KR20210077819A - Sensing apparatus of turbo charger for vehicle - Google Patents

Abstract

The present invention introduces a sensing apparatus of a turbo charger for a vehicle, in which a sensor for measuring the rotation speed of a compressor wheel is avoided from interference of the compressor wheel and the installation process of the sensor is simplified to reduce manufacturing costs. The sensing apparatus of the present invention includes: a housing provided with a compressor wheel connected to a turbine wheel through a shaft and having an inlet in which air is introduced when the compressor wheel rotates; a magnetic body installed on an end of the compressor wheel and generating a magnetic field; and a sensor mechanism installed on the inlet of the housing, arranged to face the end of the compressor wheel, and sensing changes in the magnetic field of the magnetic body when the compressor wheel rotates to convert the sensing result into electric signals.

Description

Sensing device of turbocharger for vehicle {SENSING APPARATUS OF TURBO CHARGER FOR VEHICLE}

The present invention relates to a sensing device for a turbocharger for a vehicle, and to a sensing device for a turbocharger for a vehicle for measuring a rotation speed of a compressor wheel.

In recent years, with the trend of high output and low fuel consumption, a variable geometric turbo charger (VGT) is being applied to vehicles to improve vehicle performance. This variable shape turbocharger is configured to control the opening position of the vanes provided in the turbine, and the position of the vanes is determined according to the necessary boost pressure according to the driving situation of the vehicle based on air pressure, fuel injection amount, engine speed, etc. through the ECU. do.

In the case of a low-speed region, the variable turbocharger device closes the vanes to maximize the velocity energy of the exhaust gas, thereby increasing the intake air charging efficiency, and in the high-speed region, by opening the vanes to increase the exhaust flow rate. The velocity energy of the exhaust gas is reduced.

On the other hand, when the volume of the exhaust gas of the turbocharger is increased, the maximum allowable speed of the assembly including the turbine, the compressor and the shaft may be exceeded. The assembly of such a turbocharger can break parts when the maximum allowable speed is exceeded, which causes total loss of the turbocharger. Accordingly, it is necessary to measure the rotational speed of the assembly including the turbine, the compressor, and the shaft, but it is difficult to directly measure the rotational speed.

That is, the turbine of the turbocharger has difficulty in measuring the speed of the turbine as it receives the high temperature heat of the exhaust gas, and to measure the rotational speed of the compressor, the sensor must be positioned so as to correspond to the compressor through the housing when installed. . However, in order to measure the rotational speed of the compressor, a process of penetrating the housing to form a screw tab is additionally generated, and if the sensor is installed too deeply, each component may be damaged as it comes into contact with the compressor.

The matters described as the above background art are only for improving the understanding of the background of the present invention, and should not be taken as acknowledging that they correspond to the prior art already known to those of ordinary skill in the art.

KR 10-2009-0057054 A (2009.06.03.)

The present invention has been proposed to solve this problem, and an object of the present invention is to provide a sensing device for a turbocharger for a vehicle in which a sensor for measuring the rotational speed of a compressor wheel is avoided from interference of the compressor wheel, and the installation process is simplified. .

According to an aspect of the present invention, there is provided a sensing device for a turbocharger for a vehicle, comprising: a housing having a turbine wheel and a compressor wheel connected through a shaft, and having an inlet through which air is introduced when the compressor wheel rotates; a magnetic material installed at the end of the compressor wheel and generating a magnetic field; and a sensor mechanism installed at the inlet of the housing and disposed to face the end of the compressor wheel to sense a change in the magnetic field of the magnetic material when the compressor wheel rotates and convert it into an electrical signal.

The sensor mechanism includes: a sensor unit for sensing a change in a magnetic field of a magnetic body; and a support part having one end mounted on the inner circumferential surface of the inlet part and the other end connected to the sensor part so that the sensor part is disposed to face the end part of the compressor wheel.

The sensor unit is composed of a cylindrical case and a sensor provided inside the case, and the case is characterized in that one end is disposed to face the end of the compressor wheel, and the sensor is provided at one end.

