JP2020118560A - Temperature monitoring device - Google Patents

Abstract

To prevent an increase in the number of terminals.SOLUTION: A sensor unit 100 comprises: a plurality of first lines L11 to L14; a plurality of second lines L21 to L23; and a plurality of temperature sensors T11 to T34 whose one end is connected to one of the plurality of first lines L11 to L14 and the other end is connected to one of the second lines L21 to L23. A control unit 200 comprises: a plurality of analog switches 11 to 14 for switching between connection and disconnection between each of the first lines L11 to L14 and the power supply terminal 40; a plurality of analog switches 21 to 23 for switching between connection and disconnection between each of the second lines L21 to L23 and a ground terminal 50; and a multiplexer 60 for outputting an electric potential of one of the first lines L11 to L14.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a temperature monitoring device.

A temperature monitoring device has been put into practical use, which monitors the temperature by measuring the potential of a temperature sensor whose resistance value changes according to the temperature change.

Patent Document 1 discloses a temperature monitoring device that monitors a potential of a temperature sensor with a microcomputer or the like by using a voltage dividing circuit in which one end of a sensor is connected to ground and the other end is connected to a power supply terminal via a pull-up resistor. It is disclosed. This temperature monitoring device calculates the temperature from the potential of the temperature sensor based on the temperature characteristic of the temperature sensor.

Japanese Patent Laid-Open No. 2000-193533

However, since the temperature monitoring device described in Patent Document 1 requires one or more terminals for one temperature sensor, many terminals are required when a plurality of temperature sensors are provided. For example, even if the ground side terminals of a plurality of temperature sensors are shared, N+1 terminals are required for N temperature sensors. Therefore, as the number of temperature sensors increases, the number of terminals also increases, resulting in the problem of increased cost and increased size of the device.

An object of the present invention is to provide a temperature monitoring device capable of suppressing an increase in the number of terminals.

A temperature monitoring device according to one embodiment of the present invention is a temperature monitoring device that monitors a temperature using a temperature sensor whose resistance value changes in accordance with a temperature change, and includes a plurality of first wirings and a plurality of second wirings. A sensor unit including a wire and a plurality of the temperature sensors each having one end connected to one of the plurality of first wires and the other end connected to one of the plurality of second wires; A plurality of first analog switches for switching connection and disconnection between each wiring and a power supply terminal; a plurality of second analog switches for switching connection and disconnection between each of the plurality of second wirings and a ground terminal; And a control unit including a selection circuit that outputs one of the potentials of the first wiring.

The temperature monitoring device according to one embodiment of the present invention is a plurality of first wirings, a plurality of second wirings, one end of which is connected to any of the plurality of first wirings, and the other end of which is the plurality of first wirings. A vehicle electronic control device connectable to a sensor unit including a plurality of temperature sensors connected to any of the two wirings, the plurality of first terminals connected to each of the plurality of first wirings, A plurality of second terminals connected to each of the plurality of second wirings; a plurality of first analog switches for switching connection and disconnection between each of the plurality of first terminals and a power supply terminal; A plurality of second analog switches that switch connection and disconnection of each of the terminals and the ground terminal, and a selection circuit that outputs the potential of one of the plurality of first terminals.

According to the present invention, an increase in the number of terminals can be suppressed.

It is a figure which shows the structure of the temperature monitoring apparatus in one Embodiment of this invention. 3 is a timing chart for explaining an example of a temperature monitoring device according to an embodiment of the present invention. It is a figure which shows the relationship between a temperature sensor and a terminal reduction rate.

Embodiments of the present invention will be described below with reference to the drawings. In the drawings, components having the same function are designated by the same reference numeral, and the description thereof may be omitted.

FIG. 1 is a diagram showing a configuration of a temperature monitoring device according to an embodiment of the present invention. The temperature monitoring device 10 shown in FIG. 1 monitors the temperature of a monitoring target by using the temperature sensors T11 to T34 whose resistance values change with temperature changes. The temperature monitoring device 10 may be mounted on a vehicle (not shown) and used to monitor the temperature of each part of the vehicle.

