and humidity from entering the inside of the signal conversion apparatus. The inner frame 13 supports the internal construction of the signal conversion device, maintaining the shape and overall structure of the device. The mounting square plate 14 facilitates the mounting and securing of the signal conversion device. The linkage rotating shaft 15 transmits the electric quantity information of the battery to the pneumatic cylinder 17 and the telescopic pneumatic rod 18. The movable shaft 16 is matched with the linkage rotating shaft 15 to realize self-adaptive electric quantity adjustment. The pneumatic cylinder 17 controls the length of the telescopic pneumatic rod 18 by a change in pneumatic pressure. The telescopic air pressure rod 18 realizes self-adaptive electric quantity adjustment through the change of the length. The mounting fixing buckle 19 fixes the internal structure of the signal conversion device, and keeps the stability of the structure. The fixing holes 20 are matched with the mounting fixing buckles 19 to realize the mounting and fixing of the signal conversion equipment.

The signal conversion circuit comprises a signal conversion processor U1, the signal conversion processor U1 is electrically connected with the first signal conversion receiver M1, the second signal conversion receiver M2, the third signal conversion receiver M3 and the fourth signal conversion receiver M4, the direct current source S is electrically connected with the diode D, the first capacitor C1, the third capacitor and the-IN pin of the DC-DC converter N1, and the diode D is electrically connected with the first capacitor C1, the first signal conversion receiver M1, the DC-DC converter N1 and the third capacitor C3.

The 1 foot of the signal conversion processor U1 is connected with the 1 foot of the first signal conversion receiver M1, the 2 foot of the signal conversion processor U1 is connected with the 1 foot of the second signal conversion receiver M2, the 3 foot of the signal conversion processor U1 is connected with the 1 foot of the third signal conversion receiver M3, the 4 foot of the signal conversion processor U1 is connected with the 1 foot of the fourth signal conversion receiver M4, the positive pin of the direct current source S is connected with the 1 foot of the diode D, and the negative pin of the direct current source S is connected with the 2 foot of the first capacitor C1, the 2 foot of the third capacitor C3 and the-IN pin of the DC-DC converter N1.

In the using process of the utility model, the working process of the self-adaptive signal conversion equipment is as follows: and (3) signal input: the signal to be processed is connected to the adaptive signal conversion device through the signal input port 6. Signal conversion: the signal converter 5 converts the input signal and outputs the converted signal to the signal conversion output port 8 or the tap port. And (3) signal output: the converted signal may be output through the signal conversion output port 8 or the tap port for subsequent devices to process or transmit. The power supply battery adjusts the electric quantity in a self-adaptive way: the power supply battery of the self-adaptive signal conversion equipment can carry out self-adaptive adjustment on the electric quantity of the battery through the components of the linkage rotating shaft 15, the movable shaft 16, the pneumatic cylinder 17 and the telescopic pneumatic rod 18.

The principle of the adaptive signal conversion device is to convert an input signal and output the converted signal to the signal conversion output port 8 or the tap port. The specific implementation mode is as follows: and (3) dampproof sealing: the outer shell of the self-adaptive signal conversion equipment adopts a multiple structure, and comprises a Z-shaped heightening sheet 2, a rubber inner side layer 3, a fiber filling inner layer 11 and a moistureproof sealing rubber layer 12, so that moistureproof sealing effect is realized, and the equipment is ensured to work normally in a moist or rainy environment. Signal converter 5: the input signal is converted by the signal converter 5 and can be output to the signal conversion output port 8 or the tap port. Self-adaptive electric quantity adjustment: the power supply battery 4 of the conversion equipment adopts a plurality of parts of a linkage rotating shaft 15, a movable shaft 16, a pneumatic cylinder 17 and a telescopic pneumatic rod 18, and can adaptively adjust electric quantity to ensure stable power supply of the equipment. Flexible installation: the inner frame 13, the mounting square plate 14, the mounting fixing buckle 19 and the fixing hole 20 of the self-adaptive signal conversion equipment can be flexibly mounted, and are convenient for users to use.

