JP7561061B2 - Sockets - Google Patents

Description

The present disclosure relates generally to electrical outlets. More particularly, the present disclosure relates to electrical outlets to which a plug of a load appliance is connected.

The wiring device (outlet) described in Patent Document 1 includes a device body, a temperature detection unit, and a control unit. The temperature detection unit detects the temperature corresponding to the power supply path within the device body. The control unit also makes a judgment based on the temperature detected by the temperature detection unit, and performs at least one of cutting off the power supply path and providing a notification regarding the temperature depending on the result of the judgment.

JP 2020-089198 A

The outlet in Patent Document 1 determines whether there is an abnormal temperature rise based on the temperature of the power supply path detected by a temperature detection unit. However, if tracking occurs on the surface of the outlet, the absolute amount of heat generated by tracking is small, and the temperature rise detected by the temperature detection unit located inside the device body is small, so there is a possibility that tracking will go undetected.

The objective of this disclosure is to provide an outlet that can reduce tracking detection misses.

The outlet according to one aspect of the present disclosure includes a plurality of load terminals, a plurality of power terminals, a plurality of power supply paths, a first temperature detection unit, a second temperature detection unit, and an abnormality detection unit. A plurality of contacts of a plug of a load appliance are connected to the plurality of load terminals. A plurality of power supply lines from an external power source are connected to the plurality of power terminals. The plurality of power supply paths respectively connect between the plurality of load terminals and the plurality of power terminals. The first temperature detection unit measures a power terminal temperature of at least one of the plurality of power terminals. The second temperature detection unit measures a load terminal temperature of at least one of the plurality of load terminals. The abnormality detection unit detects the presence or absence of tracking based on the magnitude of a difference value between the load terminal temperature and the power terminal temperature. The second temperature detection unit measures the temperature at each of the plurality of load terminals. The abnormality detection unit detects that tracking has occurred if a first difference value, which is the difference between a first load terminal temperature that is equal to or greater than the median value among the temperatures of the multiple load terminals measured by the second temperature detection unit, and the power supply terminal temperature, is equal to or greater than a first threshold value, and a second difference value, which is the difference between a second load terminal temperature that is less than the median value among the temperatures of the multiple load terminals, and the power supply terminal temperature, is equal to or greater than a second threshold value that is smaller than the first threshold value.

This disclosure can reduce tracking detection misses.

FIG. 1 is a block diagram illustrating a configuration of an outlet according to an embodiment of the present disclosure. FIG. 2 is an exploded perspective view of the outlet. FIG. 3 is a perspective view showing an example of use of the outlet when the opening/closing part is in a conductive state. FIG. 4 is a perspective view showing an example of use of the outlet when the opening/closing part is in a cut-off state. FIG. 5 is a front view of the outlet with the outer and inner covers removed. FIG. 6 is a rear view of the outlet with the outer and inner covers removed. FIG. 7 is a schematic cross-sectional view showing the configuration of a main part of the outlet, which corresponds to the cross section taken along line X1-X1 in FIG. FIG. 8 is a schematic cross-sectional view showing the configuration of a main part of the outlet, taken along line X2-X2 of FIG. FIG. 9 is a schematic cross-sectional view showing the configuration of the main part of the outlet, which corresponds to the cross section taken along line Z1-Z1 in FIG. FIG. 10 is a flow chart for explaining the operation of the outlet. FIG. 11 is a graph showing an example of temperature change characteristics when tracking occurs in the load terminal and the power terminal of the outlet. FIG. 12 is a graph illustrating the detection operation of the abnormality detection unit included in the outlet.

The embodiment and modified examples described below are merely examples of the present disclosure, and the present disclosure is not limited to the embodiment and modified examples. Various modifications other than the embodiment and modified examples may be made according to the design, etc., as long as they do not deviate from the technical concept of the present disclosure.

(Embodiment)
(1) Overview First, an overview of the outlet 1 of the present embodiment will be described with reference to FIGS. 1, 2 and 7. FIG.