As shown in FIG. 1, the temperature monitoring device 10 includes a sensor unit 100 and a control unit 200.

The sensor unit 100 has a plurality of first wirings L11 to L14, a plurality of second wirings L21 to L23, and a plurality of temperature sensors T11 to T34. The first wirings L11 to L14 are connected to the column-side terminals X1 to X4 that are the first terminals of the control unit 200, and the second wirings L21 to 23 are the row-side terminals Y1 that are the second terminals of the control unit 200. ~ Connected to Y3.

The temperature sensors T11 to T34 are elements whose resistance value changes with a change in temperature. One ends of the temperature sensors T11 to T34 are connected to any of the first wirings L11 to L14, and the other ends are connected to any of the second wirings L21 to L23.

In the example of the figure, the first ends of the temperature sensors T11, T21, and T31 are connected to the first wiring L11, and the first ends of the temperature sensors T12, T22, and T32 are connected to the first wiring L12. The first ends of the sensors T13, T23 and T33 are connected to the first wiring L13, and the first ends of the temperature sensors T14, T24 and T34 are connected to the first wiring L14. The second ends (ends different from the first end) of the temperature sensors T11, T12, T13, and T14 are connected to the second wiring L21, and the second ends of the temperature sensors T21, T22, T23, and T24. Is connected to the second wiring L22, and the second ends of the temperature sensors T31, T32, T33, and T34 are connected to the second wiring L23.

Although the temperature sensors T11 to T34 are arranged in a matrix in FIG. 1, the temperature sensors T11 to T34 may not be arranged in a matrix as long as they have the above-described connection relationship. For example, when the temperature monitoring device 10 is installed in a vehicle, the temperature sensors T11 to T34 measure the temperatures of exhaust gas, intake air temperature, oil temperature, water temperature, battery temperature, and various device temperatures. It may be located in the vicinity of the monitored object at various locations of the vehicle.

Below, the temperature sensors T11 to T34 are assumed to be arranged in a matrix for convenience. The temperature sensors T11 to T34 are arranged in a matrix with four columns and three rows, but the size of the matrix (the number of columns and the number of rows), that is, the number of temperature sensors is Not limited to this, it can be changed as appropriate. Further, the number of temperature sensors included in different columns (temperature sensors connected to different first wirings) and the number of temperature sensors included in different rows (temperature sensors connected to different second wirings) may be different from each other. Good.

The characteristics of the temperature sensors T11 to T34 (rate of change of resistance value with respect to temperature change, etc.) may differ depending on the monitoring target for monitoring the temperature. The temperature sensors T11 to T34 may have the same characteristics as each other, or may have the characteristics different from each other. At this time, it is desirable that the temperature sensors included in the same row have the same characteristics and the temperature sensors included in different rows have different characteristics. In this case, it is advantageous to measure the temperature of the monitored object that differs for each row.

The control unit 200 controls the sensor unit 100. The control unit 200 is composed of, for example, an ECU (Electronic Control Unit).

The control unit 200 monitors analog switches 11 to 14 and 21 to 23, pull-up resistors 31 to 34, a power supply terminal (Vcc) 40, a ground terminal (GND) 50, a multiplexer (MPX: Multiplexer) 60, and a monitor. And a control unit 70.

The column-side terminals X1 to X4 of the control unit 200 are connected to the power supply terminal 40 via the pull-up resistors 31 to 34 and the analog switches 11 to 14. The pull-up resistors 31 to 34 may have different resistance values. The resistance values of the pull-up resistors 31 to 34 are determined according to the characteristics of the temperature sensors T11 to T34 connected via the column side terminals X1 to X4.

The analog switches 11 to 14 are first analog switches that switch connection and disconnection between the terminals X1 to X4 and the power supply terminal 40 by switching on and off. When the analog switches 11 to 14 are turned on, they connect the terminals X1 to X4 and the power supply terminal 40. As a result, the power supply potential is supplied from the power supply terminal 40 to the temperature sensors T11 to T34 through the pull-up resistors 31 to 34, the column-side terminals X1 to X4, and the first wirings L11 to L14.

