CN215262218U - Pressure and temperature sensor for oil - Google Patents

Abstract

The utility model relates to the technical field of sensors, in particular to a pressure temperature sensor for oil, which comprises a ceramic pressure module provided with a signal processing chip, wherein the ceramic pressure module is connected with an upper pin, part of the upper pin is connected with a lower pin through a spring, and the lower pin is connected with a thermistor; the thermistor, the lower pins and part of the spring are packaged by an NTC base; the upper pin and part of the spring are sleeved through a connector; the NTC base and the connector can be mutually buckled to form a cavity which can position the ceramic pressure module; part of the NTC base and part of the connector can be sleeved by the shell to form protection. The device has simple and reliable structure and production process, is convenient to assemble, can not influence electronic components, and solves the problems of complex assembly process and high requirement on assembly equipment of the sensor.

Description

Pressure and temperature sensor for oil

Technical Field

The utility model relates to a sensor technical field especially relates to a pressure temperature sensor for fluid.

Background

A pressure sensor is a device or apparatus that can sense a pressure signal and convert the pressure signal into a usable output electrical signal according to a certain rule, and generally comprises a pressure sensitive element and a signal processing unit. According to different test pressure types, the pressure sensors can be divided into gauge pressure sensors, differential pressure sensors, absolute pressure sensors and the like. In the automotive field, in particular, pressure measurement of oil is of great importance. At present, most of the same type sensor technologies on the market need to be welded many times, and the structure is complicated, and requires highly to the assembly process, and the welding point is close to electronic components, causes recessive injury to electronic components easily, owing to often contact with fluid, inside fluid can permeate the sensor after the time of having a specified duration, buries down the potential safety hazard for long-term use in the future.

Therefore, a technique for solving this problem is urgently required.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned prior art's problem, provide a pressure temperature sensor for fluid, only need adopt buckle and rubberizing can realize the rapid Assembly of product, in addition, inner structure adopts elastic contact more, avoids welded connection, not only can not cause stealthy injury to the product, and elastic structure makes the crushing resistance of product stronger moreover, not only does not influence the precision that detects, can effectively improve life moreover.

The above purpose is realized by the following technical scheme:

a pressure and temperature sensor for oil comprises a ceramic pressure module provided with a signal processing chip, wherein the ceramic pressure module is connected with an upper pin, part of the upper pin is connected with a lower pin through a spring, and the lower pin is connected with a thermistor;

the thermistor, the lower pins and part of the spring are packaged by an NTC base;

the upper pin and part of the spring are sleeved through a connector;

the NTC base and the connector can be mutually buckled to form a cavity which can position the ceramic pressure module;

part of the NTC base and part of the connector can be sleeved by the shell to form protection.

Furthermore, the NTC base is T-shaped, the thermistor is arranged in the head end of the NTC base, the tail end of the NTC base is provided with an installation groove capable of installing the pressure module, and the lower pins are arranged in the body of the NTC base; the outer wall of the mounting groove is provided with a spring mounting hole for the end part of the lower pin to penetrate through, the spring is embedded in the spring mounting hole, and the other end of the spring is connected with part of the upper pin, so that the upper pin is elastically connected with the lower pin.

Further, still wrap the NTC support, place in the NTC support the NTC base, and can be right the body of stitch is established and is fixed down.

Furthermore, an oil pressure cavity groove is formed along the bottom side of the mounting groove, and the oil pressure cavity groove can be abutted against the bottom side of the ceramic pressure module to form a closed space capable of storing oil; at least one through hole for oil to pass through is arranged along the bottom side of the oil pressure cavity groove.

Furthermore, a first sealing ring is arranged along the bottom side of the oil pressure cavity groove, and the top of the first sealing ring is abutted to the bottom side of the ceramic pressure module.

Furthermore, the inner cavity of the shell is matched with the NTC base in shape, a channel for oil to flow through can be formed by the inner cavity of the shell and the outer wall of the NTC base, and the channel is communicated with the through hole; and a second sealing ring is arranged between the tail end of the channel and the outer wall of the NTC base.