It is characterized in that a shock absorbing part made of an elastic material is provided at one end of the case.

The circumferential surface of the case is characterized in that the other end of the support is inserted and seated, and a seating groove extending in one side and the other direction is formed.

The support part is composed of a plurality and is mounted along the inner peripheral surface of the inlet part, and the other end of each support part is connected to the sensor part to fix the position of the sensor part.

The support part is composed of a cylinder part mounted on the sensor part, and a piston part mounted on the inner circumferential surface of the inlet part and drawn in or out from the cylinder part, and thus the length is variable as the piston part enters or exits.

A plurality of insertion holes are formed in the piston portion to be spaced apart along the longitudinal direction, and a fixing portion that penetrates from the outer circumferential surface toward the piston portion and is fastened to the insertion hole is formed in the cylinder portion.

In the sensing device of the turbocharger for a vehicle having the structure as described above, a sensor for measuring the rotational speed of the compressor wheel is avoided from interference of the compressor wheel, and the installation process is simplified, thereby reducing manufacturing cost.

1 is a view showing a sensing device of a turbocharger for a vehicle according to an embodiment of the present invention.
2 to 3 are views for explaining a sensing device of the turbocharger for a vehicle shown in FIG. 1 ;

Hereinafter, a sensing device for a turbocharger for a vehicle according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a diagram illustrating a sensing device for a turbocharger for a vehicle according to an embodiment of the present invention, and FIGS. 2 to 3 are diagrams for explaining the sensing device for a turbocharger for a vehicle shown in FIG. 1 .

As shown in FIGS. 1 to 3, the sensing device for a turbocharger for a vehicle according to the present invention includes a turbine wheel (not shown) and a compressor wheel 12 connected through a shaft 11, and a housing 10 having an inlet 13 through which air is introduced during rotation; a magnetic body 20 installed at the end of the compressor wheel 12 and generating a magnetic field; And installed at the inlet 13 of the housing 10 and disposed to face the end of the compressor wheel 12, when the compressor wheel 12 rotates, the magnetic field change of the magnetic body 20 is sensed and converted into an electrical signal. It includes a sensor mechanism (30).

As described above, according to the present invention, the sensor mechanism 30 is installed inside the housing 10 and the magnetic body 20 is provided at the end of the compressor wheel 12, so that when the compressor wheel 12 rotates, the magnetic body 20 is It is configured to acquire rotation information of the compressor wheel 12 as the sensor mechanism 30 senses a change in the magnetic field and converts it into an electrical signal.

Here, the magnetic body 20 is installed at the end of the compressor wheel 12 and may be composed of a permanent magnet, and a nut or a shaft 11 that allows the compressor wheel 12 and the shaft 11 to be fastened to the compressor wheel ( 12) may be provided at the end of the side.

The sensor mechanism 30 is installed at the inlet 13 of the housing 10 and is disposed to face the end of the compressor wheel 12 . In the case of the sensor mechanism 30 , the change in the magnetic field generated in the magnetic body 20 can be accurately detected by being disposed adjacent to the end of the compressor wheel 12 .

Detailed description of the present invention described above, as can be seen in FIGS. 1 and 2 , the sensor mechanism 30 includes a sensor unit 31 for detecting a change in the magnetic field of the magnetic body 20 ; and a support part 32 having one end mounted on the inner circumferential surface of the inlet part 13 and the other end connected to the sensor part 31 so that the sensor part 31 is disposed to face the end of the compressor wheel 12; may include

In this way, the sensor mechanism 30 is composed of a sensor part 31 and a support part 32 , and in the case of the sensor part 31 , the sensor part 31 is disposed to face the end of the compressor wheel 12 by the support part 32 . The unit 31 may smoothly sense a change in the magnetic field of the magnetic body 20 . That is, the support part 32 has one end mounted on the inner circumferential surface of the inlet part 13 of the housing 10 and fixed and the other end connected to the sensor part 31 , so that the sensor part 31 is connected to the inlet part ( 13) As it may be located in the central portion, it is possible to arrange to face the magnetic body 20 .

