JP2018072183A - Abnormality detection device and liquid injection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an abnormality detection device that can notify an operator of disconnection even when wiring between substrates is disconnected.SOLUTION: An abnormality detection device comprises: a first circuit 4 that is installed on a first substrate 2; a second notification circuit 24 that is connected to the first circuit 4 via a first wire 13 and installed on a second substrate 3; and a second circuit 25 that is connected to the first circuit 4 via a second wire 17 and installed on the second substrate 3. The second circuit 25 and second notification circuit 24 are connected via a third wire 27, and the second notification circuit 24 detects disconnection of the first wire 13 and notifies an operator of the disconnection.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an abnormality detection device and a liquid ejection device.

  In a control device that controls various devices, a circuit may be composed of a plurality of circuit boards. Multiple circuit boards are due to reasons specific to the control device, such as the dimensions of the control device, temperature, and noise countermeasures. The plurality of circuit boards are connected by signal lines, and signals are transmitted through the signal lines.

  Each board is provided with a connector for connecting a signal line, and an interface circuit is provided depending on the type of signal. When an abnormality occurs in the connector, the signal line, or the interface circuit, the signal cannot be normally transmitted between the boards. At this time, the controller may output an abnormal output.

  Patent Document 1 discloses an apparatus that outputs an alarm indicating an abnormal state when signal transmission between substrates cannot be performed. According to this, each circuit board includes an abnormality monitoring unit that monitors abnormality. And the abnormal signal wiring which transmits the abnormal signal which shows that it is in an abnormal state is installed between the boards.

  When a signal cannot be normally transmitted between the substrates, an abnormal signal is transmitted through the abnormal signal wiring. And the abnormality monitoring part output the alarm.

JP 2002-374617 A

  The wiring between the substrates is more likely to be disconnected than the wiring in the substrate. The signal line and the abnormal signal wiring are easily disconnected. Therefore, the abnormal signal wiring may be disconnected. In the apparatus disclosed in Patent Document 1, an abnormal state alarm cannot be output when the abnormal signal wiring is disconnected. Therefore, there has been a demand for an apparatus capable of notifying that the wiring is disconnected even when the wiring is disconnected.

  The present invention has been made to solve the above-described problems, and can be realized as the following forms or application examples.

[Application Example 1]
An abnormality detection device according to this application example, a first circuit installed on a first substrate, a second notification circuit connected to the first circuit via a first wiring and installed on a second substrate, A second circuit connected to the first circuit via a second wiring and installed on the second substrate, wherein the second circuit and the second notification circuit are connected via a third wiring, The second notification circuit detects and notifies the disconnection of the first wiring.

  According to this application example, the abnormality detection device includes the first circuit, the second circuit, and the second notification circuit. The first circuit is installed on the first substrate, and the second circuit and the second notification circuit are installed on the second substrate. The first circuit and the second notification circuit are connected via the first wiring. The first circuit and the second circuit are connected via a second wiring. The second circuit and the second notification circuit are connected via a third wiring.

  When the first circuit becomes abnormal, the second circuit detects an abnormality of the first circuit and outputs an instruction signal to notify the second notification circuit via the third wiring. When the second circuit becomes abnormal, the first circuit detects an abnormality of the second circuit and outputs an instruction signal to notify the second notification circuit via the first wiring.

  Since the first wiring and the second wiring are wirings connecting the first substrate and the second substrate, they are easily damaged physically. When the second wiring is disconnected, the first circuit detects the disconnection of the second wiring and outputs an instruction signal to notify the second notification circuit via the first wiring. Alternatively, when the second wiring is disconnected, the second circuit detects the disconnection of the second wiring and outputs an instruction signal for informing the second notification circuit via the third wiring.

  When the first wiring is disconnected, the second notification circuit detects and notifies the disconnection of the first wiring. Therefore, even when the first wiring connecting the first substrate and the second substrate is disconnected, the second notification circuit can notify that the wiring between the substrates is disconnected.

[Application Example 2]
In the abnormality detection device according to the application example, the second substrate is connected to the second terminal via a second resistor, the second terminal connected to the second notification circuit to which the first wiring is connected, and the second terminal. A second power source for supplying a second voltage to the second terminal, and a first voltage different from the second voltage is supplied to the second terminal by the first wiring. Notification is not made when the voltage at the two terminals is the first voltage, and notification is made when the voltage at the second terminal is the second voltage.

  According to this application example, the second substrate includes the second terminal and the second power source. A first wiring is connected to the second terminal, and a first voltage is supplied to the second terminal through the first wiring. The second terminal is connected to the second notification circuit and supplies the first voltage to the second notification circuit.

  The second power source is connected to the second terminal via the second resistor and supplies the second voltage to the second terminal. When the first wiring is connected to the first substrate and the second substrate, the voltage supplied from the second power source is changed by the current flowing through the second resistor, so the voltage at the first terminal is close to the first voltage. .

  When the first wiring is disconnected, the first voltage is not supplied to the second terminal, so the voltage at the second terminal is close to the second voltage. The second notification circuit does not notify when the voltage at the second terminal is the first voltage, and notifies when the voltage at the second terminal is the second voltage. Therefore, when the first wiring is disconnected, the second notification circuit can notify that the first wiring is disconnected.

[Application Example 3]
In the abnormality detection apparatus according to the application example, the first substrate is connected to the first terminal via a first resistor, the first terminal connected to the first circuit to which the first wiring is connected, and the first board. A first power source for supplying the first voltage to one terminal and supplying the second voltage to the first circuit, wherein the first circuit is connected to the first terminal, and the first terminal is connected to the first terminal. A switching element for switching whether to supply the second voltage is provided, and a resistance value of the second resistor is higher than a resistance value of the first resistor.

  According to this application example, the first substrate includes the first terminal and the first power source. A first wiring is connected to the first terminal, and the first terminal is connected to the first circuit. The first power source is connected to the first terminal via a first resistor and supplies a first voltage to the first terminal.

  The first circuit includes a switching element connected to the first terminal. The switching element switches whether to supply the second voltage to the first terminal. When the switching element supplies the second voltage to the first terminal, the voltage at the second terminal becomes the second voltage. As a result, the first circuit can notify the second notification circuit.

