KR20190067412A - Automotive room temperature sensor - Google Patents

Abstract

The present invention relates to an indoor temperature sensor for a vehicle comprising: a thermoelectric element having specified specific thickness and area, and used as a base; an indoor temperature sensor disposed in close contact with an upper part of the thermoelectric element; a solar sensing sensor disposed on an upper side within a specific distance specified on one side of the indoor temperature sensor; a housing surrounding all of the thermoelectric element, the indoor temperature sensor, and the solar sensing sensor; a printed circuit board for connecting each lead of the thermoelectric element, the indoor temperature sensor, and the solar sensing sensor to a wiring according to a specified circuit configuration using a pattern; and a terminal part extending so as to connect the wiring pattern connected to each lead of the printed circuit board to an external device. Therefore, an objective of the present invention is to provide the indoor temperature sensor for the vehicle capable of improving the accuracy of the indoor temperature sensor for the vehicle and to reduce a calculation load of an air conditioning controller.

Description

[0001] AUTOMOTIVE ROOM TEMPERATURE SENSOR [0002]

The present invention relates to a vehicle interior temperature sensor, and more particularly, to a vehicle interior temperature sensor capable of overcoming the influence of disturbance caused by the solar radiation of a vehicle by hardware using a thermoelectric element, And to reduce the calculation load of the air conditioner controller.

Generally, the vehicle air conditioner operates according to the environmental conditions inside and outside the vehicle and the control conditions by the user to control the indoor environment of the vehicle. However, since the environment inside and outside the vehicle is constantly changing, an air conditioner controller (not shown) is provided to automatically adjust the temperature of the room according to changes in the environment and control conditions.

That is, the air conditioner of a vehicle typically has a configuration in which the air conditioner controller controls the air conditioner based on a signal input of various temperature sensors and a set temperature set by the user. Accordingly, the air conditioner controller controls the air conditioner by setting a predetermined target temperature in accordance with environmental conditions such as outside temperature, inside temperature, and solar radiation, and control conditions such as set temperature.

At this time, the various temperature sensors include a room temperature sensor and a solar radiation sensor. The room temperature sensor is disposed in a room of a vehicle to detect a room temperature, and the solar radiation sensor affects the heat of the housing of the room temperature sensor It detects the amount of solar radiation. The compensated temperature sensor is located inside the panel of the air conditioner and thermally separated from the room temperature sensor to sense the temperature of the air inside the air conditioner panel which affects the sensed value of the room temperature sensor.

Typically, the room temperature sensor, the compensation temperature sensor, and the solar radiation sensor are assembled in one component type (i.e., a sensor assembly).

In other words, when the solar radiation is reflected on the sensor sensor, the temperature of the housing surrounding the indoor temperature sensor rises and senses higher than the actual indoor temperature of the vehicle. In order to reduce the error between the actual vehicle room temperature and the sensor temperature sensor, a solar radiation sensor is installed.

The air conditioner controller corrects the sensed value of the room temperature sensor using the solar radiation value sensed by the solar radiation sensor. That is, it is necessary that the air conditioning controller receives the solar radiation amount from the solar radiation sensor and corrects the indoor temperature based on the input solar radiation amount.

However, such a room temperature correction operation causes a load on the calculation time of the air conditioner controller, and if the room temperature compensation logic is not optimized, the room temperature sensing performance deteriorates.

BACKGROUND ART [0002] The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 10-2011-0062232 (published on Jun. 10, 2011, an air conditioner for an electric vehicle and a control method thereof).

According to an aspect of the present invention, there is provided a vehicle interior temperature sensor, which is created to solve the above-described problems, and is capable of overcoming the influence of disturbance caused by the solar radiation of a vehicle by hardware using a thermoelectric element And an object of the present invention is to provide an indoor temperature sensor for a vehicle which can improve the accuracy of the indoor temperature sensor for a vehicle and reduce the calculation load of the air conditioner controller.

An indoor temperature sensor for a vehicle according to one aspect of the present invention includes a thermoelectric element having a specified thickness and area and used as a base; An indoor temperature sensor disposed in close contact with an upper portion of the thermoelectric element; A solar radiation sensor disposed on an upper side within a specific distance designated on one side of the room temperature sensor; A housing enclosing the thermoelectric element, the room temperature sensor, and the solar radiation sensor; A printed circuit board for connecting the leads of the thermoelectric element, the room temperature sensor, and the solar radiation sensor to wiring according to a specified circuit configuration using a pattern; And a terminal part extending to connect the wiring pattern connected to each lead of the printed circuit board to an external device.