The outlet 1 of this embodiment includes a plurality of load terminals 3, a plurality of power terminals 4, a plurality of power supply paths L1, a first temperature detection unit 91, a second temperature detection unit 92, and an abnormality detection unit 101. A plurality of contacts 211 of the plug 21 of the load appliance 2 are connected to the plurality of load terminals 3, respectively. A plurality of power supply lines 51 from an external power source 5 are connected to the plurality of power terminals 4, respectively. A plurality of power supply paths L1 connect between the plurality of load terminals 3 and the plurality of power terminals 4, respectively. The first temperature detection unit 91 measures the power terminal temperature of at least one of the plurality of power terminals 4. The second temperature detection unit 92 measures the load terminal temperature of at least one of the plurality of load terminals 3. The abnormality detection unit 101 detects the presence or absence of tracking based on the magnitude of the difference value between the load terminal temperature and the power terminal temperature.

When tracking occurs at the load terminal 3 while the plug 21 is degraded, the amount of heat generated by tracking is relatively small, so the temperature rise at the load terminal is about 30°C. However, as shown in Figure 11, a temperature difference occurs between the load terminal temperature and the power supply terminal temperature that exceeds a predetermined threshold.

In this embodiment, the abnormality detection unit 101 detects the presence or absence of tracking based on the magnitude of the difference between the load terminal temperature and the power supply terminal temperature, and by detecting the temperature difference caused by tracking, it becomes easier to detect the occurrence of tracking. Therefore, according to this embodiment, it is possible to reduce the possibility of missing tracking detection. In addition, since the power supply terminal temperature changes depending on the ambient temperature of the outlet 1, the abnormality detection unit 101 detects the presence or absence of tracking based on the magnitude of the difference between the load terminal temperature and the power supply terminal temperature, thereby reducing the possibility of erroneously detecting ambient temperature changes as tracking.

The outlet 1 of this embodiment is installed, for example, in a residential facility such as a detached house or an apartment building, or in a non-residential facility such as an office, a store, a school, or a nursing home. The outlet 1 is installed, for example, on a construction surface 100 such as a wall surface of a facility (building) (see Figures 3 and 4). The outlet 1 may also be installed on a construction surface such as a ceiling surface or a floor surface. Furthermore, the outlet 1 is not limited to being installed on a construction surface, and may be attached to a fixture such as a desk, or may be used while placed on a support surface (for example, a floor surface).

(2) Details The outlet 1 according to this embodiment will be described in more detail below with reference to FIGS. 1 to 12.

(2.1) Overall configuration The outlet 1 includes a first connection portion 8 (FIG. 1), a second connection portion 17, a temperature measurement portion 9 (including a first temperature detection portion 91 and a second temperature detection portion 92), a processing portion 10, a notification portion 11, an opening/closing portion 12, an operating member 13, a switch 16, and a power supply circuit 22.

An electric wire W1 is connected to the first connection part 8 from an external power source 5, which is an AC power source such as a commercial AC power source (e.g., AC 100/200V, 50/60Hz). The electric wire W1 includes two power feed lines 51, L pole (Live) and N pole (Neutral), and an earth wire 78. Therefore, the first connection part 8 includes two power supply terminals 4 to which the two power feed lines 51 are respectively connected, and an earth terminal 7 to which the earth wire 78 is connected.

The second connection part 17 can be connected to three contacts 210 provided on the plug 21 of the load device 2. The three contacts 210 include two contacts 211 for the L pole and the N pole, and a contact 212 for earthing. The contacts 211 for the L pole and the N pole are formed in a long and thin plate shape, and the contact 212 for earthing is formed in a round bar shape. Therefore, the second connection part 17 includes two load terminals 3 to which the two contacts 211 for the L pole and the N pole are respectively connected, and one earth pin terminal 19 to which the contact 212 for earthing is connected. Note that the outlet 1 of this embodiment includes two load terminals 3 and two power terminals 4, but the number of each of the load terminals 3 and the power terminals 4 is not limited to two, and may be three or more.

The two power supply terminals 4 of the first connection part 8 and the two load terminals 3 of the second connection part 17 are electrically connected via the power supply path L1. The earth terminal 7 of the first connection part 8 and the earth pin terminal 19 of the second connection part 17 are electrically connected via a conductive member 77. Therefore, when the electric wire W1 from the external power source 5 is connected to the first connection part 8 and the plug 21 of the load device 2 is connected to the second connection part 17, power is supplied from the external power source 5 to the load device 2 via the outlet 1.