  When the switching element does not supply the second voltage to the first terminal, since the second resistance is higher than the first resistance, the first wiring can supply a voltage close to the first voltage to the second terminal. At this time, the second notification circuit does not notify. Therefore, when the first wiring is not disconnected, the first circuit can control whether or not the second notification circuit notifies.

[Application Example 4]
In the abnormality detection device according to the application example, the second power source supplies power to the second notification circuit, and the first substrate is connected to the first circuit and is notified by inputting a notification instruction signal. A notification circuit is installed, the first circuit detects an abnormality of the second power supply, and outputs the notification instruction signal to the first notification circuit.

  According to this application example, the second power supply supplies power to the second notification circuit. A first notification circuit is installed on the first substrate. The first notification circuit is connected to the first circuit and receives a notification instruction signal from the first circuit for notification.

  When the second power source fails, the second notification circuit becomes inoperable. At this time, the first circuit detects an abnormality in the second power supply. Then, the first circuit outputs a notification instruction signal to the first notification circuit. Therefore, the first notification circuit can also notify when the second power supply that supplies power to the second notification circuit fails.

[Application Example 5]
The liquid ejecting apparatus according to this application example is a liquid ejecting apparatus that ejects liquid from a nozzle unit, and includes an ejection control unit that controls ejection of the liquid, and the ejection control unit includes the abnormality detection device described above. It is characterized by providing.

  According to this application example, the liquid ejecting apparatus ejects liquid from the nozzle portion. The liquid ejecting apparatus includes an ejection control unit, and the ejection control unit controls ejection of the liquid. The injection control unit includes the abnormality detection device described above. The abnormality detection device described above can notify that the wiring between the substrates is disconnected even when the first wiring that connects the first substrate and the second substrate is disconnected. Therefore, the liquid ejecting apparatus includes an abnormality detection device capable of notifying that the wiring between the substrates is disconnected even when the first wiring connecting the first substrate and the second substrate is disconnected. can do.

The electric circuit diagram of the abnormality detection apparatus concerning 1st Embodiment. The figure for demonstrating the relationship of the state of each site | part. FIG. 6 is a block diagram illustrating a configuration of a liquid ejecting apparatus according to a second embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. In addition, each member in each drawing is illustrated with a different scale for each member in order to make the size recognizable on each drawing.

(First embodiment)
In the present embodiment, an abnormality detection device and a characteristic operation of the abnormality detection device will be described with reference to the drawings. The abnormality detection apparatus according to the first embodiment will be described with reference to FIGS. FIG. 1 is an electric circuit diagram of the abnormality detection device. In addition, the connection in an electrical circuit diagram shows an electrical connection. The abnormality detection device is a device installed along with a device having a circuit board such as a control device.

  As shown in FIG. 1, the abnormality detection device 1 includes a first substrate 2 and a second substrate 3. A first circuit 4 is installed on the first substrate 2. The first circuit 4 includes an abnormality detection unit 5 that detects an abnormality, and the abnormality detection unit 5 audits the state of various circuits including a circuit (not shown) installed on the first substrate 2 to detect whether or not there is an abnormality.

  A switching element 6 is connected to the abnormality detection unit 5. The switching element 6 switches the voltage output to the second substrate 3 according to the detection result of the abnormality detection unit 5. The switching element 6 is not particularly limited, and a transistor, a MOSFET (metal-oxide-semiconductor field-effect transistor), or the like can be used. In this embodiment, for example, the switching element 6 uses a MOSFET in the form of an open drain. At this time, the switching element 6 operates in the same manner as an open collector of a bipolar transistor.

  When the abnormality detection unit 5 does not detect an abnormality, the abnormality detection unit 5 turns off the switching element 6. And when the abnormality detection part 5 detects abnormality, the abnormality detection part 5 switches the switching element 6 from OFF to ON.

  The first substrate 2 includes a first power supply 7, and the first power supply 7 includes a first voltage terminal 8 and a second voltage terminal 9. Although the 1st voltage terminal 8 and the 2nd voltage terminal 9 are not specifically limited, In this embodiment, the voltage of the 1st voltage terminal 8 is set to 12v, and the voltage of the 2nd voltage terminal 9 is set to 0v, for example. . The second voltage terminal 9 is connected to the ground. The drain terminal of the switching element 6 is connected to the second voltage terminal 9 that is a ground.

  The output of the first voltage terminal 8 of the first power supply 7 is connected to one end of the first resistor 10, and the other end of the first resistor 10 is connected to the drain terminal and the first terminal 11 of the switching element 6. The first terminal 11 is a terminal provided for communication between the first substrate 2 and the second substrate 3. A second terminal 12 is installed on the second substrate 3, and the first terminal 11 and the second terminal 12 are connected by a first wiring 13.

  The first terminal 11 is installed on the first substrate 2. And the 1st wiring 13 is connected to the 1st terminal 11, and the 1st terminal 11 and the 1st circuit 4 are connected by the wiring. The first voltage terminal 8 of the first power supply 7 is connected to the first terminal 11 via the first resistor 10, and the first voltage terminal 8 supplies the first voltage to the first terminal 11. The first power supply 7 supplies the second voltage to the first circuit 4. The first circuit 4 is connected to the first terminal 11. Then, the switching element 6 of the first circuit 4 switches whether to supply the second voltage terminal 9 to the first terminal 11.

  The switching element 6 transitions between two states of on and off. The ON state is a state in which the first terminal 11 is short-circuited with the second voltage terminal 9 and the voltage at the first terminal 11 becomes the second voltage. The OFF state is a state in which the first terminal 11 is insulated from the second voltage terminal 9 and the voltage at the first terminal 11 becomes the first voltage.

  A first notification circuit 14 is installed on the first substrate 2 in connection with the first circuit 4. The first notification circuit 14 receives the notification instruction signal from the first circuit 4 and notifies it. Although the method to alert | report is not specifically limited, For example, in this embodiment, the 1st alerting | reporting circuit 14 blinks red light and utters a warning sound.

  In addition, a third terminal 15 connected to the first circuit 4 is provided on the first substrate 2. The third terminal 15 is a terminal provided for communication between the first substrate 2 and the second substrate 3. A fourth terminal 16 is installed on the second substrate 3, and the third terminal 15 and the fourth terminal 16 are connected by a second wiring 17.