The row-side terminals Y1 to Y3 of the control unit 200 are connected to the ground terminal 50 via the analog switches 21 to 23. The analog switches 21 to 23 are second analog switches that switch connection and disconnection between the terminals Y1 to Y3 and the ground terminal 50. When the analog switches 21 to 23 are turned on, the terminals Y1 to Y3 are connected to the ground terminal 50. This allows
The ground potential is supplied to the temperature sensors T11 to T34 through the row-side terminals Y1 to Y3 and the second wirings L21 to L23.

Further, the wiring connecting the column-side terminals X1 to X4 and the power supply terminal 40 is branched between the column-side terminals X1 to X4 and the pull-up resistors 31 to 34, and is connected to the multiplexer 60. The multiplexer 60 selects any of the connected column-side terminals X1 to X4 in accordance with a selection signal from the monitoring controller 70, and outputs the potential of the selected terminal. That is, the multiplexer 60 outputs one of the potentials of the first wirings L11 to L14 connected to the terminals X1 to X4.

The monitoring controller 70 calculates the temperatures of the temperature sensors T11 to T34 based on the potential output from the multiplexer 60. The monitoring control unit 70 specifically includes a column selection unit 1, a row selection unit 2, an A/D conversion unit 3, and a temperature calculation unit 4.

The column selection unit 1 is connected to the column-side analog switches 11 to 14 via the output terminals P11 to P14. The column selection unit 1 outputs a column-side switching signal that switches ON/OFF of the column-side analog switches 11 to 14 to the analog switches 11 to 14 via the output terminals P11 to P14, and thus the column-side analog switch 11 Control on-off of ~14. In the present embodiment, the column selection unit 1 outputs a switching signal according to an instruction from the temperature calculation unit 4. Specifically, among the temperature sensors T11 to T34, the column number of the temperature sensor selected by the temperature calculation unit 4 is designated, and the column selection unit 1 is arranged on the column side analog to which the temperature sensor of the designated column number is connected. A switch signal that turns on the switch and turns off the analog switches on the other columns is output. The column number of the temperature sensor specifies the first wiring to which the temperature sensor is connected.

The row selection unit 2 is connected to the row side analog switches 21 to 23 via the output terminals P21 to P23. The row selection unit 2 outputs a row-side switching signal for switching on/off of the row-side analog switches 21 to 23 to the analog switches 21 to 23 via the output terminals P21 to P23, and thereby the row-side analog switch 21. Control on-off of ~23. In the present embodiment, the row selection unit 2 outputs the switching signal according to the instruction from the temperature calculation unit 4. Specifically, the row number of the temperature sensor selected by the temperature calculation unit 4 among the temperature sensors T11 to T34 is designated, and the row selection unit 2 is configured to display the analog on the row side to which the temperature sensor of the designated row number is connected. A switch signal that turns on the switch and turns off the analog switches on the other rows is output. The row number of the temperature sensor specifies the second wiring to which the temperature sensor is connected.

The A/D converter 3 is connected to the multiplexer 60 via the input terminal P42. The potential output from the multiplexer 60 is input to the A/D conversion unit 3 via the input terminal P42. The A/D converter 3 performs A/D conversion on the input potential and outputs a digital signal indicating the input potential.

The temperature calculation unit 4 controls the analog switches 11 to 14 and 21 to 23 and the multiplexer 60 by using the column selection unit 1 and the row selection unit 2, and based on the digital signal from the A/D conversion unit 3, The temperature of the monitoring target is calculated, and a temperature signal indicating the temperature is output from the output terminal P1.

Specifically, first, the temperature calculation unit 4 selects one of the temperature sensors T11 to T34. The temperature calculation unit 4 sequentially and cyclically selects the temperature sensors T11 to T34, for example. The selection cycle for selecting the temperature sensors T11 to T34 is not particularly limited, and the selection cycle can be set according to the monitoring target or the like. For example, when the temperature monitoring device 10 is mounted on a vehicle, the selection cycle may be, for example, about 10 ms to several 100 ms or about 1 s.