In detail, as shown in FIG. 2 , the sensor unit 31 includes a cylindrical case 31a and a sensor 31b provided inside the case 31a, and the case 31a has one end portion. It is disposed to face the end of the compressor wheel 12 and the sensor 31b may be provided at one end.

Here, the sensor 31b may be configured as a Hall sensor or a magnetoresistance sensor to sense the magnetic field of the magnetic body 20 . In addition, the sensor 31b may be electrically connected through a wire W extending through the support 32 .

As the case 31a is formed in a cylindrical shape, the sensor 31b can be built therein, and the air flowing in through the inlet 13 of the housing 10 flows along the cylindrical outer circumferential surface, thereby preventing airflow from being obstructed. is minimized In addition, one end and the other end of the case 31a may be sealed, and a sensor 31b is provided at one end inside and one end is disposed to face the end of the compressor wheel 12. As the sensor 31b may sense the magnetic field of the magnetic body 20 .

In addition, a shock absorbing part 31a-1 made of an elastic material is provided at one end of the case 31a to absorb the shock when the case 31a comes into contact with the end of the compressor wheel 12 . That is, when a large impact is transmitted to the housing 10 , the position of the compressor wheel 12 or the sensor unit 31 may be moved and contact with each other may occur. At this time, when the rotating compressor wheel 12 and the case 31a of the sensor unit 31 come into contact, the sensor 31b inside may be damaged. At one end of the case 31a, a shock absorbing part 31a- 1) is provided to prevent damage to the sensor 31b due to contact with the compressor wheel 12 .

Meanwhile, as shown in FIG. 2 , the other end of the support part 32 is inserted and seated on the circumferential surface of the case 31a, and seating grooves 31a-2 extending in one side and the other direction may be formed. For this reason, the support part 32 may be moved along the extension direction of the seating groove 31a-2, and the sensor part 31 and the compressor according to the position where the support part 32 is moved from the seating groove 31a-2. The distance between the ends of the wheel 12 can be adjusted. Accordingly, the other end of the support part 32 may be formed in a circular shape or a ball may be provided, and a fastening part P for fixing the position of the support part 32 may be provided on the circumferential surface of the case 31a. The fastening part (P) is composed of a fixing pin so that the movement of the support part (32) is limited when it is coupled to the circumferential surface of the case (31a).

On the other hand, as shown in FIG. 3 , the support part 32 is configured in plurality and mounted along the inner peripheral surface of the inlet part 13 , and the other end of each support part 32 is connected to the sensor part 31 and the sensor part The position of (31) can be fixed.

In this way, as the support part 32 is configured in plurality, the position of the sensor part 31 connected to the support part 32 may be firmly maintained. Here, in the case of the support part 32 , three or more may be provided in order to uniformly distribute the load and secure a strong support force, and according to the shape of the inlet part 13 , the sensor part 31 is attached to the end of the compressor wheel 12 . In order to face the , the length of each support portion 32 may be formed differently.

That is, the support part 32 includes a cylinder part 32a mounted on the sensor part 31 and a piston part 32b mounted on the inner circumferential surface of the inlet part 13 and drawn in or out from the cylinder part 32a. , the length may be changed as the piston part 32b is drawn in or out.

In this way, the support portion 32 is composed of a cylinder portion 32a and a piston portion 32b, and as the piston portion 32b is drawn out or retracted from the cylinder portion 32a, the overall length of the support portion 32 is changed. For this reason, the sensor part 31 may be positioned to face the end of the compressor wheel 12 through the length adjustment of the support part 32 . A spring is provided inside the piston part 32b to push the cylinder part 32a so that the cylinder part 32a can be smoothly mounted to the inlet part 13 of the housing 10 .

In addition, when the support part 32 is configured in plurality, the sensor part 31 can be adjusted to 360° by adjusting the length of each cylinder part 32a and the piston part 32b. By accurately positioning the end of the compressor wheel 12 to face it, information according to the rotation of the compressor wheel 12 can be clearly acquired.