Furthermore, the upper pin is connected with the ceramic pressure module through an S-shaped spring piece.

Furthermore, a spring needle through groove for a spring needle connected with the ceramic pressure module to penetrate through is further formed in the NTC base, and the spring needle penetrates through the spring needle through groove and then is connected with the shell.

Further, follow the both sides outer wall of NTC base is provided with the buckle of mutual symmetry about, and is corresponding, be provided with on the connector a set of with buckle assorted draw-in groove, the buckle with but the mutual joint of draw-in groove.

Furthermore, the shape of the shell is similar to that of the NTC base, and the shell is sleeved with the NTC base and can be connected with part of the connector through sealant.

Advantageous effects

The pressure temperature sensor for oil provided by the utility model adopts elastic contact at multiple positions in the design structure, thereby avoiding welding connection and effectively avoiding hidden damage to electronic components during welding; in addition, the structure of the device is replaced by simple mechanical assembly, the high-temperature process in the production process is greatly reduced, and the product qualification rate and the product quality durability can be effectively improved. Finally, the device can reduce the input cost of process equipment, reduce the dependence on advanced equipment, improve the one-time qualification rate of products and greatly improve the market competitiveness of the products.

Drawings

Fig. 1 is a perspective view of a pressure and temperature sensor for oil according to the present invention;

fig. 2 is a schematic diagram illustrating the connection between an NTC base and a connector of a pressure and temperature sensor for oil according to the present invention;

fig. 3 is a first perspective cross-sectional view of a pressure and temperature sensor for oil according to the present invention;

fig. 4 is a second perspective cross-sectional view of a pressure and temperature sensor for oil according to the present invention;

fig. 5 is a schematic diagram of an internal structure of a pressure and temperature sensor for oil according to the present invention;

fig. 6 is a schematic structural diagram of an NTC base of a pressure temperature sensor for oil according to the present invention.

Graphic notation:

1-ceramic pressure module, 2-signal processing chip, 3-upper pin, 4-spring, 5-lower pin, 6-thermistor, 7-NTC base, 8-connector, 9-shell, 10-NTC support, 11-channel, 12-second sealing ring, 13-S-shaped spring piece, 14-third sealing ring, 15-sealant, 16-mounting groove, 17-spring mounting hole, 18-oil pressure cavity groove, 19-through hole, 20-first sealing ring, 21-spring needle through groove, 22-spring needle, 23-buckle, 24-guide groove and 25-clamp groove.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. The described embodiments are only some, but not all embodiments of the invention. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1-4, a pressure and temperature sensor for oil, includes a ceramic pressure module 1 mounted with a signal processing chip 2, the ceramic pressure module 1 is connected with an upper pin 3, a part of the upper pin 3 is connected with a lower pin 5 through a spring 4 (i.e. one end of the spring 4 is connected with one end of the upper pin 3, the other end of the spring 4 can be connected with the lower pin 5), the lower pin 5 is connected with a thermistor 6 (i.e. one end of the lower pin 5 is connected with the spring 4, and the other end is connected with the thermistor 6);

the thermistor 6, the lower pin 5 and part of the spring 4 are encapsulated by an NTC base 7;

the upper stitch 3 and part of the spring 4 are sleeved through a connector 8;

the NTC base 7 and the connector 8 can be mutually buckled to form a cavity which can position the ceramic pressure module 1;

part of the NTC base 7 and part of the connector 8 can be sleeved by a shell 9 to form protection.

Example 1

As shown in fig. 4 and 6, as the optimization of the NTC base 7 in the pressure temperature sensor for oil according to the present invention, the NTC base 7 is T-shaped, the thermistor 6 is disposed in the head end of the NTC base 7, the mounting groove 16 for mounting the pressure module 1 is disposed at the end of the NTC base 7, and the lower pin 5 is disposed in the body of the NTC base 7; the outer wall of the mounting groove 16 is provided with a spring mounting hole 17 for the end part of the lower pin 5 to penetrate through, the spring 4 is embedded in the spring mounting hole 17, and the other end of the spring 4 is connected with the upper pin 3, so that the upper pin 3 is elastically connected with the lower pin 5. The upper pin 3 and the ceramic pressure module 1 are connected through an S-shaped spring piece 13 welded on a bonding pad of the ceramic pressure module 1 to form elastic contact. The S-shaped spring piece 13 connects the signal of the ceramic pressure module 1 to the upper pin 3 through elastic contact, welding is avoided, the assembly process can be simplified, and the influence of the assembly process on the performance of products is reduced to the minimum because no welding heat exists.

