KR101257692B1 - Dual type coupling structure for temperature sensing sensor - Google Patents

Abstract

PURPOSE: A dual type temperature sensor joining structure is provided to select extra temperature sensors by using a jumper connector in the outside, thereby reducing costs and time for replacing the temperature sensor. CONSTITUTION: A dual type temperature sensor comprises a measuring unit and power supply units(170,180,190). The measuring unit is fixed inside a target device, thereby measuring the inner temperature of the target device. The power supply units are connected to the outside of the device, thereby supplying power to the measuring unit. The measuring unit includes two or more sensors(120,130), and circuit patterns(140,150,160) The sensors are fixed to the inside of the device, thereby measuring temperature. The circuit patterns connect each electrode of the two or more sensors and the power supply units. The power supply units include a jumper connector setting a power supply to one of the two or more sensors.

Description

Dual type temperature sensor combined structure {DUAL TYPE COUPLING STRUCTURE FOR TEMPERATURE SENSING SENSOR}

The present invention relates to a connector type coupling device for a temperature sensor, and more particularly, includes a plurality of temperature sensor and a power supply unit for supplying power to the temperature sensor, which is fixed inside the device to be measured. The present invention relates to an apparatus for selecting and using one of a plurality of temperature sensors as needed by an external jumper connector of a supply part.

In general, the temperature sensor is used to detect the temperature of the device, such as a refrigerator, to perform the appropriate control according to the temperature. In the case of the refrigerator, in order to maintain the temperature inside the refrigerator at a constant temperature, if the internal temperature is formed higher than the threshold, cold air must be injected to lower the temperature. A temperature sensor is inserted into the inside of the appliance.

Such a temperature sensor detects a change in temperature by a change in current by using a change in resistance depending on temperature. For this purpose, a resistor for sensing temperature and a power supply module for supplying power to the resistor are combined. The temperature sensor of the combination is achieved.

The coupling device for the temperature sensor is fixed to the inside of the device to be measured in order to measure the internal temperature of the device to be measured. Therefore, when the combined structure is composed of one temperature sensor and a power supply device for supplying power to the same as the conventional structure of temperature sensor, it is difficult to replace the inserted sensor when it is abnormally operated. There was a problem of shortening the life.

Korean Patent Laid-Open Publication No. 10-2005-0102916 "Washing Machine Temperature Sensor" describes a configuration of a temperature sensor capable of sensing temperature and a temperature sensor cover part fixed to a device, and a connector part connected to a temperature sensor element and a lead wire.

However, since the prior patent fixes the temperature sensor to the washing machine and covers the temperature sensor cover, there is a problem in that the entire temperature sensor must be replaced together with the cover when the temperature sensor fails or shows an abnormal operation.

On the other hand, many of the devices that are subject to temperature measurement, such as refrigerators are often distributed around the moisture or moisture, and a separate coating treatment using an epoxy resin is required for the temperature sensor sensor coupling device inserted therein There was a problem that the work efficiency and productivity in the manufacturing process is lowered, there is a problem that the failure and malfunction of the sensor occurs due to the penetration of moisture despite the coating treatment.

Therefore, by adding one or more extra temperature sensor, it is possible to use the device in case of failure or malfunction of the temperature sensor, and it is possible to prevent the problem caused by moisture penetration even by simple manufacturing process. Development of the coupling structure is necessary.

Korean Patent Publication No. 10- 2005-01029168

The present invention is to solve the problems as described above, the present invention can be installed on the outside of the power supply for supplying power to the connector type and connected by using a jumper connector to select a temperature sensor to detect the temperature The purpose is to reduce the replacement cost and time by not replacing the entire measuring device due to a defective sensor.

An object of the present invention is to configure a temperature sensor sensor coupling structure using a printed circuit board (PCB), to be able to manufacture a temperature sensor sensor coupling structure in a simple process.

