CN221099906U - Antidetonation temperature sensor structure - Google Patents

Abstract

The utility model discloses an anti-vibration temperature sensor structure which comprises a sensor main body and a connecting box arranged at the right side of the sensor main body, wherein a mounting block is arranged at the lower side of the sensor main body, a probe is arranged at the lower side of the mounting block, the sensor main body is powered by being connected with an external power supply, an anti-vibration main board is arranged at the outer position of the lower side of the mounting block, a mounting cavity is arranged at the connecting position of the mounting block and the anti-vibration main board, the sensor main body is fixed on the anti-vibration main body, the probe is protected by a probe tube, the influence of external impact and vibration on the sensor main body can be reduced, the service life of the sensor is prolonged, vibration waves between the sensor main body and a measured object can be transmitted to a lower plane by using a buffer rod, a pressure rod, a rubber head and other components, and therefore the vibration impact of the sensor main body is relieved, and a better anti-vibration effect is provided.

Description

Antidetonation temperature sensor structure

Technical Field

The utility model belongs to the technical field of sensors, and particularly relates to an anti-seismic temperature sensor structure.

Background

The temperature sensor is a device for measuring the temperature of an environment or object.

The principle of operation of a temperature sensor is based on the relationship between the temperature of a substance and its electrical characteristics.

The temperature sensor has a wide application range and can be used for monitoring and controlling the temperature of various devices and systems. For example, they can be used to monitor temperature changes in industrial processes, and the accuracy and reliability of temperature sensors is critical for many applications, so they are often calibrated and verified to ensure the accuracy of their measurements.

However, the existing temperature sensor lacks an anti-seismic structure, when the temperature sensor is installed in a region with frequent vibration of a wave frequency to perform detection operation, the operation accuracy of the temperature sensor is reduced along with long-term use, operators are required to be frequently arranged to perform maintenance and calibration, and redundant manpower is consumed.

Disclosure of utility model

The utility model aims to provide an anti-vibration temperature sensor structure, which solves the problems that the existing temperature sensor provided in the background art lacks an anti-vibration structure, and when the temperature sensor is installed in a region with frequent vibration of a wave number to carry out detection operation, the operation accuracy of the temperature sensor is reduced along with long-term use, and operators are required to be frequently arranged to carry out maintenance and calibration, so that extra labor is consumed.

In order to achieve the above purpose, the present utility model provides the following technical solutions: an anti-vibration temperature sensor structure comprises a sensor main body and a connecting box arranged at the right side of the sensor main body;

A mounting block is arranged at the lower side of the sensor main body, and a probe is arranged at the lower side of the mounting block;

the sensor main body is powered by being connected with an external power supply;

An anti-seismic main board is arranged at the outer position of the lower side of the mounting block, a mounting cavity is arranged at the connecting position of the mounting block and the anti-seismic main board, a connector is arranged at the lower right side of the anti-seismic main board, and a probe tube is arranged at the lower side of the connector;

A rear plate is arranged at the left side position of the anti-seismic main plate, a pressing plate is arranged at the right upper side position of the anti-seismic main plate, a pressing rod is arranged at the right inner position of the pressing plate, and a buffer rod is arranged at the left middle inner position of the rear plate;

rubber heads are respectively arranged at the tail end positions of the lower sides of the pressing rods and the buffer rods.

Preferably, the pressing plate and the rear plate are connected with the anti-seismic main plate through an integrated connection mode respectively, and the pressing rod and the buffer rod are connected with the pressing plate and the rear plate through a threaded connection mode respectively.

Preferably, the pressing rod and the buffer rod can move up and down on the inner sides of the pressing plate and the rear plate in a threaded connection mode respectively, and the rubber head is connected with the pressing rod and the buffer rod in a bolt connection mode respectively.

Preferably, the rubber head at the tail end of the lower side of the pressure rod is tightly contacted with the upper side of the sensor main body, and the length of the buffer rod is far longer than that of the pressure rod.

Preferably, the mounting block is connected with the sensor main body in a threaded connection mode, and the probe is connected with the probe tube in a nested connection mode.

Preferably, the connector is connected with the anti-seismic main board in an integrated connection mode, and the probe tube is connected with the connector in a threaded connection mode.

