KR101526671B1 - Oil Level Detection Device without Oil Fluxation Effectiveness - Google Patents

Abstract

The oil level measuring apparatus of the present invention has a damping cup 40 connected to the sensor housing 10 and the damping cup 40, The oil passage 20 for introducing and discharging the oil is included to realize all the advantages of the ultrasonic sensor 50 which is advantageous for measuring the oil level. In particular, while the oil passage 20 and the oil passage 20 are used, The oil level is always accurately detected without affecting the oil surface dynamics in the oil pan even under static conditions such as a dynamic condition or an engine off state.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oil level measuring apparatus,

The present invention relates to an oil level measuring apparatus and, more particularly, to an oil level measuring apparatus capable of detecting a dynamic oil level which can always detect an accurate oil level without being influenced by the oil level dynamics inside the oil pan, Oil level measuring device.

In general, the main perturbation part of the engine is difficult to avoid damage even if the engine oil shortage is very short in a matter of seconds, and the damage of the main percussion part can not be recovered even after the insufficient engine oil is replenished.

Therefore, the driver manually performs visual inspection by the oil level gauge to prepare for accidents due to lack of engine oil. However, such visual inspection can not be performed periodically, and in particular, it is inevitable to measure during vehicle operation.

On the other hand, when the pressure sensor provided in the oil pan is used and the oil level signal of the detected pressure sensor is transmitted to the driver's instrument panel connected to the electric circuit, the driver can easily recognize the state of the engine oil even during the vehicle operation.

However, in the case of using the pressure sensor, the driver checks the oil warning on the instrument panel of the driver's seat, and if the engine is stopped, the engine damage has already progressed greatly. This is because the oil pressure is about 5 atm The oil pressure is about 0.5 atm or less.

Accordingly, it is inevitable to apply the oil level sensor with high accuracy and reliability of detection information as compared with the pressure sensor.

Korean Patent Publication No. 10-2008-0007326 (2008.01.18)

The patent document shows an example of a technique of eliminating the limitations of the pressure sensor by detecting the oil level using an ultrasonic sensor.

However, the ultrasonic sensor transmits the ultrasonic wave toward the oil surface and uses the return wave to return, and therefore, the dynamics of the oil surface is inevitably large.

Particularly, when an ultrasonic sensor is installed in an oil pan, which is inevitably very dynamically dynamical due to a dynamic condition which is an engine operating state or a static condition which is an engine off state, an ultrasonic sensor is used to detect an ultrasonic wave The accuracy and reliability of the oil level value obtained as a result of such transmission and reception are greatly degraded.

In general, the use of an oil level switch using a MRS (Magnetic Reed Switch) method or a level sensor using a THR (Thermoresistive Heated Wire) method can solve the weak point of the ultrasonic sensor. However, There is a disadvantage in that it is required to change the mounting position for changing the operating characteristic.

In view of the above, the present invention, which has been developed in view of the above, utilizes all the advantages of the ultrasonic wave method which is advantageous for measuring the oil level by using the ultrasonic sensor, and in particular, And an object of the present invention is to provide an oil level measuring apparatus which removes the adverse influence of the oil level inside the oil pan even in static conditions such as a dynamic condition such as a dynamic condition or an engine off state,

In order to accomplish the above object, the present invention provides an oil level measuring apparatus including a sensor housing accommodated in an ultrasonic sensor;

A damping cup formed in a hollow pillar shape so as to fill the oil into the internal space, the damping cup being covered with the internal space by a damping cap;

An oil passage communicating the connection portion between the sensor housing and the damping cup with the inner space of the damping cup so that oil is introduced into and discharged from the inner space of the damping cup; Is included.

Wherein the connection portion between the sensor housing and the damping cup has a shape in which the damping cup is wrapped around the connector boss protruded from the sensor housing and a space formed by the outer circumferential surface of the connector boss and the inner circumferential surface of the damping cup forms the flow path do.

 Wherein the flow path includes a suction hole of the damping cup to communicate the space formed by the outer circumferential surface of the connector boss and the inner circumferential surface of the damping cup, and an inner circumferential surface of the connector boss is formed to communicate the inner space of the damping cup Space.

The flow path is formed along a half section of the outer circumferential surface of the connector boss, and is communicated with the suction hole and the accommodation space, respectively.

The flow path has a semicircular shape along an outer circumferential surface of the connector boss.

Wherein the flow path includes an outsideways communication groove formed in an outer peripheral surface of the connector boss so as to communicate with the suction hole, an inner communication groove formed in an outer peripheral surface of the connector boss so as to communicate with the accommodation space, And a flow connection surface connecting the outside communication groove and the inside communication groove.

