CN211504485U - Automation equipment pressure sensor control line - Google Patents

Abstract

The utility model discloses an automation equipment pressure sensor control line, which comprises a connector, a first cable, a controller, a second cable and a pressure sensor; the outer surface of the first shell is provided with a clamping block, two ends of the second shell are both flat parts, the other end of the first cable is embedded in the corresponding flat part, and the control panel is provided with a sensor; one end of the second cable is embedded in the corresponding flat part; the four edges of the second slot are provided with semi-open-shaped guide positioning blocks. One ends of the first cable and the second cable are respectively embedded into flat parts at two ends of the second shell, so that the first cable and the second cable are stably connected with the controller; the arrangement of the clamping block ensures that the connection between the control line and the display is more stable; the arrangement of the guide positioning block can stably sense pressure, and the sensing sensitivity is improved; and through the setting of control panel and MCU, control panel and MCU optimize sensor signal, ensure the stability of data.

Description

Automation equipment pressure sensor control line

Technical Field

The utility model belongs to the technical field of the wire rod technique and specifically relates to indicate an automation equipment pressure sensor control line.

Background

With the rapid development of the industry, the pressure of the automation equipment is often required to be monitored at any time, so that the safety of the automation equipment is ensured. The pressure sensor control line is connected between the automation device and the display and is used for sensing the pressure of the automation device and transmitting the pressure to the display.

The connection between current pressure sensor control line and automation equipment, display is unstable inadequately to can lead to the response sensitivity to reduce, and traditional pressure sensor control line is on directly passing to the display with the pressure of response, can not optimize sensor signal, thereby lead to data unstability.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model discloses to the disappearance that prior art exists, its main objective provides an automation equipment pressure sensor control line, and it has solved the not stable problem and the pressure sensor control line can not optimize sensor signal of being connected between current pressure sensor control line and automation equipment, the display to lead to the unstable problem of data.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a control line of a pressure sensor of an automation device comprises a connector, a first cable, a controller, a second cable and a pressure sensor; the connector is provided with a first shell, a clamping block fixed with the display is integrally extended out of the outer end of the outer surface of the first shell, and a first slot inserted with the display is concavely arranged on the outer end surface of the first shell; the first cable comprises a first conducting wire and a second conducting wire, and one ends of the first conducting wire and the second conducting wire are in contact conduction with the connector; the controller comprises a second shell and a control panel arranged in the second shell, wherein both ends of the second shell are flat parts, the other end of the first cable is embedded in the corresponding flat part, the other ends of the first wire and the second wire are connected and conducted with the control panel, and a sensor is integrated on the control panel; one end of the second cable is embedded in the corresponding flat part, the second cable comprises a third lead, a fourth lead and a fifth lead, and one ends of the third lead, the fourth lead and the fifth lead are all connected and conducted with the control board; the pressure sensor is connected to the other end of the second cable, the third wire, the fourth wire and the fifth wire are all in contact conduction with the pressure sensor, the pressure sensor is provided with a third shell, a second slot connected with the automation equipment is concavely arranged on the bottom surface of the third shell, and guide positioning blocks in a semi-open shape are arranged on the four peripheries of the second slot.

As a preferred scheme, the outer end of the first shell is cylindrical, and correspondingly, the first slot is circular.

As a preferable scheme, a groove is concavely arranged on the outer wall of the first shell, and the clamping block is positioned in the groove and extends out of the groove.

Preferably, the first conductive line is a power line, and the second conductive line is a signal line.

Preferably, the third wire, the fourth wire and the fifth wire are respectively a ground wire, a power wire and a signal wire.

Preferably, the third housing is made of PBT material for improving sensitivity of the sensing signal.

Preferably, a tensile structure for preventing the displacement of the lead is arranged at the joint of the second cable and the pressure sensor.