Compared with the prior art, the utility model provides an anti-seismic temperature sensor structure, which has the following beneficial effects:

In this antidetonation temperature sensor structure, can play the benefit through antidetonation mainboard, back plate, clamp plate, depression bar, buffer rod and rubber head isotructure's setting:

Protecting the sensor body: the sensor main body is fixed on the anti-seismic main body, and the probe is protected by the probe tube, so that the influence of external impact and vibration on the sensor main body can be reduced, and the service life of the sensor is prolonged.

Providing a cushioning anti-shock effect: through using the subassembly such as buffer rod, depression bar and rubber head, can transmit the shock wave between sensor main part and the measured object to the below plane on to alleviate the shock impact that the sensor main part received, provide better buffering antidetonation effect.

Maintaining the operation precision: by reducing the influence of external interference and vibration, the installation and anti-vibration design can improve the operation precision of the sensor and ensure the accuracy and reliability of the measurement result.

Stability and reliability: by fixing the sensor body and using anti-vibration measures, a more stable and reliable sensor performance can be provided, errors and drift are reduced, and the reliability of the sensor is improved.

Is suitable for various environments: such a design may adapt the sensor to various environments, including vibration, or other conditions that may cause the sensor to be unstable.

In general, such mounting and anti-vibration designs can provide protection, cushioning, and stability, helping to improve the performance and reliability of the sensor, thereby making the sensor more efficient and reliable in applications that measure vibration or vibration, etc.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic structural view of a sensor body according to the present utility model.

Fig. 3 is a schematic view of an anti-seismic motherboard structure in the present utility model.

FIG. 4 is a schematic view showing the structure of the pressing rod and the buffer rod after moving downward in the present utility model.

In the figure: 1. a sensor body; 2. a connection box; 3. a mounting block; 4. a probe; 5. a mounting cavity; 6. an anti-vibration main board; 7. a connector; 8. a probe tube; 9. a rear plate; 10. a pressing plate; 11. a compression bar; 12. a buffer rod; 13. a rubber head.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model provides an anti-vibration temperature sensor structure as shown in figures 1-4, which comprises a sensor main body 1 and a connecting box 2 arranged at the right side of the sensor main body 1;

A mounting block 3 is arranged at the lower side position of the sensor main body 1, and a probe 4 is arranged at the lower side position of the mounting block 3;

the sensor body 1 is powered by being connected to an external power source;

The outer position of the lower side of the installation block 3 is provided with an anti-seismic main board 6, the connection position of the installation block 3 and the anti-seismic main board 6 is provided with an installation cavity 5, the lower right side of the anti-seismic main board 6 is provided with a connector 7, and the lower side of the connector 7 is provided with a probe tube 8;

A rear plate 9 is arranged at the left side position of the anti-seismic main plate 6, a pressing plate 10 is arranged at the right upper side position of the anti-seismic main plate 6, a pressing rod 11 is arranged at the right inner position of the pressing plate 10, and a buffer rod 12 is arranged at the left middle inner position of the rear plate 9;

Rubber heads 13 are provided at the lower end positions of the pressing rod 11 and the buffer rod 12, respectively.

In the present embodiment, the sensor body 1 determines the temperature by measuring the change in the resistance value according to the characteristic that the resistance value changes with the temperature.

The step of using the temperature sensor body 1 generally includes the following:

and (3) installing a sensor: the sensor body 1 is mounted at a position where the temperature needs to be measured, and the probe 4 of the sensor body 1 is ensured to be in good contact with the object to be measured.

The connection circuit: the signal line of the sensor body 1 is connected to a signal conversion circuit or a data acquisition device through a connection box 2.

Calibrating the sensor: the sensor body 1 is calibrated to ensure accuracy of the measurement results.

Reading temperature: the temperature signal output from the sensor body 1 is read by a signal conversion circuit or a data acquisition device.

Processing data: the read temperature signal is processed, and operations such as conversion of temperature units, filtering and correction of data can be performed.

As shown in fig. 1 to 4, the pressing plate 10 and the rear plate 9 are respectively connected with the anti-vibration main plate 6 through an integrated connection mode, the pressing rod 11 and the buffer rod 12 are respectively connected with the pressing plate 10 and the rear plate 9 through a threaded connection mode, the pressing rod 11 and the buffer rod 12 can respectively move up and down on the inner sides of the pressing plate 10 and the rear plate 9 through a threaded connection mode, the rubber head 13 is respectively connected with the pressing rod 11 and the buffer rod 12 through a bolt connection mode, the rubber head 13 at the tail end of the lower side of the pressing rod 11 is tightly contacted with the upper side of the sensor main body 1, the length of the buffer rod 12 is far longer than that of the pressing rod 11, the mounting block 3 is connected with the sensor main body 1 through a threaded connection mode, the probe 4 is connected with the probe tube 8 through a sleeved connection mode, the connector 7 is connected with the anti-vibration main plate 6 through an integrated connection mode, and the probe tube 8 is connected with the connector 7 through a threaded connection mode.