In the present invention, the room temperature sensor is in close contact with the surface of the thermoelectric element, and the surface is a surface which is cooled when the thermoelectric element is operated.

In the present invention, the solar radiation sensor is disposed above the room temperature sensor, and the solar radiation sensor is disposed above the room temperature sensor in a state where the solar radiation sensor is not in contact with the surface of the thermoelectric element. do.

In the present invention, the housing is formed in a cylindrical shape, and the housing is formed in a two-step cylindrical shape having a lower end portion than the upper end portion so as to serve as a latching protrusion when assembled with an external device do.

In the present invention, each lead of the thermoelectric element, the room temperature sensor, and the solar radiation sensor is connected to each wiring pattern of the printed circuit board attached to the lower end of the housing through the thermoelectric element .

In the present invention, each wiring pattern of the printed circuit board has six upper end wiring patterns and is connected to each lead of the thermoelectric element, the room temperature sensor, and the solar radiation sensor.

In the present invention, each wiring pattern of the printed circuit board is internally connected to one lead (-) lead of the thermoelectric element and one lead (-) lead of the room temperature sensor in common, And the other lead ((+) lead) of the thermoelectric element and the one lead (-) lead of the solar radiation sensor are connected in common.

In the present invention, each of the wiring patterns of the printed circuit board has four lower-end wiring patterns, the wiring pattern to which the other lead (+ lead) of the room temperature sensor is connected is connected to the first terminal, The wiring pattern to which the other lead ((+) lead) of the device and the one lead (-) lead of the solar radiation sensor are connected in common is connected to the second terminal, and the other lead ) Is connected to the third terminal, and a wiring pattern to which one lead (-) lead of the thermoelectric element and one lead (-) lead of the room temperature sensor are connected in common is connected to the fourth terminal Respectively.

In the present invention, the terminal portion and the wiring pattern of the printed circuit board serve to connect the input power source and the signal line from the air conditioning controller, and each terminal (first to fourth terminals) of the terminal portion is connected to the air conditioning controller And each of the designated functional terminals is a solar F / B (feedback), a GND, a 5V REF, and a room temperature F / B (feedback).

In the present invention, the voltage (5V REF) applied to the terminal designated by the air conditioning controller is applied to the solar radiation sensor through the wiring pattern, and when there is a solar radiation, the solar radiation sensor responds to the feedback voltage (+ Lead) of the thermoelectric element through a common wiring pattern connected in the printed circuit board to form the thermoelectric element (F / B) The surface temperature of the thermoelectric element on which the room temperature sensor is mounted is cooled according to the operation of the thermoelectric element and the sensed temperature rises due to the solar radiation is lowered so that the room temperature sensor can detect a normal room temperature .

According to one aspect of the present invention, the influence of disturbance caused by the solar radiation of a room temperature sensor for a vehicle can be overcome in hardware using a thermoelectric element, thereby improving the accuracy of a room temperature sensor for a vehicle, So that it is possible to reduce the calculation load of the apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary diagram showing a cross-section and a circuit configuration of a vehicle interior temperature sensor according to an embodiment of the present invention; FIG.
Fig. 2 is an exemplary view showing an interior temperature sensor for a vehicle viewed from above in Fig. 1; Fig.

Hereinafter, an embodiment of a vehicle interior temperature sensor according to the present invention will be described with reference to the accompanying drawings.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is an exemplary view showing a cross-section and a circuit configuration of a vehicle interior temperature sensor according to an embodiment of the present invention, and FIG. 2 is an exemplary view showing an interior temperature sensor for a vehicle viewed from above in FIG.