Then, the temperature calculating unit 4 instructs the column number of the selected temperature sensor to the column selecting unit 1 and the row number of the selected temperature sensor to the row selecting unit 2. Further, the temperature calculator 4 inputs to the multiplexer 60 a selection signal for selecting a column-side terminal to which the selected temperature sensor is connected among the column-side terminals X1 to X4.

Therefore, the temperature calculation unit 4 can turn on the analog switch to which the selected temperature sensor is connected and turn off the other analog switches. Therefore, the pull-up resistor and the power supply terminal 40 can be connected to the upstream side of the selected temperature sensor, and the ground terminal 50 can be connected to the downstream side. As a result, the potential of the selected temperature sensor is output from the multiplexer 60, converted into a digital signal by the A/D conversion unit 3, and input to the temperature calculation unit 4.

The temperature calculation unit 4 calculates the temperature of the monitoring target based on the input digital signal. As a calculation method for calculating the temperature from the digital signal, for example, a method of referring to a lookup table indicating the relationship between the temperature and the potential, a method of calculating using a mathematical expression (approximate expression) indicating the relationship between the potential and the temperature, etc. There is.

FIG. 2 is a timing chart for explaining an example of the operation of the temperature monitoring device 10. FIG. 2 shows an example of an operation of periodically monitoring the 12 temperature sensors T11 to T34 in order. Further, the analog switches 11 to 14 and 21 to 23 are turned off when the switching signal is at the L level and are turned on when the switching signal is at the H level.

The temperature calculation unit 4 has a pulse width of ¼ cycle from the output terminals P11 to P14 of the column selection unit 1 as a switching signal on the column side, and the period of H level is shifted by ¼ cycle. The column number of the temperature sensor is instructed to the column selection unit 1 so that the four-phase pulse signals are output.

Further, the temperature calculation unit 4 has a pulse width of 1/3 cycle from the output terminals P21 to P23 of the row selection unit 2 as a row-side switching signal, and the period of H level is 1/3 cycle at a time. The row number of the temperature sensor is instructed to the row selection unit 2 so that the three-phase pulse signals that are offset from each other are output. At this time, the temperature calculation unit 4 instructs the column number and the row number so that the cycle (pulse width) of the row-side switching signal is four times the cycle (pulse width) of the column-side switching signal.

Further, the temperature calculation unit 4 outputs, from the output terminal P41, a signal that periodically selects the terminals X1 to X4 as the selection destination with the same pulse width as the switching signal on the column side as the selection signal of the multiplexer 60.

With the above operation, the temperature sensor is periodically turned on in the order of T11, T12, T13, T14, T21, T22, T23, T24, T31, T32, T33, T34, and the potential of the turned on temperature sensor is the multiplexer. It is input to the input terminal P42 via 60. The potential input to the input terminal P42 is converted into a digital signal by the A/D conversion section 3 and converted into a temperature to be monitored by the temperature calculation section 4.

In the present embodiment described above, the number of terminals is 12 in total for the 12 temperature sensors T11 to T34, that is, the column side terminals X1 to X4 and the row side terminals Y1 to Y3. On the other hand, in the conventional technique described in Patent Document 1, when the number of temperature sensors is 12, the number of terminals is 13. Therefore, in this embodiment, the number of terminals can be reduced by 6 as compared with the conventional technique.

FIG. 3 is a diagram showing the relationship between the number of temperature sensors and the terminal reduction rate. Specifically, the number of temperature sensors, which is the number of temperature sensors, the number of terminals of the conventional technique described in Patent Document 1, and the The number of terminals in the embodiment and the terminal reduction rate, which is the ratio of the number of terminals in the present embodiment to the number of terminals in the conventional technique, are shown.

It should be noted that the number of terminals in the present embodiment differs depending on the arrangement of the temperature sensors (the number of rows and the number of columns) even if the number of temperature sensors is the same. For example, when there are 12 temperature sensors, the number of terminals is 7 when the temperature sensors are arranged in a 4×3 matrix, and when the temperature sensors are arranged in a 6×2 matrix, the number of terminals is 8. .. As for the number of terminals in this embodiment in FIG. 3, the smallest number of terminals is shown.