Specifically, in this embodiment, the NTC base 7 is a solid T-shaped cylinder, the thermistor 6 and the body of the lower pin 5 are both wrapped by the NTC base 7 by injection molding, wherein the lower pins 5 are symmetrically arranged, one end of each of the lower pins is connected to the thermistor 6, the other end of each of the lower pins is exposed in the spring mounting hole 17, and when the spring 4 is inserted into the spring mounting hole 17, the bottom end of the spring 4 is connected to the lower pin 5.

The depth of the spring mounting hole 17 is not less than 1/2 of the length of the spring 4 and not more than the length of the spring 4.

As a further optimization of this embodiment, an NTC support 10 is further included, the NTC support 10 is embedded in the NTC base 7, and the body of the lower pin 5 can be sleeved and fixed.

Specifically, the NTC support 10 may serve as a skeleton of the NTC base 7, may be used to mount the lower pin 5, and may also be beneficial to injection molding of the NTC base 7.

In addition, in this embodiment, the NTC base 7 is made of plastic, and the thermistor 6 is completely coated by a secondary injection molding process, so that the thermistor 6 cannot be penetrated by oil even if the NTC base is soaked in oil with pressure, the temperature of the oil can be sensed in real time, and the oil can be prevented from penetrating into the sensor.

Example 2

As shown in FIG. 4, the utility model discloses an optimization that is arranged in the pressure temperature sensor of fluid oil pressure to detect the passageway. An oil pressure cavity groove 18 is formed along the bottom side of the mounting groove 16, and the oil pressure cavity groove 18 can be abutted against the bottom side of the ceramic pressure module 1 to form a closed space capable of storing oil; at least one through hole 19 for oil to pass through is formed along the bottom side of the oil pressure cavity groove 18.

Preferably, a first sealing ring 20 is arranged along the bottom side of the oil pressure cavity groove 18, and the top of the first sealing ring 20 abuts against the bottom side of the ceramic pressure module 1. The structure can ensure that the oil pressure entering the oil pressure cavity groove 18 is always concentrated on the bottom side of the ceramic pressure module 1, can effectively prevent oil from overflowing outwards, and is favorable for detecting the oil pressure of the ceramic pressure module 1.

The inner cavity of the shell 9 is matched with the shape of the NTC base 7, a channel 11 for oil to flow is formed by the inner cavity and the outer wall of the NTC base 7, and the channel 11 is communicated with the through hole 19;

in order to prevent oil from continuously overflowing along the gap between the housing 9 and the outer wall of the NTC base 7, a second sealing ring 12 is provided between the end of the channel 11 and the outer wall of the NTC base 7.

Example 3

As shown in fig. 2 and 6, the NTC base 7 is further provided with a pogo pin through slot 21 for allowing a pogo pin 22 connected with the ceramic pressure module 1 to pass through, and the pogo pin 22 passes through the pogo pin through slot 21 to be connected with the housing 9 (since the housing 9 is finally connected with the NTC base, the contact of the pogo pin 22 with the pogo pin 22 is equivalent to the final connection with the housing 9).

Specifically, the spring pin 22 can realize the electricity connection of ceramic pressure module 1 and shell 9 to the realization is with the good ground connection of car frame ground, prevents EMC interference in the work in the future, avoids because the various incident that EMC caused, improves product reliability greatly.

Example 4

As shown in fig. 1-3, as the utility model discloses an optimization of the connection mode of NTC base 7, connector 8 and shell 9 in a pressure temperature sensor for fluid follows the both sides outer wall of NTC base 7 is provided with left and right mutual symmetry's buckle 23, and is corresponding, be provided with on the connector 8 a set of with buckle 23 assorted draw-in groove 25, buckle 23 with draw-in groove 25 can joint each other.