The present invention is to configure the temperature sensor sensor coupling structure using a double-sided printed circuit board, so that different poles of power are supplied to each side, to prevent failure and malfunction of the temperature sensor due to moisture infiltration The purpose.

In order to achieve the above object, the present invention is fixed to the inside of the device to be measured is a measurement unit for measuring the ambient temperature, the power supply for supplying the power of the measurement unit, the electrical according to the temperature change measured in the measurement unit It includes a microcomputer (MICOM) to receive a signal and adjust the temperature.

The measurement unit is fixed inside the device to be measured, and includes a temperature sensor for measuring temperature and at least one preliminary temperature sensor, and each temperature sensor is connected to a power supply and a circuit pattern. have. One of the (-) electrode or the (+) electrode of the temperature sensor is connected to each other and connected to the power supply, and one electrode not connected is connected to each power supply. The temperature sensor is a negative temperature characteristic (NTC) sensor whose resistance value is inversely proportional to the temperature by measuring the temperature of the device to be measured.The resistance value decreases when the temperature rises, and the correlation with the reference resistance value By the relationship, the current value is transmitted to the MICOM as the potential difference of the voltage supplied from the power supply is changed.

The power supply unit is fixed to the outside of the device to be measured to supply power to the measurement unit. The power supply connected to the outside has a circuit pattern that is connected to the temperature sensor of the measuring part, respectively, and can be connected by selecting the connector connected to the temperature sensor as a jumper connector.

MICOM operates to receive the current value changed according to the temperature change detected by the temperature sensor of the measurement unit and change the temperature to a temperature preset by the user.

The temperature sensors fixed to the equipment to be measured are in a situation in which the temperature sensors need to be replaced if they malfunction or do not function properly as the temperature sensors. However, in the prior literature or the prior patent, the cost is high and the replacement time is long because it is necessary to replace the fixed temperature sensor coupling device or the whole device to which the coupling device is fixed, instead of replacing only the temperature sensor according to the replacement object. I have a problem.

The present invention to solve this problem by installing the power supply to the outside in the form of a connector and by installing the margin of the temperature sensor to the measurement unit to enable the temperature sensor of the margin by using a jumper connector from the outside temperature sensor This can reduce the cost and time of replacement.

Therefore, due to the development of the temperature sensor sensor coupling device that must be fixed to the device when measuring the temperature can be utilized in a variety of industries, such as home appliances, industrial, production equipment.

The present invention has been described based on the fact that the temperature sensor can be selected as a jumper connector from the outside, but the core configuration of the present invention is not to replace the entire device with sensors that are fixed by using not only the temperature sensor but other sensors. The biggest feature is that it can be selected and replaced externally.

According to the present invention, the board connected between the measuring unit and the power supply unit is formed of a double-sided printed circuit board (PCB), and the (+) pole is placed on the front side and the (+) pole is placed on the rear side according to the polarity connected between the measuring unit and the power supply unit. In addition, the arrangement may be reversed, and the safety of the electrical short may be increased according to the circuit pattern disposed on the double-sided printed circuit board (PCB).

1 is a view showing an overall view of a temperature sensor connector type coupling device according to an embodiment of the present invention.
2 is a device configuration diagram of a temperature sensor connector type coupling device according to an embodiment of the present invention.
3 is a view showing the overall application of the temperature sensor connector type coupling device according to an embodiment of the present invention.
4 is a view showing a coupling state between the temperature sensor sensor connector type coupling device and the device to be measured according to an embodiment of the present invention.
FIG. 5 is a view showing a temperature sensor connector type coupling device according to an embodiment of the present invention disposed on a double-sided circuit board (PCB).

Other objects and features of the present invention will become apparent from the following description of embodiments with reference to the accompanying drawings.

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

However, the present invention is not limited to or limited by the embodiments. Like reference symbols in the drawings denote like elements.

The present invention relates to a connector-type coupling device for a temperature sensor, and more particularly, to an external jumper connector including a temperature sensor and a power supply for supplying power to a device to be measured. The present invention relates to a device for selecting and using a desired temperature sensor.

