KR102046526B1 - Pressure sensor - Google Patents

Abstract

The present invention relates to a pressure sensor. In the pressure sensor of the present invention, the housing body 12 includes a housing body 12 having an internal space 12 ′ formed therein and a housing cover 14 that shields the internal space 12 ′. One side of the housing body 12 is formed with a connector portion 20 to which the mating connector is coupled. The other side of the housing body 12 is formed with a tube connection portion 22 to which the tube is coupled. A pressure passage 24 is formed to pass through the tube connection part 22 and communicate with the internal space 12 ′. The sensing element 30 is installed at a portion where the pressure passage 24 communicates with the internal space 12 ′ with a gasket 32 interposed therebetween. The sensing element 30 is mounted in the inner space 12 ′ of the housing body 12 in a state where it is mounted on the substrate 30. A plurality of atmospheric pressure passages 40 are formed through the portion where the gasket 32 is positioned to communicate the internal space 12 ′ and the pressure passage 24. One end portion of the atmospheric pressure passage 40 faces the upper portion of the gravity direction and the other end portion thereof faces the lower portion of the gravity direction, and the atmospheric pressure passage 40 is formed to be bent in an 'S' shape. According to the present invention, no moisture or foreign matter remains in the atmospheric pressure passage 40, and moisture or foreign matter in the atmospheric pressure passage 40 is discharged to the outside of the atmospheric pressure passage 40 by gravity.

Description

Pressure sensor

The present invention relates to a pressure sensor, and more particularly to a pressure sensor having a flow path for preventing the flow path for introducing atmospheric pressure to be blocked.

Recently, various sensors have been used in automobiles to detect the situation around the vehicle. For example, there is a pressure sensor that detects a shock applied to an automobile as a change in pressure and provides data to take necessary actions. In other words, in order to obtain a signal for pedestrian protection, a pressure sensor is installed in the vehicle, and a pressure change is detected to create an operation to protect the pedestrian.

The pressure sensor performing the above operation obtains the necessary signal by detecting the pressure difference from the atmospheric pressure. To this end, in order to balance the pressure of the fluid to be detected with the atmospheric pressure, there is an atmospheric pressure flow path which guides the atmospheric pressure from the outside of the pressure sensor toward the sensing element inside the pressure sensor.

This atmospheric pressure flow path is formed to extend to the sensing element. The atmospheric pressure flow path is formed through a section of the gasket to prevent leakage when the fluid for detecting the pressure change is transferred toward the sensing element. When moisture forms in the atmospheric pressure flow path, the atmospheric pressure flow path is blocked and the atmospheric pressure is blocked. There is a problem that cannot be guided toward the sensing element.

Republic of Korea Patent Publication No. 10-2005-9681

An object of the present invention is to solve the conventional problems as described above, to prevent the atmospheric pressure flow path that induces atmospheric pressure into the interior of the pressure sensor is blocked.

Another object of the present invention is to have a plurality of atmospheric pressure passages for inducing atmospheric pressure into the pressure sensor so that the induction of atmospheric pressure into the pressure sensor is desired.

According to a feature of the present invention for achieving the above object, the present invention is a housing formed with an atmospheric pressure guide hole for communicating between the outside and the inner space and a pressure flow path communicating with the inner space, installed in the inner space And a sensing element for measuring the pressure in the pressure passage, a gasket installed between the bottom surface of the housing and the sensing element to prevent pressure leakage between the pressure passage and the sensing element, and the pressure passage and the inside. It is formed so as to communicate between the space to induce the atmospheric pressure of the internal space into the pressure passage, when the housing is installed in the fixed portion, the atmospheric pressure passage extending to continue to be lowered in the direction of gravity while going from one end to the other end Include.

The atmospheric pressure flow path is formed to be bent in an 'S' shape.

A plurality of atmospheric flow paths are formed.

One end of the atmospheric pressure passage communicates with the inner space and the other end communicates with the pressure passage, and is formed on at least one side of the inner space bottom of the housing or the gasket.