As the optimization of this structure, follow NTC base 7's both sides outer wall is provided with the mutually symmetrical guiding groove 24 of left and right sides, buckle 23 set up in guiding groove 24's axle center position, guiding groove 24 can lead draw-in groove 25 extremely fast buckle 23's position realizes buckle 23 and draw-in groove 25's quick joint.

The shape of the shell 9 is similar to that of the NTC base 7, and the shell 9 is partially sleeved with the NTC base 7 and is connected with the outer wall of the connector 8 through a sealant 15 to realize fixation after being partially sleeved with the connector 8; a third gasket 14 for sealing a tank or the like is provided on the outer wall of the head of the housing 9.

The above description is only for the purpose of illustrating embodiments of the present invention and should not be taken as limiting the invention, and any modifications, equivalents, improvements and the like made by those skilled in the art within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. A pressure and temperature sensor for oil is characterized by comprising a ceramic pressure module provided with a signal processing chip, wherein the ceramic pressure module is connected with an upper pin, part of the upper pin is connected with a lower pin through a spring, and the lower pin is connected with a thermistor;

the thermistor, the lower pins and part of the spring are packaged by an NTC base;

the upper pin and part of the spring are sleeved through a connector;

the NTC base and the connector can be mutually buckled to form a cavity which can position the ceramic pressure module;

part of the NTC base and part of the connector can be sleeved by the shell to form protection.

2. The pressure and temperature sensor for oil according to claim 1, wherein the NTC base is T-shaped, the thermistor is disposed in a head end of the NTC base, a mounting groove for mounting the pressure module is formed in a tail end of the NTC base, and the lower pin is disposed in a body of the NTC base; the outer wall of the mounting groove is provided with a spring mounting hole for the end part of the lower pin to penetrate through, the spring is embedded in the spring mounting hole, and the other end of the spring is connected with part of the upper pin, so that the upper pin is elastically connected with the lower pin.

3. The pressure and temperature sensor for oil according to claim 2, further comprising an NTC bracket, wherein the NTC bracket is embedded in the NTC base and can cover and fix the lower pin body.

4. The pressure and temperature sensor for oil according to claim 2, wherein an oil pressure cavity is formed along the bottom side of the mounting groove, and the oil pressure cavity can be abutted against the bottom side of the ceramic pressure module to form a closed space for storing oil; at least one through hole for oil to pass through is arranged along the bottom side of the oil pressure cavity groove.

5. The pressure and temperature sensor for oil of claim 4, wherein a first seal ring is disposed along a bottom side of said oil pressure cavity groove, a top portion of said first seal ring abutting a bottom side of said ceramic pressure die set.

6. The pressure/temperature sensor for oil of claim 4, wherein the inner cavity of the housing matches with the shape of the NTC base, and forms a passage for oil to flow with the outer wall of the NTC base, the passage communicating with the through hole; and a second sealing ring is arranged between the tail end of the channel and the outer wall of the NTC base.

7. The pressure and temperature sensor for oil of claim 1, wherein the upper pin is connected to the ceramic pressure die set by an S-shaped spring plate.

8. The pressure and temperature sensor for oil according to claim 1, wherein the NTC base further has a pogo pin through slot for allowing a pogo pin connected to the ceramic pressure module to pass therethrough, and the pogo pin passes through the pogo pin through slot to be connected to the housing.

9. The pressure and temperature sensor for oil according to claim 1, wherein the NTC base is provided with left and right symmetrical buckles along outer walls of two sides thereof, and the connector is correspondingly provided with a set of clamping grooves matched with the buckles, and the buckles and the clamping grooves can be mutually clamped.

10. The pressure and temperature sensor for oil of claim 1, wherein said housing has a shape similar to said NTC base, and said housing is configured to fit over said NTC base and to be connected to an outer wall of said connector by a sealant after a portion of said connector.

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