As shown in FIG. 3, it is possible to reduce the number of terminals with four or more temperature sensors, and the greater the number of temperature sensors, the higher the terminal reduction rate. For example, when there are four temperature sensors, the terminal reduction rate is 20%, but when there are 16 temperature sensors, the terminal reduction rate is 52.9%, and when there are 36 temperature sensors, the terminal reduction rate is This is 67.6%, and when the number of temperature sensors is 64, the terminal reduction rate is 75.4%.

As described above, the present disclosure includes the following items.
A temperature monitoring device (10) according to an aspect of the present disclosure monitors a temperature using temperature sensors (T11 to T34) whose resistance value changes with a change in temperature. The temperature monitoring device (10) includes a sensor unit (100) and a control unit (200). The sensor unit has a plurality of first wirings (L11 to L14), a plurality of second wirings (L21 to L23), one end connected to one of the plurality of first wirings, and the other end connected to one of the second wirings. A plurality of temperature sensors connected thereto. The control unit includes a plurality of first analog switches (11 to 14) for switching connection and disconnection between each of the plurality of first wirings and the power supply terminal (40), each of the plurality of second wirings, and a ground terminal (50). A plurality of second analog switches (21 to 23) for switching connection and disconnection with and a selection circuit (60) for outputting the potential of any of the plurality of first wirings are included.

Therefore, the plurality of temperature sensors has one end connected to one of the plurality of first wirings and the other end connected to one of the plurality of second wirings, and the connection and disconnection of each of the first wirings and the power supply terminal. Connection and disconnection of each of the second wirings and the ground terminal are switched. Therefore, the number of terminals for the temperature sensor can be limited to the sum of the numbers of the first wirings and the second wirings, so that the increase in the number of terminals can be suppressed.

In addition, the control unit selects any one of the plurality of temperature sensors, and among the plurality of first analog switches and the plurality of second analog switches, the first analog switch and the second analog switch connected to the selected temperature sensor. It has a supervisory control unit (70) for turning on. The selection circuit outputs the potential of the first wiring connected to the turned-on first analog switch.

Therefore, the first analog switch and the second analog switch connected to the selected temperature sensor are turned on, and the potential of the first wiring connected to the turned on first analog switch is output. Therefore, since the desired potential of the temperature sensor can be acquired, the temperature of the monitoring target can be individually monitored.

Moreover, the monitoring control unit sequentially selects the plurality of temperature sensors. Therefore, since the plurality of temperature sensors are sequentially selected, the temperatures of the plurality of monitoring targets can be sequentially monitored.

Further, the monitoring control unit periodically selects the plurality of temperature sensors. Therefore, since the plurality of temperature sensors are periodically selected, it is possible to periodically monitor the temperatures of the plurality of monitoring targets.

The control unit also has a plurality of pull-up resistors (31 to 34) connected to each of the plurality of first wirings. The characteristics of the temperature sensors connected to the different first wirings among the plurality of temperature sensors are different from each other, and the resistance values of the plurality of pull-up resistors are different from each other.

Therefore, among the plurality of temperature sensors, the characteristics of the temperature sensors connected to the different first wirings are different from each other, and the resistance values of the plurality of pull-up resistors connected to the respective first wirings are different from each other. Therefore, it is possible to change the characteristics of the temperature sensor and the resistance value of the pull-up resistor according to the monitoring target, and it is possible to appropriately monitor the temperature according to the monitoring target.

The control unit has a plurality of first terminals connected to the plurality of first wirings and a plurality of second terminals connected to the plurality of second wirings, respectively. The second analog switch is connected to the first wiring via the first terminal, and the second analog switch is connected to the second wiring via the second terminal.

As described above, since the control unit includes the plurality of first terminals connected to each of the plurality of first wirings and the plurality of second terminals connected to each of the plurality of second wirings, the sensor unit and the control unit can be controlled. It becomes possible to easily connect the parts.