As shown in Figs. 2 to 9, the outlet 1 has internal components such as a load terminal 3, a power terminal 4, and a power supply line L1, and a housing 1A that holds the internal components. The housing 1A further holds a temperature measuring unit 9, a processing unit 10, a notification unit 11, an opening/closing unit 12, an operating member 13, and a switch 16.

The opening/closing unit 12 has two contacts electrically connected between the two load terminals 3 and the two power supply terminals 4, respectively, and an opening/closing circuit that opens the two contacts in response to a shutoff command from the control unit 102. Here, the opening/closing unit 12 is a latching relay having two contacts, and the two contacts are normally-on contacts. Therefore, when no shutoff command is input from the control unit 102, the two contacts are conductive. On the other hand, when a shutoff command is input from the control unit 102, the opening/closing unit 12 opens the two contacts, and the two contacts are held in an open state. When the two contacts are opened, the power supply from the external power source 5 to the load appliance 2 is shut off.

The operating member 13 is for manually closing the two contacts that are in an open state. When the two contacts of the opening/closing unit 12 are switched to a cut-off state by a cut-off command from the control unit 102, the user can resume the power supply to the load device 2 by closing the two contacts using the operating member 13 after the abnormal state is resolved.

The notification unit 11 notifies the detection result of the abnormality detection unit 101. The notification unit 11 includes a display unit 14 that notifies by turning on an LED or the like, and a buzzer 15 that notifies by sound. The display unit 14 may include a display device that notifies by displaying characters or symbols on a screen. The notification unit 11 may also notify by outputting an alarm sound or a voice message from a speaker. The notification unit 11 may also transmit the detection result of the abnormality detection unit 101 to an external display terminal (for example, a terminal or smartphone installed in a facility) to display the detection result of the abnormality detection unit 101 on a display device of the terminal device, or output the detection result of the abnormality detection unit 101 as sound or the like from the speaker of the terminal device.

The switch 16 is provided to accept an operation to stop the notification process of the notification unit 11. When the switch 16 accepts a user operation, it outputs an operation signal to the control unit 102.

The temperature measurement unit 9 measures the temperatures of the multiple measurement sites P1 to P4. In this embodiment, the temperature measurement unit 9 includes two first temperature detection units 91 and two second temperature detection units 92. The two first temperature detection units 91 detect the temperature at the two measurement sites P1 and P2 corresponding to the two power terminals 4, respectively, and output the detection results to the abnormality detection unit 101. The two second temperature detection units 92 detect the temperature at the two measurement sites P3 and P4 corresponding to the two load terminals 3, respectively, and output the detection results to the abnormality detection unit 101. The two first temperature detection units 91 and the two second temperature detection units 92 are realized, for example, by thermistors, thermocouples, or thermopiles. The detection signals output by the first temperature detection unit 91 and the second temperature detection unit 92 may be electrical signals that convey temperature information, and are, for example, signals such as resistance values, voltage values, or current values that change according to the temperature information (temperature measurement results).

Each of the two load terminals 3 has a holding portion 96 (see FIG. 7) formed in a C-shape when viewed from the side. A block-shaped second temperature detection portion 92 is held by this holding portion 96, and the second temperature detection portion 92 is thermally coupled to the load terminal 3 to be detected. As shown in FIG. 8, the power supply terminal 4 is mounted on one surface (e.g., the rear surface) of the substrate 6. The first temperature detection portion 91 is mounted on one surface (the rear surface) of the substrate 6 so as to be positioned between the power supply terminal 4 to be detected and the substrate 6, and the first temperature detection portion 91 is thermally coupled to the load terminal 3 to be detected.

In the following embodiments, of the two first temperature detection units 91, the first temperature detection unit that detects the temperature of the power terminal 4 on the L pole side at measurement site P1 may be referred to as the first temperature detection unit 911, and the first temperature detection unit that detects the temperature of the power terminal 4 on the N pole side at measurement site P2 may be referred to as the first temperature detection unit 912. Also, of the two second temperature detection units 92, the second temperature detection unit that detects the temperature of the load terminal 3 on the L pole side at measurement site P3 may be referred to as the second temperature detection unit 921, and the second temperature detection unit that detects the temperature of the load terminal 3 on the N pole side at measurement site P4 may be referred to as the second temperature detection unit 922.