The pressure passage is formed to penetrate the inside of the tube connecting portion formed to protrude from the housing.

The housing includes a housing body in which the inner space is formed and a housing cover mounted to the housing body to shield the inner space.

In the pressure sensor according to the present invention, the following effects can be obtained.

In the present invention, since the atmospheric pressure passage for transferring the atmospheric pressure toward the sensing element extends along the direction of gravity, foreign matters containing moisture do not stay inside the passage, so that the passage is prevented from being blocked by moisture or foreign matter. The operation reliability of the sensor is increased.

In addition, in the present invention, since a plurality of atmospheric pressure passages for transmitting atmospheric pressure toward the sensing element are formed, even if one of the atmospheric pressure passages is blocked by moisture or foreign matter, the atmospheric pressure can be delivered to the sensing element family through the other atmospheric pressure passage. There is an effect that the operation of the pressure sensor can be made accurately.

1 is a perspective view showing the configuration of a preferred embodiment of a pressure sensor according to the present invention.
Figure 2 is a perspective view showing the configuration of the housing body constituting the embodiment shown in FIG.
3 is a cross-sectional view showing a main part configuration of the embodiment shown in FIG.
4 is a partially enlarged perspective view showing an important configuration of the embodiment shown in FIG.
Figure 5 is a perspective view showing another arrangement of the atmospheric pressure flow path in the present invention.

Hereinafter, preferred embodiments of the pressure sensor according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in the figures, the housing 10 forms the appearance of the pressure sensor of the embodiment of the present invention. The housing 10 is an insulating material, preferably made of a synthetic resin material. The housing 10 is composed of a housing body 12 and a housing cover 14 in this embodiment. The housing body 12 is made of a substantially hexahedral shape and has an internal space 12 'formed therein. The housing cover 14 is mounted on the housing body 12 to shield the internal space 12 ′ from the outside. The housing cover 14 is made in a plate shape. The housing cover 14 may be coupled to the housing body 12 by ultrasonic welding. In this embodiment, the housing 10 is composed of the housing body 12 and the housing cover 14, but may be made in other forms.

On the outer surface of the housing body 12, the mounting piece 16 is formed to protrude. The mounting piece 16 is for mounting the housing 10 to the fixed portion. A mounting hole 18 penetrates through the mounting piece 16.

One side surface of the housing body 12 is formed to protrude a connector 20. The connector unit 20 is for connecting a power sensor and a signal to the outside of the pressure sensor. An insertion space 20 'is formed inside the connector 20 so as to be opened to the front, and a mating connector (not shown) is inserted into and inserted into the insertion space 20'. One end of the terminal 21 is provided inside the connector 20.

The other side of the housing body 12 is provided with a tube connecting portion 22 protrudes. The pressure passage 24 through which the pressure fluid flows is formed in the tube connection part 22. The pressure passage 24 communicates with the inner space 12 ′ of the housing body 12.

On the other hand, an atmospheric pressure guide hole 26 for inducing atmospheric pressure into the inner space 12 'by communicating with the inner space 12' is perforated through the housing body 12. The atmospheric pressure outside the pressure sensor is induced to the internal space 12 ′ through the atmospheric pressure induction hole 26.

The substrate support 28 is formed in the internal space 12 ′. The substrate support 28 allows the substrate 30 described below to be seated at a predetermined height in the inner space 12 ′. A plurality of substrate support 28 is formed in the inner space 12 ′.

The substrate 30 is seated on the substrate support 28. One end of the terminal 21 provided in the connector 20 is inserted into the board 30. The substrate 30 is also provided with components for the operation of the pressure sensor. The sensing element 32 is mounted on one side of the substrate 30. The sensing element 32 is to sense the pressure substantially. The sensing element 32 measures the pressure of the fluid transferred through the pressure passage 24 in a state in which the sensing element 32 is mounted on the substrate 30.