Wherein the outer side communication groove has a groove shape that is vertically folded so as not to touch the top surface of the connector boss with the bottom surface of the connector boss as a start position, 15 as a start position, and is formed in a groove shape that is vertically wedged so as not to touch the bottom surface of the connector boss.

The connection portion between the sensor housing and the damping cup is coupled with the male screw of the sensor housing and the female screw of the damping cup.

The sensor housing is provided with a positioner, which prevents misassembly of the damping cup coupled to the sensor housing.

The sensor housing is provided with a counter-milling, and the counter-milling is concentrically centered around a connecting portion between the sensor housing and the damping cup.

The present invention has the effect of applying an oil level sensor to an oil pan in which the advantages of the ultrasonic method are realized by detecting the oil level by the ultrasonic sensor.

Further, according to the present invention, since a flow path for rapidly flowing the oil flowing into and out of the oil level sensor is formed, quick response can be obtained when the oil pan is replenished with oil, The oil level can be accurately detected even when the oil level is generated when the oil level is generated during the braking, the high-speed curve, the start, and the sudden stop.

In addition, the present invention can stably protect a transducer and a circuit unit connected to an ultrasonic sensor by fixing the ultrasonic sensor stably using the inflow and outflow route of the oil, and in particular, the ultrasonic transmission / There is an effect that it is accurately performed without being affected by the influence.

FIG. 1 is a configuration diagram of an oil level measuring apparatus in which a dynamic oil level effect is removed according to the present invention, FIG. 2 is a configuration of a sensor housing applied to the oil level measuring apparatus according to the present invention, FIG. 5 is a sectional view of an oil level measuring apparatus according to an embodiment of the present invention. FIG. 5 is a cross-sectional view of an oil level measuring apparatus according to an embodiment of the present invention. FIG. 6 is a state in which the oil is drained from the damping cup due to a decrease in the oil level in the oil pan, and FIG. 7 is a view showing a state in which the ultrasonic sensor of the oil level measuring apparatus according to the present invention, To detect an oil level.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which illustrate exemplary embodiments of the present invention. The present invention is not limited to these embodiments.

1 shows a configuration of an oil level measuring apparatus in which a dynamic oil level effect is eliminated according to the present embodiment.

As shown in the figure, the oil level measuring apparatus includes a sensor housing 10 mounted on an oil pan, oil for flowing oil from the outside into the sensor housing 10 or discharging the oil from the inside of the sensor housing 10 to the outside A damping cup 40, which is coupled with the sensor housing 10 while enclosing the flow path 20 to discharge the oil into the flow path 20 or filled with the oil introduced into the flow path 20, And an ultrasonic sensor 50 for transmitting and receiving ultrasonic waves to the oil surface of the damping cup 40 and detecting the oil level.

The positioner 30 is further provided in the sensor housing 10 to hold the damping cup 40 in an assembled position so that the damping cup 40 is not misassembled. And is formed in a pin-column shape that protrudes vertically at an off-position.

The oil level measuring apparatus further includes a damping cap 40-1. The damping cap 40-1 is coupled to the damping cup 40 so as to be coupled to the sensor housing 10 Off portion of the damping cup 40 that has not been opened.

The oil level measuring apparatus further includes a base mill 60. A groove 13 is formed in the sensor housing 10 along the circumference of the flow channel 20 to position the base mill 60 .

On the other hand, Fig. 2 shows the configuration of the sensor housing 10. Fig.

As shown in the figure, the sensor housing 10 includes a base 11 having a flat surface and formed with at least one or more holes for fastening, a base 11 having a circular groove, And a connector boss 15 protruding at a predetermined height from the surface of the base 11 concentrically in the space of the groove 13.

In particular, the connector boss 15 has a helical rim formed around the outer circumferential surface thereof so that the damping cup 40 can be coupled in a screw-tight manner. In addition, the helical rim, which surrounds the outer circumferential surface of the channel 20, So that oil flows into the inner space of the connector boss 15 by using the oil passage 20 or flows out of the inner space of the protruding boss 15.

In the present embodiment, the flow path 20 is preferably formed in the half of the connector boss 15, but may be formed to exceed the half section as required.

The receiving space 15-1 is fixed to the connector boss 15 while the ultrasonic sensor 50 is inserted into the receiving space 15-1 and a plurality of stepped bosses and bosses are formed in the receiving space 15-1 The fixed state of the ultrasonic sensor 50 can be stably maintained.

On the other hand, Fig. 3 shows the configuration of the flow path 20.