1 and 2, the vehicle room temperature sensor according to the present embodiment includes a thermoelectric element 110 having a specified thickness and area and used as a base, A solar radiation sensor 130 disposed closely within a specified distance on one side of the room temperature sensor 120, the thermoelectric device 110, the indoor temperature sensor 120 A housing 140 for enclosing the solar radiation sensor 130 and the solar radiation sensor 130, a lead (e.g., (+)) of the thermoelectric device 110, the indoor temperature sensor 120, A printed circuit board (PCB) 150 for connecting the leads of the printed circuit board 150 to the wirings according to the circuit configuration using a pattern, and a pattern of each lead of the printed circuit board 150, Including a terminal portion 160 (or a connector pin), in one component type (i.e., a sensor assembly Assy: a ssembly).

The room temperature sensor 120 is in close contact with the surface of the thermoelectric element 110. More specifically, the room temperature sensor 120 has a structure in which the thermoelectric element 110 is placed on a surface cooled when the thermoelectric element 110 is operated .

The solar radiation sensor 130 is disposed on the upper side of the room temperature sensor 120 and the solar radiation sensor 130 is positioned on the upper side without contacting the thermoelectric element 110. That is, the solar radiation sensor 130 is disposed above the room temperature sensor 120 for the purpose of avoiding interference by the peripheral housing 140.

The room temperature sensor 120 is disposed at a central portion of the thermoelectric element 110 relative to the solar radiation sensor 130.

The thermoelectric element 110 used as the base is a rectangular shape and the housing 140 that surrounds the thermoelectric element 110, the indoor temperature sensor 120, and the solar radiation sensor 130 is cylindrical . More specifically, the housing 140 is formed in a two-stage cylindrical shape having a lower diameter than the upper end so that the housing 140 can act as a latching jaw when assembled with an external device (e.g., an air conditioner panel or an air conditioner panel).

Leads (e.g., (+) and (-) leads) of the thermoelectric element 110, the indoor temperature sensor 120, and the solar radiation sensor 130 penetrate through the thermoelectric element 110 And is connected to each wiring pattern of the printed circuit board 150 attached to the lower end of the housing 140.

Here, it is assumed that the printed circuit board 150 is connected to each lead (e.g., (+), (-) lead) of the thermoelectric element 110, the indoor temperature sensor 120 and the solar radiation sensor 130 The upper end wiring patterns are six in number, and one lead (e.g., (-) lead) of the thermoelectric element 110 and one lead (e.g., (-) lead) of the room temperature sensor 120 are connected in common (For example, (+) lead) of the thermoelectric element 110 and one lead (for example, (-) lead) of the solar radiation sensor 130 are connected in common.

A wiring pattern to which the other lead (for example, (+) lead) of the room temperature sensor 120 is connected is connected to the first terminal (For example, (+) lead) of the thermoelectric element 110 and one lead (for example, (-) lead) of the solar radiation sensor 130 are connected to the heating element (For example, (+) lead) of the solar radiation sensor 130 is connected to a third terminal (for example, a lead wire) connected to a second terminal 5V REF and a wiring pattern to which one lead (for example, lead) of the thermoelectric element 110 and one lead (for example, lead (-)) of the room temperature sensor 120 are connected in common To a fourth terminal (e.g., GND).

The terminal portion 160 and the wiring pattern of the printed circuit board 150 serve to connect an input power source and a signal line from the air conditioning controller 200.

The terminals (first to fourth terminals) of the terminal unit 160 are connected to respective designated terminals (for example, solar F / B, GND, 5V REF, room temperature F / B) of the air conditioner controller 200.

The voltage 5V REF applied to the terminal designated by the air conditioning controller 200 is applied to the solar radiation sensor 130 through the wiring pattern of the PCB 150 and the solar radiation sensor 130, The feedback voltage (solar F / B) is formed.

The thus formed feedback voltage (solar F / B) is applied to the other lead (for example, (+) lead) of the thermoelectric element 110 in the common wiring pattern in the printed circuit board 150, .

Accordingly, when the thermoelectric element 110 operates, the surface of the thermoelectric element 110 on which the room temperature sensor 120 is mounted is cooled (cooled) and the sensed temperature rises due to the infrared ray is lowered. Accordingly, the indoor temperature sensor 120 can normally detect the indoor temperature. That is, the temperature of the housing 140 rising due to the sunlight reflected in the housing 140 of the sensor sensor according to the present embodiment is compensated through a hardware circuit so that the air conditioning controller 200 performs temperature compensation So that the calculation load can be reduced.