If the temperature sensor is fixed to the conventional device to be measured falls into a bad state or does not function properly as a temperature sensor is in a situation to replace the temperature sensor. However, in the prior literature or the prior patent, the cost is high and the replacement time is long because it is necessary to replace the fixed temperature sensor coupling device or the whole device to which the coupling device is fixed, instead of replacing only the temperature sensor according to the replacement object. I have a problem.

The present invention adds an extra temperature sensor of the measuring unit fixed to the device and connects with the power supply unit to provide a user with a desired temperature sensor using an external connector.

1 is a view showing an overall view of a temperature sensor connector type coupling device according to an embodiment of the present invention.

The measuring unit 110 of the temperature sensor connector type coupling device is fixed inside the device to be measured to serve to measure the temperature of the measurement target. The measuring unit 110 includes at least two or more sensors 120 and 130, and circuit patterns 140, 150 and 160 that connect the at least two or more sensors 120 and 130 to the power supply units 170, 180 and 190. ).

Sensors 120 and 130 are sensors for temperature sensing, which are fixed inside the device to be measured to measure the temperature of the measurement target and have a negative temperature characteristic (NTC) in which the resistance value is inversely proportional to the temperature of the measurement target. ) It is a sensor and receives power from the power supply unit 170, 180, 190 and transmits the amount of change of the current value to the MICOM according to the resistance value that changes. In general, the resistance has a characteristic that the resistance value increases as the temperature increases, but in a device such as a refrigerator, since a large amount of current flows into the microcomputer when the internal temperature increases, it is required to be configured to inject cold air. As the temperature increases, it is advantageous to use a negative temperature characteristic sensor that has a low resistance value and allows a large amount of current to flow.

The power supply units 170, 180 and 190 are configured as a connector type which is fixed to the outside of the device to be measured and supplies power to the sensors 120 and 130. The power supply unit 170, 180, 190 may select the temperature sensor 120 or the extra temperature sensor 130 using a jumper connector.

The circuit patterns 140, 150, and 160 serve to connect the respective sensors 120 and 130 and the respective power supply units 170, 180, and 190. One of the (-) or (+) electrodes of the sensors 120 and 130 is connected to each other and is connected to the power supply units 170, 180, and 190 using the circuit patterns 140, 150, and 160. . For example, connecting the (-) poles of the sensors 120 and 130 to each other is called the circuit pattern 150, and each of the (+) poles is assumed to be the circuit pattern 160 and 170 and then the circuit pattern 150. ) And the power supply unit 180. The remaining circuit patterns 160 and 170 are connected to the respective power supply units 170 and 190. In general, the circuit pattern means a portion formed in the printed circuit board to allow current to flow, and in the present invention, any medium or material may be used as long as it is a medium for connecting the current between the power supply and the sensor. The invention is not limited by the material or the material.

2 is a device configuration diagram of a temperature sensor connector type coupling device according to an embodiment of the present invention.

As shown in FIG. 2, the temperature sensor connector type coupling device according to the present invention includes a jumper connector 210, a first negative temperature sensor 220, a second negative temperature sensor 230, a reference resistor 240, The microcomputer 250 is included.

The jumper connector 210 serves to deliver a DC power supply (Vcc) to the place where necessary according to the user's selection of the negative temperature sensor (220, 230).

When the user wants to connect with the first sub-temperature sensor 220, a jumper connector is used to connect the connector fixed to the outside of the device to be measured. For example, when the user wants to select the first sub-temperature sensor 220, when the first sub-temperature sensor 220 is the sensor 120 of FIG. 1, the jumper connector 210 may supply the power supply unit 170 and the power. It is coupled between the supply unit 180 to activate the sensor 120. At this time, the second sub-temperature sensor 230 becomes an extra sensor 130 and becomes a power supply unit 180, 190 for supplying power to the extra sensor 130, and maintains the standby state as a spare sensor until the user desires it. Have

In the future, when the first sub-temperature sensor 220 becomes inoperable or fails to perform a desired role, the user is coupled between the power supply units 170 and 180 to use the second sub-temperature sensor 230. The jumper connector 210 may be coupled between the power supply units 180 and 190 to activate the sensor 130 to use the second sub-temperature sensor 230.