Compared with the prior art, the utility model obvious advantage and beneficial effect have, particularly, can know by above-mentioned technical scheme:

one ends of the first cable and the second cable are respectively embedded into flat parts at two ends of the second shell, so that the first cable and the second cable are stably connected with the controller; a clamping block fixed with the display is integrally extended from the outer end of the outer surface of the first shell, and the clamping block is arranged to enable the connection between the control line and the display to be more stable; the four peripheries of the second slot are provided with semi-opening-shaped guide positioning blocks, so that the connection stability of the pressure sensor and the automation equipment is enhanced, the pressure can be stably sensed, and the sensing sensitivity is improved; and through the setting of control panel and MCU, control panel and MCU optimize sensor signal, ensure the stability of data.

To illustrate the structural features and functions of the present invention more clearly, the present invention will be described in detail with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is a schematic structural diagram of a preferred embodiment of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a bottom view of the connector in accordance with the preferred embodiment of the present invention;

fig. 4 is a left side view of the connector in the preferred embodiment of the present invention;

fig. 5 is a bottom view of the pressure sensor in the preferred embodiment of the present invention.

The attached drawings indicate the following:

10. connector 11, first shell

12. Clamping block 101 and first slot

102. Groove 20, first cable

21. First and second conductive lines 22 and 22

30. Controller 31, second housing

311. Flat portion 32 and control panel

33. Sensor 40, second cable

41. Third and fourth conductive lines 42 and 42

43. Fifth conductor 50, pressure sensor

51. Third shell 501, second slot

52. Guide positioning block 60, tensile structure.

Detailed Description

Referring to fig. 1 to 5, a specific structure of a preferred embodiment of the present invention is shown, which includes a connector 10, a first cable 20, a controller 30, a second cable 40 and a pressure sensor 50.

The connector 10 has a first housing 11, a fixture block 12 fixed to the display is integrally extended from an outer end of an outer surface of the first housing 11, a first slot 101 inserted into the display is concavely formed on an outer end surface of the first housing 11, a clamping groove is concavely formed on the display corresponding to the fixture block 12, and the connection between the control line and the display is more stable due to the arrangement of the fixture block 12. In this embodiment, the outer end of the first housing 11 is cylindrical, and correspondingly, the first slot 101 is circular. A groove 102 is concavely formed on the outer wall of the first housing 11, and the latch 12 is located in the groove 102 and extends out of the groove 102.

The first cable 20 includes a first conductive wire 21 and a second conductive wire 22, one end of the first conductive wire 21 and one end of the second conductive wire 22 are in contact with the connector 10, in this embodiment, the first conductive wire 21 is a power line, and the second conductive wire 22 is a signal line.

The controller 30 includes a second housing 31 and a control board 32 disposed in the second housing 31, both ends of the second housing 31 are flat portions 311, the other end of the first cable 20 is embedded in the corresponding flat portion 311, and the flat portions 311 compact the ends of the connected cables, so that the cables are more stably connected to the controller 30. And the other ends of the first wire 21 and the second wire 22 are connected and conducted with the control board 32, the MCU33 is integrated on the control board 32, and the MCU33 is conducted with a signal contact on the control board 32. The traditional sensor control line directly transmits the sensed pressure to the display, the sensor signals cannot be optimized, and now through the arrangement of the control board 32 and the MCU33, the control board 32 and the MCU33 optimize the sensor signals, and the stability of data is ensured.

One end of the second cable 40 is embedded in the corresponding flat part 311, the second cable 40 comprises a third conducting wire 41, a fourth conducting wire 42 and a fifth conducting wire 43, and one ends of the third conducting wire 41, the fourth conducting wire 42 and the fifth conducting wire 43 are all connected and conducted with the control board 32; in the present embodiment, the third conductive line 41, the fourth conductive line 42 and the fifth conductive line 43 are a ground conductive line, a power conductive line and a signal conductive line, respectively.