  In addition, the first substrate 2 is provided with a fifth terminal 18 that is electrically connected to the second voltage terminal 9 included in the first power supply 7. The fifth terminal 18 is a terminal provided to make the ground have the same voltage between the first substrate 2 and the second substrate 3. A sixth terminal 21 is installed on the second substrate 3, and the fifth terminal 18 and the sixth terminal 21 are connected by a ground wiring 22. The first voltage terminal 8 and the second voltage terminal 9 connected to the first power supply 7 are also connected to the first circuit 4 and the first notification circuit 14. The first power supply 7 supplies the first voltage and the second voltage to the first circuit 4 and the first notification circuit 14.

  The second substrate 3 includes a second power source 23, and the second power source 23 is connected to the first voltage terminal 8 and the second voltage terminal 9. Similar to the first substrate 2, also in the second substrate 3, the voltage at the first voltage terminal 8 is the first voltage, and the voltage at the second voltage terminal 9 is the second voltage. The second voltage terminal 9 is connected to the ground. Since the sixth terminal 21 is connected to the ground, the ground of the first substrate 2 and the ground of the second substrate 3 are at the same voltage.

  In addition to the second power source 23, a second notification circuit 24 and a second circuit 25 are installed on the second substrate 3. The second power supply 23 supplies power to the second notification circuit 24 and the second circuit 25. The second terminal 12 is connected to the second notification circuit 24. Accordingly, the second notification circuit 24 is connected to the first circuit 4 via the first wiring 13. A first voltage different from the second voltage is supplied to the second terminal 12 by the first wiring 13.

  Further, the second terminal 12 is connected to the second voltage terminal 9 via the second resistor 26. The second voltage terminal 9 is a terminal to which the second power source 23 supplies a second voltage. Accordingly, the second power source 23 is connected to the second terminal 12 via the second resistor 26 and supplies the second voltage to the second terminal 12. The resistance value of the second resistor 26 is set to be higher than the resistance value of the first resistor 10.

  The second circuit 25 audits the state of various circuits (not shown) installed on the second substrate 3 and detects whether or not it is abnormal. Further, the second circuit 25 audits the state of the first circuit 4 and detects whether it is abnormal. Then, when an abnormality is recognized in various circuits or the first circuit 4, the second circuit 25 outputs a notification instruction signal to the second notification circuit 24.

  The abnormality detection unit 5 is connected to the second circuit 25 via the second wiring 17. Then, the abnormality detection unit 5 detects whether or not the second circuit 25 is normal. Further, when the second power source 23 fails, the second circuit 25 does not operate normally, so the abnormality detection unit 5 also detects a failure of the second power source 23.

  When the second power supply 23 fails, the second notification circuit 24 cannot notify the abnormal state. The abnormality detector 5 of the first circuit 4 detects an abnormality of the second power supply 23 and outputs a notification instruction signal to the first notification circuit 14. Then, the first notification circuit 14 receives the notification instruction signal from the first circuit 4 and notifies it.

  The fourth terminal 16 is connected to the second circuit 25. Accordingly, the second circuit 25 is connected to the first circuit 4 via the second wiring 17. The second circuit 25 is connected to the second notification circuit 24 via the third wiring 27 in addition to the fourth terminal 16.

  One of the first voltage terminals 8 connected to the second power source 23 is installed in the second notification circuit 24, and the first voltage is supplied to the first voltage terminal 8. Further, the second notification circuit 24 is provided with a second voltage terminal 9 connected to the second power source 23, and the second voltage terminal 9 is supplied with the second voltage. The warning lamp 28 and the buzzer 29 are connected in parallel with the first voltage terminal 8. The configuration of the warning lamp 28 is not particularly limited as long as it emits light when a voltage is applied. In the present embodiment, for example, an LED (Light Emitting Diode) is used for the warning light 28. The configuration of the buzzer 29 is not particularly limited as long as a warning sound is generated by applying a voltage. In the present embodiment, for example, the buzzer 29 has a configuration in which a transmission circuit and a speaker are combined.

  The warning lamp 28 and the buzzer 29 are connected to the first switch 30. The first switch 30 includes a first terminal 30a, a second terminal 30b, and a third terminal 30c, and a first control terminal 30d. When the voltage of the first control terminal 30d is close to the first voltage, the first terminal 30a is short-circuited with the second terminal 30b, and the third terminal 30c is insulated from the other terminals. When the voltage of the first control terminal 30d is close to the second voltage, the first terminal 30a is short-circuited with the third terminal 30c, and the second terminal 30b is insulated from the other terminals. The second terminal 30b and the third terminal 30c are always in an insulated state. The warning lamp 28 and the buzzer 29 are connected to the first terminal 30 a of the first switch 30.

  The second terminal 30 b of the first switch 30 is connected to the second switch 32 via the third resistor 31. The second switch 32 includes two terminals, a fourth terminal 32a and a fifth terminal 32b, and a second control terminal 32c. When the voltage of the second control terminal 32c is close to the first voltage, the fourth terminal 32a is short-circuited with the fifth terminal 32b. When the voltage at the second control terminal 32c is close to the second voltage, the fourth terminal 32a is insulated from the fifth terminal 32b. The third resistor 31 is connected to the fourth terminal 32 a of the second switch 32.

  The notification instruction signal output from the second circuit 25 to the second notification circuit 24 is a voltage close to the first voltage. When the second circuit 25 outputs a notification instruction signal to the second notification circuit 24, the fourth terminal 32a and the fifth terminal 32b are short-circuited in the second switch 32.

  The fifth terminal 32 b of the second switch 32 is connected to one of the second voltage terminals 9. The second control terminal 32 c is connected to the second circuit 25 by the third wiring 27. The third terminal 30 c of the first switch 30 is connected to one of the second voltage terminals 9 via the fourth resistor 33.

  When the first circuit 4 and the second circuit 25 operate normally, the second switch 32 is turned off, and the fourth terminal 32a and the fifth terminal 32b are insulated. A first voltage different from the second voltage is supplied to the second terminal 12 by the first wiring 13. When the voltage at the second terminal 12 is the first voltage, the second notification circuit 24 does not notify the first terminal 30a due to a short circuit with the second terminal 30b. When the first wiring 13 is disconnected, the first voltage is not supplied to the second terminal 12 and thus becomes the second voltage. When the voltage of the second terminal 12 is the second voltage, in the first switch 30, the first terminal 30a is short-circuited with the third terminal 30c for notification. Therefore, the second notification circuit 24 detects and notifies the disconnection of the first wiring 13.