The processing unit 10 has, for example, a computer system having a processor and a memory. The processor executes a program stored in the memory, causing the computer system to function as the processing unit 10. The program executed by the processor is pre-recorded in the memory of the computer system here, but may also be provided by being recorded on a recording medium such as a memory card, or may be provided via a telecommunications line such as the Internet.

The processing unit 10 has the functions of the abnormality detection unit 101 and the control unit 102 described above. The processing unit 10 is mounted on, for example, a control board 23 (see FIG. 7) disposed behind the first inner body 184.

The anomaly detection unit 101 detects whether tracking is occurring based on the measurement results of the temperature measurement unit 9. The detection operation of the anomaly detection unit 101 will be explained in detail in "(2.2) Operation Description".

When the abnormality detection unit 101 detects the occurrence of tracking, the control unit 102 outputs a cut-off command to the opening/closing unit 12 to cut off the power supply line L1. In other words, the outlet 1 further includes an opening/closing unit 12 that cuts off the power supply line L1 when the abnormality detection unit 101 detects the occurrence of tracking. When the abnormality detection unit 101 detects the occurrence of tracking, the control unit 102 outputs a notification command to the notification unit 11 to instruct the notification unit 11 to notify the abnormality detection unit 101 of the detection result. When the notification unit 11 receives the notification command, the notification unit 11 performs notification processing to notify the occurrence of tracking. When an operation signal is input from the switch 16 to the control unit 102 while the notification unit 11 is performing notification, the control unit 102 outputs a stop command to the notification unit 11, and the notification unit 11 that receives the stop command stops the notification processing.

The power supply circuit 22 converts the AC voltage input from the external power supply 5 into a DC voltage of a predetermined voltage value and supplies it to the processing unit 10, the temperature measurement unit 9, etc.

3 and 4 are perspective views of the outlet 1 attached to the construction surface 100. In this embodiment, the outlet 1 is a recessed outlet that is attached to the mounting frame of a large rectangular multi-purpose outlet standardized by the Japanese Industrial Standards, for example. Specifically, the outlet 1 is attached to the construction surface 100 via the mounting frame. Here, the mounting frame is fixed to the construction surface 100 via a recessed box or directly. In other words, the mounting frame is fixed to the construction surface 100, and the outlet 1 is attached to the construction surface 100 via the mounting frame. A decorative plate 111 is attached to the mounting frame, and as shown in Figs. 3 and 4, the front surface of the outlet 1 is exposed from an opening window 112 on the front surface of the decorative plate 111. Here, the mounting frame may be a separate member from the outlet 1, or may be a single member. In this embodiment, the case where the outlet 1 is for indoor use, that is, the construction surface 100 is the inner wall surface of a building (facility), will be described, but this example is not limited to this, and the outlet 1 may be for outdoor use.

In the following, the direction perpendicular to the horizontal plane when the outlet 1 is attached to the inner wall surface of the building, which is the construction surface 100, is referred to as the "up-down direction", and the bottom (vertical direction) when the outlet 1 is viewed from the front is referred to as the "bottom" of the outlet 1. Also, the direction perpendicular to the up-down direction and parallel to the construction surface 100 is referred to as the "left-right direction", and the right side when the outlet 1 is viewed from the front is referred to as the "right" of the outlet 1. Furthermore, the direction perpendicular to both the up-down direction and the left-right direction, that is, the direction perpendicular to the construction surface 100, is referred to as the "front-rear direction", and the back side of the construction surface 100 (back side of the wall) is referred to as the "rear". However, these directions are not intended to limit the direction in which the outlet 1 is used. In this disclosure, "vertical" may include not only completely vertical, but also a state inclined within a predetermined error range (for example, about several degrees) from the vertical direction. In this disclosure, "parallel" may include not only completely parallel, but also a state inclined within a predetermined error range from the parallel state.

In this embodiment, a single-port outlet 1 that can connect one plug 21 (see FIG. 7) is illustrated. That is, the outlet 1 has one connection port 170 that corresponds to the contacts 211, 212 of one plug 21.