The pressure sensor 50 is connected to the other end of the second cable 40, the third wire 41, the fourth wire 42 and the fifth wire 43 are all in contact conduction with the pressure sensor 50, the pressure sensor 50 is provided with a third shell 51, a second slot 501 connected with the automation equipment is concavely arranged on the bottom surface of the third shell 51, and guide positioning blocks 52 in a half-open shape are arranged on the four peripheries of the second slot 501, so that the connection stability of the pressure sensor 50 and the automation equipment is enhanced, and pressure can be stably sensed. The third housing 51 is made of PBT for improving the sensitivity of the sensing signal, specifically, the third housing 51 is made of PBT plus 30% glass fiber, and the sensitivity of the sensing signal of the third housing 51 made of the PBT is higher than that of ABS. And a tensile structure 60 for preventing displacement of the wire is provided at the junction of the second cable 40 and the pressure sensor 50.

When the pressure sensor is used, the pressure sensor 50 is plugged into the automatic equipment, and then the connector 10 is plugged into the display, so that the monitoring of the pressure sensor of the automatic equipment is realized.

The utility model discloses a design focus lies in:

one ends of the first cable and the second cable are respectively embedded into flat parts at two ends of the second shell, so that the first cable and the second cable are stably connected with the controller; a clamping block fixed with the display is integrally extended from the outer end of the outer surface of the first shell, and the clamping block is arranged to enable the connection between the control line and the display to be more stable; and the four peripheries of the second slot are provided with semi-open-shaped guide positioning blocks, so that the connection stability of the pressure sensor and the automation equipment is enhanced, pressure can be stably sensed, and the sensing sensitivity is improved.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any slight modifications, equivalent changes and modifications made by the technical spirit of the present invention to the above embodiments are all within the scope of the technical solution of the present invention.

Claims (7)

1. The utility model provides an automation equipment pressure sensor control line which characterized in that: the device comprises a connector, a first cable, a controller, a second cable and a pressure sensor; the connector is provided with a first shell, a clamping block fixed with the display is integrally extended out of the outer end of the outer surface of the first shell, and a first slot inserted with the display is concavely arranged on the outer end surface of the first shell; the first cable comprises a first conducting wire and a second conducting wire, and one ends of the first conducting wire and the second conducting wire are in contact conduction with the connector; the controller comprises a second shell and a control panel arranged in the second shell, wherein both ends of the second shell are flat parts, the other end of the first cable is embedded in the corresponding flat part, the other ends of the first wire and the second wire are connected and conducted with the control panel, and the control panel is integrated with an MCU; one end of the second cable is embedded in the corresponding flat part, the second cable comprises a third lead, a fourth lead and a fifth lead, and one ends of the third lead, the fourth lead and the fifth lead are all connected and conducted with the control board; the pressure sensor is connected to the other end of the second cable, the third wire, the fourth wire and the fifth wire are all in contact conduction with the pressure sensor, the pressure sensor is provided with a third shell, a second slot connected with the automation equipment is concavely arranged on the bottom surface of the third shell, and guide positioning blocks in a semi-open shape are arranged on the four peripheries of the second slot.

2. The automated device pressure sensor control line of claim 1, wherein: the outer end of the first shell is cylindrical and correspondingly, the first slot is circular.

3. The automated device pressure sensor control line of claim 1, wherein: the outer wall of the first shell is concavely provided with a groove, and the clamping block is positioned in the groove and extends out of the groove.

4. The automated device pressure sensor control line of claim 1, wherein: the first conducting wire is a power wire, and the second conducting wire is a signal wire.

5. The automated device pressure sensor control line of claim 1, wherein: the third wire, the fourth wire and the fifth wire are respectively a grounding wire, a power wire and a signal wire.

6. The automated device pressure sensor control line of claim 1, wherein: the third shell is made of PBT materials for improving the sensitivity of the sensing signals.

7. The automated device pressure sensor control line of claim 1, wherein: and a tensile structure for preventing the displacement of the lead is arranged at the joint of the second cable and the pressure sensor.

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