  FIG. 2 is a diagram for explaining the relationship between the states of the respective parts. FIG. 2 is a table format, and items are shown in the first column at the left end of the figure. The second column to the ninth column show the status of each item in the status numbers “1” to “8”, respectively. With reference to FIG.1 and FIG.2, operation | movement of the abnormality detection apparatus 1 in the state of each site | part is demonstrated.

  2, the first circuit 4 is normal, the second circuit 25 is normal, the first wiring 13 is normal, the second wiring 17 is normal, the first power supply 7 is normal, and the second power supply is normal. 23 is a normal state. Normality in the first wiring 13 and the second wiring 17 indicates a state in which communication is possible without disconnection of the wiring. This state is a state in which the abnormality detection device 1 operates normally.

  Returning to FIG. 1, since the first power supply 7 and the first circuit 4 are normal, the abnormality detection unit 5 functions normally. Since the first circuit 4 is normal, the second circuit 25 is normal, and the second wiring 17 is normal, the abnormality detection unit 5 turns off the switching element 6 to insulate the first terminal 11 and the second voltage terminal 9 from each other. To do. For this reason, the voltage of the first terminal 11 is close to the first voltage of the first voltage terminal 8.

  Since the first wiring 13 is normally connected, a current flows through the first resistor 10, the first wiring 13 and the second resistor 26. A first voltage different from the second voltage is supplied to the second terminal 12 by the first wiring 13. Since the second resistor 26 has a higher resistance value than the first resistor 10, the voltage at the second terminal 12 is close to the first voltage. Since a voltage close to the first voltage is applied to the first control terminal 30d of the first switch 30, the first terminal 30a and the second terminal 30b are short-circuited in the first switch 30.

  Since the first circuit 4 is normal and the state of the second wiring 17 is also normal, the second circuit 25 detects that the first circuit 4 is normal. At this time, the second circuit 25 outputs a voltage close to the second voltage to the second control terminal 32 c of the second switch 32. In the second switch 32, since the voltage of the second control terminal 32c is close to the second voltage, the fourth terminal 32a and the fifth terminal 32b are insulated.

  Since the fourth terminal 32 a and the fifth terminal 32 b are insulated, no current flows through the warning lamp 28 and the buzzer 29. That is, the second notification circuit 24 does not notify when the voltage at the second terminal 12 is the first voltage. Accordingly, the second notification circuit 24 enters a stationary state.

  In the first circuit 4, the abnormality detection unit 5 detects whether or not the second power supply 23 is normal. Since the state of the first power supply 7 is normal, the abnormality detection unit 5 does not output a notification instruction signal to the first notification circuit 14. Accordingly, the first notification circuit 14 is in a stationary state. As a result, as shown in FIG. 2, when the state number is “1”, the first notification circuit 14 and the second notification circuit 24 are in a stationary state.

  When the state number is “2”, the first circuit 4 is normal, the second circuit 25 is abnormal, the first wiring 13 is normal, the second wiring 17 is normal, the first power supply 7 is normal, and the second power supply 23 is normal It is a state. This state is a state in which the second circuit 25 has failed and operates abnormally.

  Returning to FIG. 1, since the first power supply 7 and the first circuit 4 are normal, the abnormality detection unit 5 functions normally. Then, the abnormality detection unit 5 detects that the second circuit 25 is abnormal. The abnormality detection unit 5 turns on the switching element 6 to bring the first terminal 11 and the second voltage terminal 9 into a connected state. For this reason, the voltage of the first terminal 11 is close to the second voltage.

  Since the first wiring 13 is normally connected, the voltage of the second terminal 12 is close to the second voltage. Since a voltage close to the second voltage is applied to the first control terminal 30d of the first switch 30, the first terminal 30a and the third terminal 30c are short-circuited in the first switch 30.

  The first circuit 4 is normal, but the second circuit 25 is out of order. Therefore, the second circuit 25 cannot detect that the first circuit 4 is normal. At this time, the voltage output from the second circuit 25 to the second control terminal 32c of the second switch 32 is unknown. However, since the second terminal 30b of the first switch 30 is not connected, the second switch 32 is not energized. Therefore, the warning lamp 28 and the buzzer 29 are not affected by the failure of the second circuit 25.

  Since the first terminal 30a and the third terminal 30c are short-circuited, current flows through the warning lamp 28 and the buzzer 29. Accordingly, the warning lamp 28 is turned on and the buzzer 29 sounds. That is, the second notification circuit 24 is in a notification state.

  Since the second circuit 25 is out of order, the abnormality detection unit 5 cannot detect whether the second power source 23 is normal in the first circuit 4. Since the state of the first power supply 7 is normal, the abnormality detection unit 5 outputs a notification instruction signal to the first notification circuit 14. Accordingly, the first notification circuit 14 is in a notification state. As a result, as shown in FIG. 2, when the state number is “2”, the first notification circuit 14 is in the notification state, and the second notification circuit 24 is also in the notification state.

  In the state of the state number “3” in FIG. 2, the first circuit 4 is abnormal, the second circuit 25 is normal, the first wiring 13 is normal, the second wiring 17 is normal, the first power supply 7 is normal, and the second power supply is normal. 23 is a normal state. This state is a state in which the first circuit 4 has failed and operates abnormally.

  Returning to FIG. 1, since the first power supply 7 is normal but the first circuit 4 is abnormal, the state of the switching element 6 becomes unknown. For this reason, the voltage of the 1st terminal 11 and the 2nd terminal 12 becomes unknown.

  Since the voltage applied to the first control terminal 30d of the first switch 30 is unknown, in the first switch 30, the first terminal 30a is short-circuited with either the second terminal 30b or the third terminal 30c.

  The second circuit 25 is normal, and the second circuit 25 detects that the first circuit 4 is abnormal. At this time, the second circuit 25 outputs a voltage close to the first voltage to the second control terminal 32 c of the second switch 32. In the second switch 32, since the voltage of the second control terminal 32c is close to the first voltage, the second switch 32 is turned on. Then, the fourth terminal 32a and the fifth terminal 32b are short-circuited.