As shown in the drawing, the oil passage 20 includes an outsideways communication groove 21 for sucking oil into the connector boss 15 or discharging the oil in the accommodation space 15-1 to the outside of the connector boss 15, An inside communicating groove 23 for discharging the oil sucked into the boss 15 to the housing space 15-1 of the connector boss 15 or for discharging the oil in the housing space 15-1, 21) and a flow connection surface (25) for continuing the oil flow following the inside communication groove (23).

The outer side communication groove 21 is formed in a groove shape vertically so as not to touch the top surface of the connector boss 15 with the bottom surface of the connector boss 15 as a start position, The inside communication groove 23 has a groove shape that is vertically wedged so as not to touch the bottom surface of the connector boss 15 with the top surface of the connector boss 15 as a start position.

The outer side communication groove 21 and the inside communication groove 23 are opposed to each other with respect to the center of the connector boss 15.

The flow connection surface 25 is grooved on the outer circumferential surface of the connector boss 15 to connect the inside communicating groove 23 in the outside communicating groove 21 and the oil flowing into the outside communicating groove 21, To the inside communicating groove (23) or to the outside communicating groove (21) through the inside communicating groove (23).

In the present embodiment, the flow connecting surface 25 is formed by using a space between the helix ridges formed on the connector boss 15 so that a separate processing step is not required.

4 shows the configuration of the damping cup 40 and the damping cap 40-1.

As shown in the figure, the damping cup 40 is formed with a hollow hole 40a filled with oil therein, and one of the damping cups 40 forms a connection portion to be screwed with the connector boss 15 of the sensor housing 10 And the opposite side portion forms a cap engagement portion to which the damping cap 40-1 is coupled.

In the present embodiment, the connection portion of the damping cup 40 further includes a suction hole 41, and the suction hole 41 is formed in a groove shape so as to communicate with the inside and outside of the connection portion. The suction hole 41 is coincident with the outsidecontact groove 21, so that the oil can flow into and out of the oil passage 20. [

A positioner position groove 43 is further formed at a position spaced apart from the suction hole 41 in the connecting portion of the damping cup 40. The positioner position groove 43 is formed at a position where the positioner 30 As shown in FIG.

When the damping cup 40 is engaged with the connector boss 15 of the sensor housing 10, the suction hole 41 of the damping cup 40 is positioned in the outflow position of the flow path 20, The operation of assembling the sensor housing 10 and the damping cup 40 can be facilitated.

FIG. 5 shows a state in which the oil is introduced into the damping cup by the oil level measuring device in which the dynamic oil level effect is removed according to the present embodiment.

5 (A) is an assembled state of the oil level measuring apparatus. When the oil level measuring apparatus is assembled, the damping cup 40 having the damping cap 40-1 coupled to the sensor housing 10 is connected to the connector boss 15 An ultrasonic sensor 50 is fixed to the receiving space 15-1 of the connector boss 15 and a transducer and circuitry connected to the ultrasonic sensor 50 are connected to the sensor housing 10, As shown in FIG.

The positioner 30 provided in the sensor housing 10 catches the assembly position of the damping cup 40 so that the suction hole 41 of the damping cup 40 and the flow path 20 of the damping cup 40, The outer side communication grooves 21 may be formed to be coincident with each other.

In this assembled state, the flow path 20 is formed through the joint portion between the damping cup 40 and the connector boss 15. Therefore, when the oil level measuring apparatus is installed in the oil pan, the joint between the sensor housing 10 and the damping cup 40 is contained in the oil filled in the oil pan, so that the oil flows through the oil passage 20 through the damping cup 40 (See FIG.

5 (B) shows a flow in which the oil flows into the hollow hole 40a of the damping cup 40 through the flow path 20.

As shown in the drawing, the oil enters the suction hole 41 and flows into the oil passage 20, and the oil introduced into the oil passage 20 flows into the outside communication groove 21 and flows through the flow connection surface 25 And reaches the inside space (15-1) after reaching the inside communicating groove (23).

Therefore, the hollow hole 40a of the damping cup 40 is filled with oil through the receiving space 15-1, and this process is repeated until the oil level of the damping cup 40 is equal to the oil level in the oil pan .

Particularly, the level of the oil flow filled in the damping cup 40 does not increase abruptly because the flow connecting surface 25 which flows around the outer circumferential surface of the connector boss 15 is included in the oil flow path, And the flow rate is kept constant.

The oil filled in the damping cup 40 does not include air bubbles because the flow path of the oil includes a flow connecting surface 25 that flows around the outer circumferential surface of the connector boss 15, ≪ / RTI >

Meanwhile, FIG. 6 shows a state in which the oil escapes from the damping cup due to the decrease in oil level in the oil pan.