The connection port 170 is located on the front of the outlet 1. The connection port 170 is compatible with a two-pole earthed plug 21 having contacts 211 for the left and right poles and a contact 212 for earthing, and has two plug blade insertion holes 171 and one earth pin insertion hole 172 (see Figures 2 to 4).

The second connection part 17 of the outlet 1 includes a pair of load terminals 3 and an earth pin terminal 19, which are of opposite polarity. The L-side contact 211 is connected to one of the pair of load terminals 3, and the N-side contact 211 is connected to the other of the pair of load terminals 3. The first connection part 8 of the outlet 1 includes a pair of power terminals 4 and an earth terminal 7, which are of opposite polarity. The L-side power supply line 51 is connected to one of the pair of power terminals 4, and the N-side power supply line 51 is connected to the other of the pair of power terminals 4. The earth terminal 7 is connected to an earth wire 78. The load terminal 3 and the power terminal 4, which are of the same polarity, are electrically connected to each other by the power supply path L1 via the opening/closing part 12. The earth terminal 7 and the earth pin terminal 19 are electrically connected to each other via a conductive member 77.

As shown in FIG. 2, the housing 1A has an outer body 181, an outer cover 182, an inner cover 183, a first inner body 184, and a second inner body 185. Here, the outer body 181, the outer cover 182, the inner cover 183, the first inner body 184, and the second inner body 185 are made of an insulating material such as a synthetic resin.

The outer body 181 is formed in a box shape with an opening on the front. The opening surface (front) of the outer body 181 is rectangular in shape with the vertical dimension longer than the horizontal dimension. The first inner body 184 is housed in the outer body 181 together with other internal parts (power terminal 4, opening/closing part 12, etc.) while holding the load terminal 3 and the earth pin terminal 19. The second inner body 185 is housed in the outer body 181 together with other internal parts while holding the power terminal 4 and the earth terminal 7, as shown in Figures 2, 8 and 9. The inner cover 183 is attached to the front of the outer body 181. As a result, the internal parts including the load terminal 3 and the earth pin terminal 19 held by the first inner body 184, and the power terminal 4 and the earth terminal 7 held by the second inner body 185 are housed between the outer body 181 and the inner cover 183. The outer cover 182 is attached to the front of the inner cover 183. As a result, the load terminal 3, earth pin terminal 19, power terminal 4, and earth terminal 7 are housed between the first inner body 184 and the outer cover 182, and the front of the first inner body 184 and the second inner body 185 is covered by the outer cover 182. Here, an opening window 183A that penetrates in the front-rear direction is formed in the inner cover 183 at the portion corresponding to the load terminal 3, earth pin terminal 19, and earth terminal 7. Therefore, when the outer cover 182 is removed, the load terminal 3, earth pin terminal 19, and earth terminal 7 are exposed to the front through the opening window 183A.

Furthermore, in this embodiment, the outer cover 182 is configured to be divisible into multiple members (e.g., three members: a first portion 182A, a second portion 182B, and an earth cover 182C).

The first portion 182A of the outer cover 182, which covers the first inner body 184, is provided with the above-mentioned one connection port 170. The connection port 170 has a pair of blade insertion holes 171 and an earth pin insertion hole 172, as described above. The first portion 182A is provided with an earth lid 182C below the first connection portion 8. Inside the housing 1A, the load terminals 3 are arranged at positions corresponding to the pair of blade insertion holes 171, the earth pin terminal 19 is arranged at a position corresponding to the earth pin insertion hole 172, and the earth terminal 7 is arranged at a position corresponding to the earth lid 182C. Here, the earth pin terminal 19 and the earth terminal 7 are electrically connected. The earth pin terminal 19 is a spring member to which the contact 212 of the plug 21 is connected. The earth terminal 7 is provided with a first earth terminal 71 (see Figures 2 and 5) to which the earth wire of the load device 2 is connected on the side facing the earth lid 182C. The earth terminal 7 also includes a second earth terminal 72 (see FIG. 6) to which the earth wire 78 of the external power source 5 is connected.