Preferably, in this sensor body 1, when the operator is installing, can insert the probe 4 of the sensor body 1 into the probe tube 8 and protrude to contact the measured object, insert the installation block 3 into the installation cavity 5, fix the sensor body 1 on the shock-resistant body 6, the probe tube 8 plays the role of protecting the probe 4 at this time, afterwards, fix the shock-resistant main board 6 in a certain position on the back plate 9 by using bolts or other connection structures, and keep the contact between the probe 4 and the measured object before and after fixing, the operator can twist the buffer rod 12 in the back plate after the fixing operation is finished, keep the rubber head 13 at the lower end of the buffer rod 12 to contact the plane, twist the compression rod 11 in the compression plate 10, keep the rubber head 13 at the lower end of the compression rod to contact the upper surface of the sensor body 2, after the shock wave is transmitted to the sensor body 1, the sensor body 1 can transmit the shock wave to the rubber head 13, perform the first buffering operation, and rely on the compression plate 10, the shock-resistant body 6, the back plate 9 transmits the force to the lower end of the buffer rod 12 to the lower end of the buffer rod through the lower end of the buffer rod 13, the shock-resistant body is better in order to keep the accuracy of the vibration-resistant body, and the accuracy is better to be transmitted to the main body.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present utility model, and although the present utility model has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present utility model.

Claims (6)

1. An anti-vibration temperature sensor structure comprises a sensor main body (1) and a connecting box (2) arranged at the right side of the sensor main body (1);

A mounting block (3) is arranged at the lower side position of the sensor main body (1), and a probe (4) is arranged at the lower side position of the mounting block (3);

the sensor main body (1) is powered by being connected with an external power supply;

The method is characterized in that: an anti-seismic main board (6) is arranged at the outer position of the lower side of the installation block (3), an installation cavity (5) is arranged at the connecting position of the installation block (3) and the anti-seismic main board (6), a connector (7) is arranged at the right lower side of the anti-seismic main board (6), and a probe tube (8) is arranged at the lower side of the connector (7);

A rear plate (9) is arranged at the left side position of the anti-seismic main plate (6), a pressing plate (10) is arranged at the right upper side position of the anti-seismic main plate (6), a pressing rod (11) is arranged at the right inner position of the pressing plate (10), and a buffer rod (12) is arranged at the left middle inner position of the rear plate (9);

Rubber heads (13) are respectively arranged at the tail end positions of the lower sides of the pressing rod (11) and the buffer rod (12).

2. An anti-shock temperature sensor structure according to claim 1, characterized in that: the pressing plate (10) and the rear plate (9) are connected with the anti-seismic main plate (6) in an integrated connection mode respectively, and the pressing rod (11) and the buffer rod (12) are connected with the pressing plate (10) and the rear plate (9) in a threaded connection mode respectively.

3. An anti-shock temperature sensor structure according to claim 2, characterized in that: the compression bar (11) and the buffer bar (12) can respectively move up and down on the inner sides of the compression plate (10) and the rear plate (9) in a threaded connection mode, and the rubber head (13) is respectively connected with the compression bar (11) and the buffer bar (12) in a bolt connection mode.

4. A shock resistant temperature sensor structure according to claim 3, wherein: the rubber head (13) at the tail end of the lower side of the pressing rod (11) is tightly contacted with the upper side of the sensor main body (1), and the length of the buffer rod (12) is far longer than that of the pressing rod (11).

5. An anti-shock temperature sensor structure according to claim 1, characterized in that: the mounting block (3) is connected with the sensor main body (1) in a threaded connection mode, and the probe (4) is connected with the probe tube (8) in a sleeved connection mode.

6. An anti-shock temperature sensor structure according to claim 1, characterized in that: the connector (7) is connected with the anti-seismic main board (6) in an integrated connection mode, and the probe tube (8) is connected with the connector (7) in a threaded connection mode.