The first sub-temperature sensor 220 measures the temperature in the measuring unit fixed inside the device to be measured. The first sub-temperature sensor 220 is a device whose resistance value changes depending on the temperature, and measures the temperature inside the device to be measured. When the internal temperature increases, the resistance value decreases, and when the internal temperature decreases, the resistance value increases. Do it. Therefore, when the internal temperature rises while the DC power source is connected to the first negative temperature sensor 220 by the reference resistor 240 or the jumper connector 210, the resistance value of the first negative temperature sensor 220 is lowered. The value of the changed current applied between the reference resistor 240 and the first negative temperature sensor 220 is received by the microcomputer 250.

The second sub-temperature sensor 230 is a sensor 130 that serves as the first sub-temperature sensor 220 and serves as a preliminary sensor 130 of the first sub-temperature sensor 220 selected by the user. If the first sub-temperature sensor 220 malfunctions or becomes unusable, the user may utilize the jumper connector 210 installed on the outside of the device to be measured to make the second sub-temperature outside the device to be measured. The sensor 230 may be selected and activated. The second sub-temperature sensor 230 is a device whose resistance value changes depending on the temperature, and measures the temperature inside the device to be measured. When the internal temperature increases, the resistance value decreases, and when the internal temperature decreases, the resistance value increases. do. Accordingly, the resistance value of the second negative temperature sensor 230 when the internal temperature rises while the DC power source is connected to the second negative temperature sensor 230 by the jumper connector 210 through the reference resistor 240. Is lowered, so that the value of the changed current applied between the reference resistor 240 and the second negative temperature sensor 230 is received by the microcomputer 250.

The reference resistor 240 has a predetermined resistance value and is connected through a power supply unit and a first negative temperature sensor 220 or a second negative temperature sensor 230 and a jumper connector 210 to connect the first negative temperature sensor. According to the change in the resistance value of the 220 or the second negative temperature sensor 230, the current according to the potential difference between the reference resistor 240 and the first negative temperature sensor 220 or the second negative temperature sensor 230 is changed. The microcomputer 250 receives the changed current value.

The microcomputer 250 receives a current changed according to a potential difference between the first sub-temperature sensor 220 or the second sub-temperature sensor 230 fixed inside the device to be measured to determine the temperature of the device to be measured. It controls to maintain user preset temperature.

3 is a view showing the overall application of the temperature sensor connector type coupling device according to an embodiment of the present invention.

In the temperature sensor connector type coupling device, the measuring unit 310 connects at least two or more sensors 320 and 330 and a power supply unit 370, 380, and 390 to supply power to the sensors 320 and 330. Circuit patterns 340, 350, and 360.

The role of the temperature sensing sensor connector type coupling device as shown in Figure 1, but the width of the circuit pattern (340, 350, 360) in the end surface substrate can be configured by application.

The circuit patterns 340, 350, and 360 serve to connect the respective sensors 320 and 330 and the respective power supply units 370, 380, and 390. According to the exemplary embodiment of the present invention, the circuit pattern 350 may have a negative polarity, and the circuit patterns 340 and 360 corresponding thereto may have a positive polarity. Accordingly, the circuit patterns 340, 350, and 360, the sensors 320 and 330, and the respective power supply units 370, 380, and 390 may be disposed in front of the measurement unit 310, respectively. The negative polarities of the sensors 320 and 330 are connected to each other to be connected to the power supply 380. The positive polarities of the remaining sensors 320 and 330 are connected to the circuit patterns 340 and 360, respectively, to the respective power supply units 370 and 380.