  As a result, in the first switch 30, current flows through the warning lamp 28 and the buzzer 29 regardless of whether the first terminal 30 a is short-circuited with either the second terminal 30 b or the third terminal 30 c. Accordingly, the second notification circuit 24 enters a notification state.

  Since the first circuit 4 is out of order, it is unknown whether the abnormality detection unit 5 outputs a notification instruction signal to the first notification circuit 14. As a result, as shown in FIG. 2, when the state number is “3”, the operation of the first notification circuit 14 is unknown, and the second notification circuit 24 is in the notification state.

  In the state of the state number “4” in FIG. 2, the first circuit 4 is abnormal, the second circuit 25 is abnormal, the first wiring 13 is normal, the second wiring 17 is normal, the first power supply 7 is normal, and the second power supply is normal. 23 is a normal state. This state is a state in which the first circuit 4 and the second circuit 25 are out of order and operate abnormally.

  Returning to FIG. 1, since the first power supply 7 is normal but the first circuit 4 is abnormal, the state of the switching element 6 is unknown. For this reason, the voltage of the 1st terminal 11 and the 2nd terminal 12 becomes unknown. Then, the voltage applied to the first control terminal 30d of the first switch 30 becomes unknown. In the first switch 30, the first terminal 30a is short-circuited with either the second terminal 30b or the third terminal 30c.

  The second circuit 25 is abnormal and the operation of the second switch 32 is in an unknown state. It is unclear whether the fourth terminal 32a is short-circuited with the fifth terminal 32b.

  As a result, it is unclear whether or not current flows through the warning lamp 28 and the buzzer 29. Therefore, the operation of the second notification circuit 24 is in an unknown state.

  Since the first circuit 4 is out of order, it is unknown whether the abnormality detection unit 5 outputs a notification instruction signal to the first notification circuit 14. As a result, as shown in FIG. 2, when the state number is “4”, the operation of the first notification circuit 14 is unknown and the second notification circuit 24 is in an unknown state. However, the probability that the first circuit 4 and the second circuit 25 fail simultaneously is low, and there is a high probability that one of them will fail and then the other will fail. Therefore, there is a high possibility that a period during which the second notification circuit 24 is in the notification state occurs.

  The state number “5” in FIG. 2 indicates that the first circuit 4 is normal, the second circuit 25 is normal, the first wiring 13 is disconnected, the second wiring 17 is normal, the first power supply 7 is normal, and the second power supply is normal. 23 is a normal state. This is a failure state in which the first wiring 13 is disconnected.

  Returning to FIG. 1, since the first power supply 7 and the first circuit 4 are normal, the abnormality detection unit 5 functions normally. Since the first circuit 4 is normal, the second circuit 25 is normal, and the second wiring 17 is normal, the abnormality detection unit 5 turns off the switching element 6 to insulate the first terminal 11 and the second voltage terminal 9 from each other. . For this reason, the voltage of the first terminal 11 is close to the first voltage of the first voltage terminal 8.

  However, since the first wiring 13 is disconnected, a circuit through which current flows through the first resistor 10, the first wiring 13, and the second resistor 26 is not formed. Since the second terminal 12 is connected to the second voltage terminal 9 via the second resistor 26, the voltage of the second terminal 12 is close to the second voltage. Since a voltage close to the second voltage is applied to the first control terminal 30d of the first switch 30, the first terminal 30a and the third terminal 30c are short-circuited in the first switch 30.

  The first circuit 4 is normal, and the second circuit 25 detects that the first circuit 4 is normal. At this time, the second circuit 25 outputs a voltage close to the second voltage to the second control terminal 32 c of the second switch 32. In the second switch 32, since the voltage of the second control terminal 32c is close to the second voltage, the fourth terminal 32a and the fifth terminal 32b are insulated.

  Since the first terminal 30a of the first switch 30 is short-circuited with the third terminal 30c, a current flows through the warning lamp 28 and the buzzer 29. That is, the notification is made when the voltage at the second terminal 12 is the second voltage. Accordingly, the second notification circuit 24 enters a notification state. As a result, the second notification circuit 24 detects and notifies the disconnection of the first wiring 13.

  In the first circuit 4, the abnormality detection unit 5 detects whether or not the second power supply 23 is normal. Since the state of the first power supply 7 is normal, the abnormality detection unit 5 does not output a notification instruction signal to the first notification circuit 14. Accordingly, the first notification circuit 14 is in a stationary state. As a result, as shown in FIG. 2, when the state number is “5”, the first notification circuit 14 is in a stationary state and the second notification circuit 24 is in a notification state.

  In the state of the state number “6” in FIG. 2, the first circuit 4 is normal, the second circuit 25 is normal, the first wiring 13 is normal, the first power supply 7 is normal, and the second power supply 23 is normal. . This is a failure state in which the second wiring 17 is disconnected.

  Returning to FIG. 1, since the first power supply 7 and the first circuit 4 are normal, the abnormality detection unit 5 functions normally. The first circuit 4 is normal and the second circuit 25 is normal. However, since the second wiring 17 is disconnected, the abnormality detecting unit 5 turns on the switching element 6 to turn on the first terminal 11 and the second voltage. Terminal 9 is connected. For this reason, the voltage of the first terminal 11 is close to the second voltage.

  Since the first wiring 13 is normally connected, the voltage of the second terminal 12 becomes close to the second voltage by the first wiring 13. Since a voltage close to the second voltage is applied to the first control terminal 30d of the first switch 30, the first terminal 30a and the third terminal 30c are short-circuited in the first switch 30.

  Since the first circuit 4 is normal but the second wiring 17 is disconnected, the second circuit 25 cannot detect that the first circuit 4 is normal. At this time, the second circuit 25 outputs a voltage close to the first voltage to the second control terminal 32 c of the second switch 32. In the second switch 32, since the voltage of the second control terminal 32c is close to the first voltage, the second switch 32 is turned on, the fourth terminal 32a and the fifth terminal 32b are short-circuited, and the connection state is established.

  The first terminal 30 a and the third terminal 30 c of the first switch 30 are short-circuited, and current flows through the warning lamp 28 and the buzzer 29. That is, the second notification circuit 24 notifies that the voltage at the second terminal 12 is close to the second voltage. Accordingly, the second notification circuit 24 enters a notification state.