The vehicle electronic control device (10) according to an aspect of the present disclosure includes a plurality of first wirings (L11 to L14), a plurality of second wirings (L21 to L23), and a plurality of first wirings at one end. And a sensor unit (100) including a plurality of temperature sensors (T11 to T34) connected to either of the second wirings and the other end thereof. The vehicle electronic control device (10) includes a plurality of first terminals (X1 to X4) connected to each of the plurality of first wirings, and a plurality of second terminals (X1 to X4) connected to each of the plurality of second wirings. Y1 to Y4), a plurality of first analog switches (11 to 14) for switching connection and disconnection between each of the plurality of first terminals and the power supply terminal (40), each of a plurality of second terminals and a ground terminal ( A plurality of second analog switches (21 to 23) for switching between connection and disconnection with 50) and a selection circuit (60) for outputting the potential of any of the plurality of first terminals.

Therefore, the plurality of temperature sensors has one end connected to one of the plurality of first wirings and the other end connected to one of the plurality of second wirings, and the connection and disconnection of each of the first wirings and the power supply terminal. Connection and disconnection of each of the second wirings and the ground terminal are switched. Therefore, the number of terminals for the temperature sensor can be limited to the sum of the numbers of the first wirings and the second wirings, so that the increase in the number of terminals can be suppressed.

The embodiment described above is merely an example, and the present invention is not limited to the configuration.

DESCRIPTION OF SYMBOLS 1... Column selection part 2... Row selection part 3... A/D conversion part 4... Temperature calculation part 10... Temperature monitoring device 11-14, 21-23... Analog switch 31-34... Pull-up resistance 40... Power supply terminal 50... Ground terminal 60... Multiplexer 70... Monitoring control part 100... Sensor part 200... Control part L11-L14... First wiring L21-L23 Second wiring T11-T34... Temperature sensor

Claims (7)

A temperature monitoring device that monitors a temperature using a temperature sensor whose resistance value changes with temperature change,
A plurality of first wirings, a plurality of second wirings, a plurality of the temperature sensors one end of which is connected to any of the plurality of first wirings, the other end is connected to any of the plurality of second wirings, A sensor unit including
A plurality of first analog switches that switch connection and disconnection between each of the plurality of first wirings and a power supply terminal, and a plurality of second analog switches that switch connection and disconnection between each of the plurality of second wirings and a ground terminal And a control unit including a selection circuit that outputs the potential of any one of the plurality of first wirings. The control unit selects any one of the plurality of temperature sensors, and selects a first analog switch and a first analog switch connected to the selected temperature sensor from among the plurality of first analog switches and the plurality of second analog switches. 2 It has a monitor and control unit that turns on the analog switch,
The temperature monitoring device according to claim 1, wherein the selection circuit outputs a potential of the first wiring connected to the turned-on first analog switch. The temperature monitoring device according to claim 2, wherein the monitoring control unit sequentially selects the plurality of temperature sensors. The temperature monitoring device according to claim 2, wherein the monitoring control unit periodically selects the plurality of temperature sensors. The control unit has a plurality of pull-up resistors connected to each of the plurality of first wirings,
The characteristics of the temperature sensors connected to the first wiring different from each other among the plurality of temperature sensors are different from each other,
The temperature monitoring device according to claim 1, wherein resistance values of the plurality of pull-up resistors are different from each other. The control unit has a plurality of first terminals connected to each of the plurality of first wirings and a plurality of second terminals connected to each of the plurality of second wirings,
The first analog switch is connected to the first wiring via the first terminal,
The temperature monitoring device according to claim 1, wherein the second analog switch is connected to the second wiring via the second terminal. A plurality of first wirings, a plurality of second wirings, and a plurality of temperature sensors each having one end connected to one of the plurality of first wirings and the other end connected to one of the plurality of second wirings. An electronic control device for a vehicle that can be connected to a sensor unit including:
A plurality of first terminals connected to each of the plurality of first wirings;
A plurality of second terminals connected to each of the plurality of second wirings;
A plurality of first analog switches for switching connection and disconnection between each of the plurality of first terminals and a power supply terminal;
A plurality of second analog switches for switching connection and disconnection between each of the plurality of second terminals and the ground terminal;
A vehicle electronic control device comprising: a selection circuit that outputs the potential of any one of the plurality of first terminals.

Images