4 is a view showing a coupling state between the temperature sensor sensor connector type coupling device and the device to be measured according to an embodiment of the present invention.

As illustrated in FIG. 4, the measurement unit 410 is coupled to and fixed by the coupling unit 480 of the device 470 to be measured.

As the measuring unit 410 is fixed to the inside of the device 470 to be measured, the temperature inside the device 470 to be measured is measured by at least two sensors 420 and 430. For example, when the user selects to use the sensor 420, the sensor 420 is activated by connecting the power supply units 440 and 450 located outside the device 470 to be measured using a jumper connector. . The remaining deactivated sensor 430 serves as a spare, and when the sensor 420 malfunctions or fails to perform a desired operation, the user uses a jumper connector to externally measure the device 470. It can be used by activating the sensor 430 by connecting to the power supply unit 405, 406 located in the.

FIG. 5 is a view showing a temperature sensor connector type coupling device according to an embodiment of the present invention disposed on a double-sided circuit board (PCB).

The temperature sensor connector type coupling device on the double-sided printed circuit board (PCB) consists of a rear portion (A) and a front portion (B). At least two sensors 510 and 520 and a power supply unit 560 and 580 are disposed on the front side B and at least two or more sensors 510 using circuit patterns 530 and 540 having the same electrode. 520 and the power supply units 560 and 580. In the rear part A, a circuit pattern 550 having another electrode not disposed in the front part B is disposed and connected to the power supply 570 to electrically short the electrical polarity with other polarities during operation in the temperature sensor connector type coupling device. (short) Probability can be greatly lowered to ensure safety.

According to an exemplary embodiment of the present invention, when a sensor is added in addition to at least two or more sensors 510 and 520, the pattern having the same electrode is combined with the circuit patterns 530 and 540 and the rest is corresponding to the number of sensors added. The other electrode can be joined by adding another power supply.

In the present invention as described above has been described by the specific embodiments, such as specific components and limited embodiments and drawings, but this is provided to help a more general understanding of the present invention, the present invention is not limited to the above embodiments. For those skilled in the art, various modifications and variations are possible from these descriptions.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and all of the equivalents and equivalents of the claims, as well as the following claims, will fall within the scope of the present invention. .

110: temperature sensor
120: temperature sensor
130: extra temperature sensor
140: circuit pattern connecting the sensor and the power supply
170: external connector of the power supply
210: jumper connector

Claims (4)

A measuring unit fixed inside the apparatus to be measured to measure internal temperature; And
A power supply unit connected to the outside of the device to supply power to the measurement unit;
Including,
The measuring unit is fixed to the inside of the device (sensor) for measuring the temperature (sensor); And
A circuit pattern connecting the electrodes of the at least two sensors and the power supply unit;
/ RTI >
The power supply unit is a jumper connector (Jumper connector) for setting to supply power to any one of the two or more sensors
Including,
The circuit pattern
Connecting the electrodes of any one of-or + electrodes of the two or more sensors to each other, and connecting them to the power supply unit;
The other one electrode which is not connected is formed to be connected to the power supply, respectively.
The jumper connector is
And a dual-type temperature sensor coupling structure configured to supply power to a circuit pattern connecting the one electrode to each other and a circuit pattern connected to the other electrode of the selected one of the two or more sensors. delete The method of claim 1,
The two or more sensors and the circuit pattern are disposed on a double-sided printed circuit board (PCB), the dual type temperature sensor coupled to each of the different electrodes of the two or more sensors on the front and rear of the double-sided printed circuit board, respectively rescue. The method of claim 1,
The two or more sensors are negative temperature characteristic (NTC) sensor in which the resistance value is inversely proportional to temperature,
The measuring unit is a dual type temperature sensor sensor coupling structure for transmitting the current passing through the sensor is supplied to the power supply to the microcomputer (MICOM), to perform the control according to the temperature in the microcomputer (MICOM).

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