At this time, the resistance value of the pull-down resistor connected to the solar radiation sensor 130 is adjusted to the air conditioning controller 200, and the operation of the thermoelectric device 110 according to the solar radiation amount applied to the housing 140 is evaluated The resistance value of the pull-down resistor may be fixed after grasping.

As described above, the present embodiment overcomes the disturbance influence of the room temperature sensor in the sensor sensor by using a hardware circuit using a thermoelectric element, without correcting it through a software algorithm or logic logic, The accuracy of the temperature sensor can be improved. Accordingly, there is an additional effect that the calculation load for temperature compensation (correction) of the air conditioning controller can be reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, I will understand the point. Accordingly, the technical scope of the present invention should be defined by the following claims.

110: thermoelectric element 120: indoor temperature sensor
130: Solar radiation sensor 140: Housing
150: printed circuit board 160: terminal portion

Claims (10)

A thermoelectric element having a specific thickness and area specified and used as a base;
An indoor temperature sensor disposed in close contact with an upper portion of the thermoelectric element;
A solar radiation sensor disposed on an upper side within a specific distance designated on one side of the room temperature sensor;
A housing enclosing the thermoelectric element, the room temperature sensor, and the solar radiation sensor;
A printed circuit board for connecting the leads of the thermoelectric element, the room temperature sensor, and the solar radiation sensor to wiring according to a specified circuit configuration using a pattern; And
And a terminal part extending to connect the wiring pattern connected to each lead of the printed circuit board to an external device.
The indoor temperature sensor according to claim 1,
Wherein the surface is in close contact with the surface of the thermoelectric element, and the surface is a surface which is cooled when the thermoelectric element is operated.
The apparatus of claim 1, wherein the solar radiation sensor comprises:
Wherein the temperature sensor is disposed on the upper side of the room temperature sensor, and the solar radiation sensor is disposed on the upper side of the room temperature sensor without contacting the surface of the thermoelectric device.
The method according to claim 1,
The housing is formed in a cylindrical shape,
Wherein the housing is formed in a two-step cylindrical shape having a lower end portion longer in diameter than an upper end portion so that the housing can act as a latching jaw when assembled with an external device.
The method according to claim 1,
Each lead of the thermoelectric element, the room temperature sensor, and the solar radiation sensor,
Wherein the housing is connected to each wiring pattern of a printed circuit board attached to a lower end portion of the housing through the thermoelectric element.
The printed wiring board according to claim 1,
Wherein the upper end wiring pattern is six, and is connected to each lead of the thermoelectric element, the indoor temperature sensor, and the solar radiation sensor.
The printed wiring board according to claim 1,
(-) lead of the thermoelectric element and a one-side lead (-) lead of the room temperature sensor are connected in common, and the other lead ((+ And one side lead of the sensor ((-) lead) is connected in common.
The printed wiring board according to claim 1,
(+) Lead of the room temperature sensor is connected to the first terminal, and the other lead ((+) lead) of the thermoelectric element and the solar radiation sensor And a wiring pattern to which the other lead ((+) lead) of the solar radiation sensor is connected is connected to the third terminal, Wherein a wiring pattern to which one lead (-) lead of the device and one lead (-) lead of the room temperature sensor are connected in common is connected to the fourth terminal.
2. The printed wiring board according to claim 1,
It performs the role of connecting the input power and signal line from the air conditioning controller,
The respective terminals (first to fourth terminals) of the terminal unit are connected to respective designated functional terminals of the air conditioning controller, and the designated functional terminals are connected to a solar F / B (feedback), a GND, a 5V REF, / B (feedback). ≪ / RTI >
10. The method of claim 9,
The voltage (5V REF) applied to the terminal designated by the air conditioning controller is applied to the solar radiation sensor through the wiring pattern. When there is a solar radiation, the solar radiation sensor responds to the feedback voltage (solar F / B) Lt; / RTI >
The generated feedback voltage (solar F / B) is applied to the other lead ((+) lead) of the thermoelectric element through a common wiring pattern connected in the printed circuit board to operate the thermoelectric element,
Wherein a surface temperature of the thermoelectric element on which the room temperature sensor is mounted is cooled by the operation of the thermoelectric element to lower the sensed temperature caused by the solar radiation so that the room temperature sensor can sense a normal room temperature. Room temperature sensor.

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