  In the first circuit 4, the abnormality detection unit 5 detects whether or not the second power supply 23 is normal via the second wiring 17. Since the state of the second power supply 23 is unknown to the abnormality detection unit 5 when the second wiring 17 is disconnected, the abnormality detection unit 5 outputs a notification instruction signal to the first notification circuit 14. Accordingly, the first notification circuit 14 is in a notification state. As a result, as shown in FIG. 2, when the state number is “6”, the first notification circuit 14 and the second notification circuit 24 are in the notification state.

  2 is a state in which the second circuit 25 is normal, the first wiring 13 is normal, the second wiring 17 is normal, and the second power supply 23 is normal. The first circuit 4 and the first power supply 7 are in an abnormal state. This shows a state in which the first power supply 7 has failed and the first circuit 4 has malfunctioned.

  Returning to FIG. 1, since the first power supply 7 is abnormal, the operation of the abnormality detection unit 5 becomes abnormal. And the state of the switching element 6 becomes unknown. For this reason, the voltage of the 1st terminal 11 and the 2nd terminal 12 becomes unknown. Since the voltage applied to the first control terminal 30d of the first switch 30 is unknown, it is unclear whether the first switch 30 is short-circuited with the first terminal 30a as the second terminal 30b or the third terminal 30c. When the terminal that is short-circuited with the first terminal 30a is the third terminal 30c, a current flows through the warning lamp 28 and the buzzer 29.

  The first circuit 4 is abnormal, and the second circuit 25 detects that the first circuit 4 is abnormal. At this time, the second circuit 25 outputs a voltage close to the first voltage to the second control terminal 32 c of the second switch 32. In the second switch 32, since the voltage of the second control terminal 32c is close to the first voltage, the fourth terminal 32a and the fifth terminal 32b are short-circuited.

  Since the fourth terminal 32a and the fifth terminal 32b are short-circuited, current flows through the warning lamp 28 and the buzzer 29 even when the terminal short-circuited with the first terminal 30a is the second terminal 30b. That is, the second notification circuit 24 notifies when the first power supply 7 becomes abnormal. Accordingly, the second notification circuit 24 enters a notification state.

  In the first circuit 4, the first notification circuit 14 is not driven because the first power supply 7 is abnormal. Accordingly, the first notification circuit 14 is in a stationary state. As a result, as shown in FIG. 2, when the state number is “7”, the first notification circuit 14 is in a stationary state and the second notification circuit 24 is in a notification state.

  2 is a state in which the first circuit 4 is normal, the first wiring 13 is normal, the second wiring 17 is normal, and the first power supply 7 is normal. And the 2nd circuit 25 and the 2nd power supply 23 are in an abnormal state. This shows a state where the second power supply 23 has failed and the second circuit 25 has malfunctioned.

  Returning to FIG. 1, since the first power supply 7 and the first circuit 4 are normal, the abnormality detection unit 5 functions normally. Since the first circuit 4 is normal, the second circuit 25 is abnormal, and the second wiring 17 is normal, the abnormality detection unit 5 detects that the second circuit 25 is abnormal. Then, the abnormality detection unit 5 turns on the switching element 6 to bring the first terminal 11 and the second voltage terminal 9 into a connected state. For this reason, the voltage of the first terminal 11 is close to the second voltage.

  Since the first wiring 13 is normally connected, the voltage of the second terminal 12 is close to the second voltage. However, since the second power supply 23 is abnormal, it is unknown whether the operation of the second notification circuit 24 is in a notification state or a stationary state.

  In the first circuit 4, the abnormality detection unit 5 detects that the second power supply 23 is abnormal. Since the state of the first power supply 7 is normal, the abnormality detection unit 5 outputs a notification instruction signal to the first notification circuit 14. Accordingly, the first notification circuit 14 is in a notification state. As a result, as shown in FIG. 2, when the state number is “8”, the first notification circuit 14 is in the notification state and the second notification circuit 24 is in the unknown state.

As described above, this embodiment has the following effects.
(1) According to the present embodiment, the abnormality detection device 1 includes the first circuit 4, the second circuit 25, and the second notification circuit 24. The first circuit 4 is installed on the first substrate 2, and the second circuit 25 and the second notification circuit 24 are installed on the second substrate 3. The first circuit 4 and the second notification circuit 24 are connected via the first wiring 13. The first circuit 4 and the second circuit 25 are connected via the second wiring 17. The second circuit 25 and the second notification circuit 24 are connected via a third wiring 27.

  When the first circuit 4 becomes abnormal, the second circuit 25 detects the abnormality of the first circuit 4 and outputs an instruction signal to notify the second notification circuit 24 via the third wiring 27. This instruction signal is a signal for bringing the voltage of the second control terminal 32c close to the first voltage. When the second circuit 25 becomes abnormal, the first circuit 4 detects an abnormality of the second circuit 25 and outputs an instruction signal to notify the second notification circuit 24 via the first wiring 13. This instruction signal is a signal for bringing the voltage of the second terminal 12 close to the second voltage.

  Since the first wiring 13 and the second wiring 17 are wirings connecting the first substrate 2 and the second substrate 3, they are easily damaged physically. When the second wiring 17 is disconnected, the first circuit 4 detects the disconnection of the second wiring 17 and outputs an instruction signal to notify the second notification circuit 24 via the first wiring 13. This instruction signal is a signal for bringing the voltage of the second terminal 12 close to the second voltage. Alternatively, when the second wiring 17 is disconnected, the second circuit 25 detects the disconnection of the second wiring 17 and outputs an instruction signal to notify the second notification circuit 24 via the third wiring 27. This instruction signal is a signal for bringing the voltage of the second control terminal 32c close to the first voltage.

  When the first wiring 13 is disconnected, the second notification circuit 24 detects and notifies the disconnection of the first wiring 13. Therefore, even when the first wiring 13 that connects the first substrate 2 and the second substrate 3 is disconnected, the second notification circuit 24 can notify that the wiring between the substrates is disconnected.

  (2) According to the present embodiment, the second substrate 3 includes the second terminal 12 and the second power source 23. A first wiring 13 is connected to the second terminal 12, and a first voltage is supplied to the second terminal 12 through the first wiring 13. The second terminal 12 is connected to the second notification circuit 24 and supplies the first voltage to the second notification circuit 24.