Here, the piston part 32b has a plurality of insertion holes 32b-1 spaced apart along the longitudinal direction, and the cylinder part 32a penetrates from the outer circumferential surface toward the piston part 32b to insert an insertion hole 32b-1. ) may be formed with a fixing portion (32a-1) fastened to.

This is for fixing the position of the piston part 32b in the cylinder part 32a, and the fixing part 32a-1 of the cylinder part 32a is any one of the insertion holes 32b-1 of the piston part 32b. When inserted into one, the position of the piston part 32b is fixed. Here, the fixing part (32a-1) is formed to have a hook shape and can be fixed so as not to be separated when inserted into the insertion hole (32b-1), and is made of a screw so as to be screwed into the insertion hole (32b-1). can

For this reason, by inserting the fixing part 32a-1 into the insertion hole 32b-1 after the piston part 32b is withdrawn or retracted from the cylinder part 32a and the length is adjusted, the piston part 32b As the position is fixed, the overall length of the support 32 can be set,

In the sensing device of the turbocharger for a vehicle having the structure as described above, the sensor for measuring the rotational speed of the compressor wheel 12 is avoided from the interference of the compressor wheel 12, and the installation process is simplified, thereby reducing the manufacturing cost.

Although the present invention has been shown and described with reference to specific embodiments, it is within the art that the present invention can be variously improved and changed without departing from the spirit of the present invention provided by the following claims. It will be obvious to one of ordinary skill.

10: housing 11: shaft
12: compressor wheel 13: inlet
20: magnetic material 30: sensor mechanism
31: sensor unit 31a: case
31a-1: shock absorbing part 31a-2: seating groove
31b: sensor 32: support
32a: cylinder part 32a-1: fixed part
32b: piston part 32b-1: insertion hole

Claims (8)

a housing having a turbine wheel and a compressor wheel connected through a shaft, and having an inlet through which air is introduced when the compressor wheel rotates;
a magnetic material installed at the end of the compressor wheel and generating a magnetic field; and
A sensing device for a turbocharger for a vehicle comprising a; a sensor device installed at the inlet of the housing and disposed to face the end of the compressor wheel to detect a change in the magnetic field of a magnetic material when the compressor wheel rotates and convert it into an electrical signal. The method according to claim 1,
The sensor mechanism includes: a sensor unit for sensing a change in a magnetic field of a magnetic body; and
and a support part having one end mounted on the inner circumferential surface of the inlet part and the other end connected to the sensor part so that the sensor part is disposed to face the end part of the compressor wheel. 3. The method according to claim 2,
The sensor unit consists of a cylindrical case and a sensor provided inside the case,
A sensing device for a turbocharger for a vehicle, characterized in that the case is disposed so that one end faces the end of the compressor wheel, and a sensor is provided at one end. 4. The method according to claim 3,
A sensing device for a turbocharger for a vehicle, characterized in that a shock absorbing part made of an elastic material is provided at one end of the case. 4. The method according to claim 3,
A sensing device for a turbocharger for a vehicle, characterized in that the other end of the support is inserted and seated on the circumferential surface of the case, and seating grooves extending in one side and the other direction are formed. 3. The method according to claim 2,
A sensing device for a turbocharger for a vehicle, characterized in that the plurality of supports are mounted along the inner circumference of the inlet, and the other end of each support is connected to the sensor to fix the position of the sensor. 3. The method according to claim 2,
The support part is composed of a cylinder part mounted on the sensor part, and a piston part mounted on the inner circumferential surface of the inlet part and being drawn in or out of the cylinder part, so that the length of the support part is variable as the piston part enters or exits. . 8. The method of claim 7,
A plurality of insertion holes are formed in the piston part to be spaced apart along the longitudinal direction,
A sensing device for a turbocharger for a vehicle, characterized in that the cylinder part has a fixing part formed on the outer peripheral surface toward the piston part and fastened to the insertion hole.

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