A gasket 34 is installed between the sensing element 32 and the pressure passage 24 to allow the pressure of the fluid transferred through the pressure passage 24 to be transmitted without leakage to the sensing element 32. . The gasket 34 has a through hole 36 in the center thereof. The through hole 36 serves to communicate between the pressure passage 24 and the sensing element 32. The through hole 36 is formed through the gasket 34.

The gasket 34 is in close contact with a portion of the inner surface of the housing body 12 corresponding to the inlet edge of the pressure passage 24 and the sensing element 32. Sidewalls 38 are formed to allow the gasket 34 to be firmly fixed to the inner space 12 ′ of the housing body 12. The side wall 38 is formed to be in close contact with the outer surface of the gasket 34. In the present embodiment, the gasket 34 has a substantially flat hexahedral shape, and accordingly, the side wall 38 also has a quadrangular shape when viewed in plan view. Of course, the side wall 38 is not entirely rectangular, and some sections are open. That is, in the present embodiment, the edge portion of the gasket 34 is all surrounded by the side wall 38, and the side wall 38 is not formed in some sections at portions corresponding to the four sides of the gasket 34.

On the other hand, in the area partitioned by the side wall 38, an atmospheric pressure passage 40 is formed to communicate the internal space 12 'and the pressure passage 24 to transfer the atmospheric pressure to the pressure passage 24. . The atmospheric pressure passage 40 communicates with the pressure passage 24 starting from an open area of the side wall 38, as shown in FIGS. 2 and 4. Of course, the atmospheric pressure passage 40 is formed in the form of a channel so as to be opened at the bottom of the inner space 12 ′. In the state in which the pressure sensor is assembled, most of the atmospheric pressure passage 40 is shielded by the gasket 34 so that the passage is not a channel form. Becomes In the state in which the gasket 34 is installed, the open area of the side wall 38 is opened in communication with the internal space 12 ′ and the opposite side is in communication with the pressure passage 24.

The pressure passage 24 is formed to be continuously lowered in the direction of gravity along its extension direction. To this end, in the present embodiment, the pressure passage 24 has a substantially 'S' shape. The pressure passage 24 extends in the direction of gravity. That is, the pressure passage 24 in the upper portion relative to FIG. 4 has one end portion in the area in which the side wall 38 is open, and the upper portion in the gravity direction, and the other end side in communication with the pressure passage 24. This is the lower gravity direction.

In addition, the atmospheric pressure passage 40 has the upper side in the direction of gravity in communication with the pressure passage 24 and the lower side in the direction of gravity on the opposite side. Of course, the extension of the atmospheric pressure passage 40 in the direction of gravity depends on how the housing 10 is installed, but the pressure sensor of the present invention is mounted so that the atmospheric pressure passage 40 is disposed as described above. Should be.

As described above, the atmospheric pressure passage 40 is formed to extend in the direction of gravity so that moisture or foreign matter may escape from the atmospheric pressure passage 40 due to the action of gravity when moisture is formed in the atmospheric pressure passage 40 or when there is foreign matter. To do this.

In FIG. 4, two atmospheric pressure passages 40 are formed. This is to ensure that even if one atmospheric pressure passage 40 is blocked, the rest can play its role. At least two atmospheric passages 40 may be formed.

In addition, the atmospheric pressure passage 40 may be formed to have various arrangements. As an example, FIG. 5 shows that the atmospheric pressure passage 40 is disposed symmetrically with respect to the pressure passage 24. In addition, a total of four atmospheric pressure passages 40 may be formed in pairs at the upper and lower sides with respect to the pressure passage 24.

Hereinafter, the pressure sensor according to the present invention having the configuration as described above will be used in detail.

The pressure sensor of the present invention is installed in a bumper or the like of the vehicle to detect an impact applied from the outside. The pressure sensor of the present invention detects an impact as follows. That is, the two pressure sensors are connected to each other by a tube (not shown), and the fluid inside the tube flows by the impact applied to the tube to measure the pressure change. The measured pressure change value is transmitted to the control unit of the vehicle through the substrate 30 and through the mating connector coupled to the connector unit 20.