  The second power source 23 is connected to the second terminal 12 via the second resistor 26 and supplies the second voltage to the second terminal 12. When the first wiring 13 is connected to the first substrate 2 and the second substrate 3, the voltage supplied from the second power source 23 is changed by the current flowing through the second resistor 26, and thus the voltage at the second terminal 12. Becomes close to the first voltage.

  When the first wiring 13 is disconnected, the first voltage is not supplied to the second terminal 12, so that the voltage at the second terminal 12 becomes close to the second voltage. The second notification circuit 24 does not notify when the voltage of the second terminal 12 is close to the first voltage, and notifies when the voltage of the second terminal 12 is close to the second voltage. Therefore, when the first wiring 13 is disconnected, the second notification circuit 24 can notify that the first wiring 13 is disconnected.

  (3) According to the present embodiment, the first substrate 2 includes the first terminal 11 and the first power supply 7. A first wiring 13 is connected to the first terminal 11, and the first terminal 11 is connected to the first circuit 4. The first power supply 7 is connected to the first terminal 11 via the first resistor 10 and supplies the first voltage to the first terminal 11.

  The first circuit 4 includes a switching element 6 connected to the first terminal 11. The switching element 6 switches whether to supply the second voltage to the first terminal 11. When the switching element 6 supplies the second voltage to the first terminal 11, the voltage at the second terminal 12 becomes the second voltage. Accordingly, the first circuit 4 can notify the second notification circuit 24.

  When the switching element 6 does not supply the second voltage to the first terminal 11, the first wiring 13 can supply a voltage close to the first voltage to the second terminal 12 because the second resistor 26 is higher than the first resistor 10. Therefore, when the first wiring 13 is not disconnected, the first circuit 4 can control the notification of the second notification circuit 24.

  (4) According to the present embodiment, the second power supply 23 supplies power to the second notification circuit 24. A first notification circuit 14 is installed on the first substrate 2. The first notification circuit 14 is connected to the first circuit 4 and receives a notification instruction signal from the first circuit 4 for notification.

  When the second power source 23 breaks down, the second notification circuit 24 becomes inoperable. At this time, the first circuit 4 detects an abnormality of the second power supply 23. Then, the first circuit 4 outputs a notification instruction signal to the first notification circuit 14. Therefore, even when the second power supply 23 that supplies power to the second notification circuit 24 fails, the first notification circuit 14 can notify the failure of the second power supply 23.

(Second Embodiment)
Next, an embodiment of the liquid ejecting apparatus in which the abnormality detecting device is installed will be described with reference to a block diagram showing the configuration of the liquid ejecting apparatus in FIG. This embodiment is different from the first embodiment in that the abnormality detection device is installed in the liquid ejecting apparatus. Note that description of the same points as in the first embodiment is omitted.

  In the present embodiment, as shown in FIG. 3, the liquid ejecting apparatus 36 includes a hand piece 37. The liquid ejecting apparatus 36 is a medical device, and the handpiece 37 is an instrument that an operator holds and operates when performing an operation. The handpiece 37 is provided with an ejection pipe 38 that is a fluid flow path. A nozzle portion 39 for ejecting fluid is installed at one end of the ejection pipe 38. A pulsating flow generation unit 40 is installed at the other end of the injection pipe 38. A filter 42, a tube detection sensor 43, and a tube pump 44 are connected to the pulsating flow generation unit 40 via a tube 41 in this order. Further, the tube pump 44 is connected to the pack 45 via the tube 41. The liquid ejecting apparatus 36 includes an ejection control unit 46 that controls the liquid ejecting apparatus 36. The ejection control unit 46 is connected to the tube pump 44, the tube detection sensor 43, and the pulsating flow generation unit 40 through a wiring 47 and controls the operation of the liquid ejection device 36.

  A liquid 48 is installed inside the pack 45, and the liquid 48 is supplied to the tube pump 44. The tube pump 44 is a type of pump that moves the liquid 48 in the tube 41 by pushing the tube 41 from the outside. The tube pump 44 can cause the liquid 48 to flow continuously.

  The tube detection sensor 43 measures the flow rate of the fluid flowing through the tube 41. Then, the tube detection sensor 43 detects whether or not the flow paths in the tube 41 and the handpiece 37 are closed, and whether or not the tube is properly set with respect to the tube detection sensor 43.

  The filter 42 has a function of removing foreign matters, bacteria, bubbles and the like in the liquid 48. The pulsating flow generation unit 40 is a part that generates a pulsating flow in the flow of the liquid 48 that passes therethrough.

  A main switch 49 is installed in the injection control unit 46. In addition, an injection switch 50 (foot switch) and the like are connected to the injection control unit 46 via a wiring cord. The main switch 49 is a switch that activates the liquid ejecting apparatus 36. When the main switch 49 is turned on, electric power is supplied to the injection control unit 46. The ejection switch 50 is a switch for switching between ejection and non-ejection of fluid from the nozzle portion 39. The injection switch 50 is a switch that is operated by an operator by stepping on the foot.

  When the surgeon turns on the main switch 49, the injection control unit 46 is activated. After the ejection control unit 46 is activated, initial setting processes such as an inspection process and a liquid filling process before the start of use are executed. When the operator turns on the injection switch 50 after the initial setting process is completed, the tube pump 44 is activated and the liquid 48 advances inside the tube 41.

  The fluid traveling through the tube 41 passes through the filter 42. The filter 42 removes dust, bubbles, salt crystals, and the like from the liquid 48. The liquid 48 that has reached the pulsating flow generation unit 40 is pulsated by the pulsating flow generation unit 40. The liquid 48 that has passed through the pulsating flow generation unit 40 passes through the ejection pipe 38 and is ejected from the nozzle unit 39. Since the pulsation is applied to the liquid 48 that has passed through the pulsating flow generation unit 40, the liquid 48 ejected from the nozzle unit 39 is a pulsating flow that is a pulsed fluid. The surgeon sprays the pulsed liquid 48 onto the living tissue, so that the living tissue can be incised, excised, peeled off, and the like.

  The injection control unit 46 is provided with the abnormality detection device 1 described in the first embodiment. The abnormality detection apparatus 1 is provided with a first substrate 2 and a second substrate 3. Circuits such as the first circuit 4 and the first notification circuit 14 are installed on the first substrate 2. A second notification circuit 24 and a second circuit 25 are installed on the second substrate 3.