As shown in the figure, the oil flows out through the inside space 15-1 through the inside communicating groove 23 and then reaches the outside communicating groove 21 through the flow connecting surface 25 connected thereto. (41).

Therefore, when the oil level of the damping cup 40 becomes equal to the oil level in the oil pan, the oil level of the oil filled in the hollow hole 40a of the damping cup 40 is lowered as much as the oil level is discharged. .

7 is an operating state in which the ultrasonic sensor of the oil level measuring apparatus according to the present embodiment detects the oil level from the oil level on which the damping cup internal influence in the damping cup is removed.

7 (A), the ultrasonic sensor 50 is accommodated in the connector boss 15 so as to face the damping cup 40 connected to the sensor housing 10, thereby filling the hollow hole 40a of the damping cup 40 The pressure of the oil flow is applied.

Therefore, in the ultrasonic sensor 50, a burst pulse is generated in a transducer due to a piezoelectric effect, and a received wave is received in which a transmitted wave is reflected on the interface between oil and air and returned.

7 (B) shows an example of an echo time difference obtained by the ultrasonic sensor 50 using a transmission wave and a reception wave. From this, an oil level conversion using an echo time difference, which is a general knowledge technique, The oil level with the measured value is provided to the driver's instrument panel in real time.

As described above, the oil level measuring apparatus according to the present embodiment in which the damping cup effect is removed is formed at the connection portion between the sensor housing 10 accommodating the ultrasonic sensor 50 and the damping cup 40, (20) for introducing and discharging oil into and from the internal space of the oil passage (40), thereby realizing all the advantages of the ultrasonic sensor (50) The oil level is always accurately detected without affecting the oil surface dynamics in the oil pan even under the dynamic conditions that are the engine operation state and the static conditions that are the engine off state.

10: sensor housing 11: base
13: groove 15: connector boss
15-1: Capacity space 20: Euro
21: Outside communication groove 23: Inside communication groove
25: Flow connection surface 30: Positioner
40: Damping Cup 40a: hollow hole
41: suction hole 43: positioner position groove
40-1: Damping Cap
50: ultrasonic sensor 60: milling

Claims (11)

A sensor housing in which an ultrasonic sensor is housed;
A damping cup formed in a hollow pillar shape so as to fill the oil into the internal space, the damping cup being covered with the internal space by a damping cap;
And a flow path communicating a connection portion between the sensor housing and the damping cup with the inner space of the damping cup to allow oil to flow in and out of the inner space of the damping cup,
Wherein the sensor housing is provided with a base milling, and the base milling is concentrically centered around a connecting portion between the sensor housing and the damping cup.
The damping cup according to claim 1, wherein a connection portion between the sensor housing and the damping cup is formed by wrapping a connector boss protruding from the sensor housing, the damping cup having a space formed between an outer circumferential surface of the connector boss and an inner circumferential surface of the damping cup Wherein the flow path is formed in the oil passage.
The damping cup according to claim 2, wherein the flow path includes a suction hole of the damping cup so as to communicate a space formed by an outer peripheral surface of the connector boss and an inner peripheral surface of the damping cup, Wherein the oil level measuring device includes a receiving space for forming an inner circumferential surface.
The apparatus of claim 3, wherein the receiving space is provided with the ultrasonic sensor.
4. The oil level measurement apparatus according to claim 3, wherein the flow path is formed along a half section of the outer circumferential surface of the connector boss, and is communicated with the suction hole and the accommodation space, respectively.
The oil level measuring apparatus according to claim 5, wherein the flow path has a semicircular shape along an outer circumferential surface of the connector boss.
The connector according to any one of claims 5 and 6, wherein the flow path includes an outer side communication groove formed in the outer peripheral surface of the connector boss so as to communicate with the suction hole, an inner communication groove formed in the outer peripheral surface of the connector boss to communicate with the accommodation space, And a flow connection surface connecting the outer side communication groove and the inside communication groove along the outer peripheral surface of the connector boss.
The connector according to claim 7, wherein the outer side communication groove has a groove shape that is vertically wedged so as not to touch the top surface of the connector boss with the bottom surface of the connector boss as a starting position, Wherein the groove has a groove shape that is vertically elongated so as not to touch the bottom surface of the connector boss with the top surface of the connector boss as a start position.
The apparatus of claim 1, wherein a connection portion between the sensor housing and the damping cup is coupled with a male screw of the sensor housing and a female screw of the damping cup.
The apparatus of claim 1, wherein the sensor housing is provided with a positioner, and the positioner prevents misassembly of the damping cup coupled to the sensor housing.
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