In this case, the pressure sensor is disposed such that the mounting pieces 16 protruding from both side surfaces of the housing body 12 face the gravity upward direction and the gravity downward direction, respectively. As such, when the housing body 12 is mounted, both ends of the atmospheric pressure passage 40 are disposed to face the gravity upward direction and the gravity downward direction, respectively, as shown in the figure.

In this arrangement, moisture or foreign matter generated in the atmospheric pressure passage 40 is released from the atmospheric pressure passage 40 by the action of gravity. Therefore, the atmospheric pressure passage 40 is prevented from being blocked, and the atmospheric pressure outside the pressure sensor is introduced into the pressure passage 24 through the atmospheric pressure passage 40.

In general, when the atmospheric pressure is introduced into the pressure passage 24 through the atmospheric pressure passage 40, when the shock is applied to the tube and the fluid in the tube is transferred to the pressure passage 24, The sensing element 32 measures the change in pressure. When the change value of the measured pressure in this way exceeds a predetermined value, the controller of the vehicle issues a necessary command. For example, if the detected change in pressure value is greater than or equal to a predetermined value, the controller may command the airbag to operate.

When the impact is eliminated, the fluid that has been delivered to the pressure passage 24 is transferred to the tube again, and the atmospheric pressure outside the housing body 12 is introduced into the inner space 12 ′ of the housing body 12. It is introduced through the atmospheric pressure induction hole 26 and is transferred to the pressure passage 24 through the atmospheric pressure passage 40.

The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self evident.

For example, the atmospheric pressure passage 40 is formed on the bottom of the housing body 12 in the illustrated embodiment, but is not necessarily so. The atmospheric pressure passage 40 may be formed in the gasket 34 or may be divided into the gasket 34 and the housing body 12.

10: housing 12: housing body
12 ': internal space 14: housing cover
16: mounting piece 18: mounting holes
20: connector portion 20 '; Insertion space
21: terminal 22: tube connection
24: pressure passage 26: atmospheric pressure induction
28: substrate support 30: substrate
32: sensing element 34: gasket
36: through-hole 38: side wall
40: atmospheric pressure flow path

Claims (6)

A housing 10 having an atmospheric pressure induction hole 26 for communicating between the outside and the inner space 12 ', and a pressure passage 24 for communicating with the inner space 12';
A sensing element 32 installed in the inner space 12 'and measuring the pressure of the pressure passage 24;
A gasket (34) installed between the bottom surface of the housing (10) and the sensing element (32) to prevent pressure leakage between the pressure passage (24) and the sensing element (32);
It is formed to communicate between the pressure passage 24 and the internal space 12 'to induce atmospheric pressure of the internal space 12' to the pressure passage 24, the housing 10 is fixed to the When installed, the pressure sensor comprising an atmospheric pressure flow passage (40) extending to continue to be lowered in the direction of gravity while going from one end to the other end.
The pressure sensor according to claim 1, wherein the atmospheric pressure passage (40) is formed to be bent in an 'S' shape.
The pressure sensor according to claim 1, wherein a plurality of atmospheric pressure passages (40) are formed.
The housing of any one of claims 1 to 3, wherein one end of the atmospheric pressure passage 40 is in communication with the internal space 12 'and the other end is in communication with the pressure passage 24. Pressure sensor formed on at least one side of the bottom surface of the inner space (12 ') of the (10) or the gasket (34).
The pressure sensor according to claim 4, wherein the pressure passage (24) is formed to penetrate the inside of the tube connection portion (22) which protrudes from the housing (10).
The housing cover of claim 5, wherein the housing 10 is mounted to the housing body 12 and the housing body 12 in which the inner space 12 ′ is formed, and shields the inner space 12 ′. A pressure sensor comprising 14).

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