The above embodiments are only for illustrating the present utility model and not for limiting the technical solutions described in the present utility model, and although the present utility model has been described in detail in the present specification with reference to the above embodiments, the present utility model is not limited to the above specific embodiments, and thus any modifications or substitutions are made thereto; all technical solutions and modifications thereof that do not depart from the spirit and scope of the utility model are intended to be included in the scope of the appended claims.

Claims (10)

1. The utility model provides a self-adaptation signal conversion equipment, includes conversion equipment shell body (1), its characterized in that, Z type backing piece (2) have been inlayed respectively on conversion equipment shell body (1) bottom four corners, be provided with rubber inlayer (3) on conversion equipment shell body (1) inner wall, conversion equipment power supply battery (4) are installed to power supply area electric property on conversion equipment shell body (1) bottom circuit board, signal converter (5) are installed to one side of conversion equipment power supply battery (4), and signal converter (5) are located bottom circuit board.

2. An adaptive signal conversion device according to claim 1, characterized in that the top of the signal converter (5) is connected with a signal input port (6), and that the signal input port (6) is internally provided with conductive copper wires.

3. An adaptive signal conversion device according to claim 2, wherein the signal conversion input port (7) and the signal conversion output port (8) and the signal conversion tap port (9) are electrically connected in a groove on a circuit board at the bottom of the outer casing (1) of the conversion device.

4. An adaptive signal conversion device according to claim 3, characterized in that the upper hinge shaft on the top outer edge of the conversion device outer housing (1) is provided with a dust-proof sealing cover (10).

5. The self-adaptive signal conversion equipment according to claim 4, wherein a fiber filling inner layer (11) is arranged inside the dustproof sealing cover (10), a dampproof sealing rubber layer (12) is covered on the inner wall of the dustproof sealing cover (10), and an inner frame (13) is inlaid on the inner edge of the dustproof sealing cover (10).

6. The self-adaptive signal conversion equipment according to claim 5, wherein an installation square plate (14) is embedded on the inner side wall of the conversion equipment outer shell (1), and a linkage rotating shaft (15) is embedded on the outer plate of the installation Fang Xingban (14).

7. The self-adaptive signal conversion equipment according to claim 6, wherein a movable shaft (16) is embedded on the surface of the plate cover of the dustproof sealing cover (10), a pneumatic cylinder (17) is embedded in a groove of the movable shaft (16), a telescopic pneumatic rod (18) is installed in the pneumatic cylinder (17), a push rod of the telescopic pneumatic rod (18) is mutually connected with the linkage rotating shaft (15), installation fixing buckles (19) are embedded on four corners of the outer shell (1) of the conversion equipment, and fixing holes (20) are embedded on the surface of the installation fixing buckles (19).

8. The adaptive signal converting apparatus according to claim 7, further comprising a signal converting circuit, wherein the signal converting circuit comprises a signal converting processor U1, the signal converting processor U1 is electrically connected to the first signal converting receiver M1 and the second signal converting receiver M2, the third signal converting receiver M3 and the fourth signal converting receiver M4, the DC source S is electrically connected to the diode D and the first capacitor C1, the third capacitor and the-IN pin of the DC-DC converter N1, and the diode D is electrically connected to the first capacitor C1, the first signal converting receiver M1, the DC-DC converter N1 and the third capacitor C3.

9. An adaptive signal converting device according to claim 8, wherein pin 1 of the signal converting processor U1 is connected to pin 1 of the first signal converting receiver M1, pin 2 of the signal converting processor U1 is connected to pin 1 of the second signal converting receiver M2, pin 3 of the signal converting processor U1 is connected to pin 1 of the third signal converting receiver M3, and pin 4 of the signal converting processor U1 is connected to pin 1 of the fourth signal converting receiver M4.

10. An adaptive signal converting device according to claim 9, wherein the positive pin of the DC source S is connected to the 1 pin of the diode D, and the negative pin of the DC source S is connected to ground with the 2 pin of the first capacitor C1, the 2 pin of the third capacitor C3 and the-IN pin of the DC-DC converter N1.