  The first substrate 2 and the second substrate 3 are connected by wiring such as the first wiring 13, the second wiring 17, and the ground wiring 22. Then, when a failure occurs in the circuits such as the first circuit 4 and the second circuit 25, the abnormality detection device 1 notifies an alarm.

  Further, when the first wiring 13 is disconnected, the second notification circuit 24 detects and notifies the disconnection of the first wiring 13. Therefore, even when the first wiring 13 that connects the first substrate 2 and the second substrate 3 is disconnected, the second notification circuit 24 can notify that the wiring between the substrates is disconnected.

As described above, this embodiment has the following effects.
(1) According to this embodiment, the liquid ejecting apparatus 36 ejects the liquid 48 from the nozzle portion 39. The liquid ejecting apparatus 36 includes an ejection control unit 46, and the ejection control unit 46 controls ejection of the liquid 48. The injection control unit 46 includes the abnormality detection device 1 described in the first embodiment. In the abnormality detection device 1 described in the first embodiment, even when the first wiring 13 that connects the first substrate 2 and the second substrate 3 is disconnected, the second notification circuit 24 disconnects the wiring between the substrates. Can be notified. Accordingly, the liquid ejecting apparatus 36 can notify that the wiring between the substrates is disconnected even when the first wiring 13 connecting the first substrate 2 and the second substrate 3 is disconnected. 1 can be provided.

Note that the present embodiment is not limited to the above-described embodiment, and various changes and improvements can be added by those having ordinary knowledge in the art within the technical idea of the present invention. A modification will be described below.
(Modification 1)
In the first embodiment, the voltage of the first terminal 11 is connected to the first voltage via the first resistor 10 in the first substrate 2. Then, the second substrate 3 was connected to the second voltage via the second resistor 26. By changing the characteristics of the switching element 6 and the first switch 30, the voltage of the first terminal 11 may be connected to the second voltage via the first resistor 10 in the first substrate 2. Then, the second substrate 3 may be connected to the first voltage via the second resistor 26. A circuit configuration that facilitates circuit design can be selected.

(Modification 2)
In the first embodiment, the warning lamp 28 and the buzzer 29 are arranged inside the second notification circuit 24. The warning lamp 28 and the buzzer 29 may be installed outside the second substrate 3. Then, the warning lamp 28 and the buzzer 29 may be connected to the second substrate 3 by wiring and controlled. It is possible to easily design a layout in which the warning light 28 and the buzzer 29 are arranged.

(Modification 3)
In the first embodiment, the abnormality detection device 1 is configured by the first substrate 2 and the second substrate 3. Not limited to this, the abnormality detection apparatus 1 may be configured by three or more circuit boards. Also at this time, the disconnection of the wiring connecting each substrate may be detected and notified.

(Modification 4)
In the first embodiment, the electric circuit is configured by combining electric elements such as the switching element 6 and the first switch 30. In addition, the abnormality detection apparatus 1 may be configured by a CPU (Central Processing Unit) and a program. In addition, an electrical circuit may be configured using an ASIC (application specific integrated circuit). The mounting process can be facilitated.

(Modification 5)
In the second embodiment, the example in which the abnormality detection device 1 is installed in the liquid ejecting apparatus 36 as an example of a medical device has been described. The abnormality detection device 1 can be used for various electronic devices and medical devices other than the liquid ejecting device 36. For example, the abnormality detection apparatus 1 can be used in an ultrasonic measurement apparatus that transmits ultrasonic waves, receives reflected waves, and forms an ultrasonic image. In addition, it can be used in a control unit of an apparatus for culturing nucleic acids. Also at this time, when the wiring between the substrates is disconnected, the disconnection of the wiring can be detected and notified.

  DESCRIPTION OF SYMBOLS 1 ... Abnormality detection apparatus, 2 ... 1st board | substrate, 3 ... 2nd board | substrate, 4 ... 1st circuit, 6 ... Switching element, 7 ... 1st power supply, 10 ... 1st resistance, 11 ... 1st terminal, 12 ... 1st 2 terminals, 13 ... 1st wiring, 14 ... 1st information circuit, 17 ... 2nd wiring, 23 ... 2nd power supply, 24 ... 2nd information circuit, 25 ... 2nd circuit, 26 ... 2nd resistance, 27 ... 1st 3 wirings, 36... Liquid ejection device, 46.

Claims (5)

A first circuit installed on a first substrate;
A second notification circuit connected to the first circuit via a first wiring and installed on a second substrate;
A second circuit connected to the first circuit via a second wiring and installed on the second substrate,
The second circuit and the second notification circuit are connected via a third wiring,
The abnormality detection device, wherein the second notification circuit detects and notifies the disconnection of the first wiring. The abnormality detection apparatus according to claim 1,
The second substrate has a second terminal connected to the second notification circuit to which the first wiring is connected;
A second power source connected to the second terminal via a second resistor and supplying a second voltage to the second terminal;
A first voltage different from the second voltage is supplied to the second terminal by the first wiring,
The abnormality detection device, wherein the second notification circuit does not notify when the voltage of the second terminal is the first voltage, and notifies when the voltage of the second terminal is the second voltage. The abnormality detection apparatus according to claim 2,
The first substrate has a first terminal to which the first wiring is connected and connected to the first circuit;
A first power source connected to the first terminal via a first resistor to supply the first voltage to the first terminal and to supply the second voltage to the first circuit;
The first circuit includes a switching element that is connected to the first terminal and switches whether to supply the second voltage to the first terminal;
The abnormality detection device, wherein a resistance value of the second resistor is higher than a resistance value of the first resistor. The abnormality detection device according to claim 2 or 3,
The second power supply supplies power to the second notification circuit;
A first notification circuit that is connected to the first circuit and inputs a notification instruction signal for notification is installed on the first substrate,
The abnormality detection device, wherein the first circuit detects an abnormality of the second power supply and outputs the notification instruction signal to the first notification circuit. A liquid ejecting apparatus that ejects liquid from a nozzle part,
An ejection control unit that controls ejection of the liquid;
The liquid ejection device, wherein the ejection control unit includes the abnormality detection device according to any one of claims 1 to 4.

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