In addition, the opening/closing unit 12 and the board 20 are housed in the space between the outer body 181 and the inner cover 183 to the left of the first inner body 184. The board 20 is disposed above the opening/closing unit 12. The board 20 is mounted with the first indicator light 141 and the second indicator light 142 constituting the display unit 14, the switch 16, and the like. As an example, the first indicator light 141 and the second indicator light 142 are LEDs (Light Emitting Diodes) that emit light of different colors, and the switch 16 is a push button switch. In addition, the inner cover 183 is formed with a light-transmitting window hole 183C and a cantilever 183D so that the light of the display unit 14 can be seen from the front of the outlet 1 and the switch 16 can be pressed from the front of the outlet 1. The outer cover 182 is provided with a window 182E for making the light of the first indicator light 141 and the second indicator light 142 visible from the front, and a through hole 182F for pressing the switch 16. That is, the light of the display unit 14 is visible from the front of the outlet 1 through the window 183C and the window 182E. By pressing the cantilever 183D from the front of the outlet 1 through the through hole 182F, the switch 16 can be indirectly pressed via the cantilever 183D. For convenience, in FIG. 3 and FIG. 4, the symbols for the display unit 14 and the switch 16 are attached to the positions on the front of the outlet 1 that correspond to the display unit 14 (the first indicator light 141 and the second indicator light 142) and the switch 16.

In this embodiment, the two load terminals 3 of the outlet 1 are held by the first inner body 184, as shown in Figs. 5 and 7. The first inner body 184 also holds an earth pin terminal 19. Here, the pair of load terminals 3 are arranged at positions corresponding to a pair of blade insertion holes 171 formed in the outer cover 182. The earth pin terminal 19 is arranged at a position corresponding to the earth pin insertion hole 172 formed in the outer cover 182.

The load terminal 3 is a prong receiving member into which the L-pole and N-pole contacts 211 of the plug 21 are inserted. The earth pin terminal 19 is a spring member into which the earth contact 212 of the plug 21 is inserted. The load terminal 3 and the earth pin terminal 19 are made of a metal that is conductive and elastic, such as copper or a copper alloy. The load terminal 3 is electrically connected to the contact 211 and mechanically holds the contact 211. The earth pin terminal 19 is electrically connected to the contact 212 and mechanically holds the contact 212.

As shown in Figs. 6 and 8, the pair of power terminals 4 are held by the second inner body 185. Also, as shown in Fig. 5, the second inner body 185 holds the earth terminal 7. Here, the pair of power terminals 4 are arranged at positions corresponding to the pair of power terminal holes 185A formed on the rear surface of the second inner body 185. The earth terminal 7 is formed integrally with the earth pin terminal 19. The earth terminal 7 is arranged at a position corresponding to the earth terminal hole 185B formed on the rear surface of the second inner body 185. Each power terminal 4 is a plug-in type quick-connect terminal into which the power supply line 51 is connected by inserting the core wire 52 of the power supply line 51. Specifically, each power terminal 4 has a terminal plate 41 and a locking spring 42 as shown in Fig. 8. The terminal plate 41 is made of a metal having electrical conductivity, such as copper or a copper alloy. The locking spring 42 is made of a metal having elasticity, such as stainless steel. When the power supply line 51 is inserted into the corresponding power supply terminal hole 185A, each power supply terminal 4 is electrically connected to the power supply line 51 and mechanically holds the power supply line 51 with the core wire 52 of the power supply line 51 sandwiched between the terminal board 41 and the locking spring 42. The terminal board 41 of each power supply terminal 4 is mounted on one surface (e.g., the rear surface 62) of the board 6 on the front side of the outlet 1. Here, each power supply terminal 4 and the board 6 are thermally coupled.

The earth terminal 7 includes a first earth terminal 71 (see Figs. 2 and 5) to which the earth wire of the load device 2 is connected, and a second earth terminal 72 (see Figs. 6 and 9) to which the earth wire 78 of the external power source 5 is connected. The first earth terminal 71 and the second earth terminal 72 include a common base member 73. The first earth terminal 71 includes a retaining member 74 and a screw 75 for fixing the earth wire of the load device 2 to the base member 73, and the second earth terminal 72 includes a locking spring 76 held by the base member 73. The base member 73 is made of a metal having electrical conductivity, such as copper or a copper alloy. The locking spring 76 is made of a metal having elasticity, such as stainless steel. The second earth terminal 72 is a plug-in type quick-connect terminal similar to the power source terminal 4, and is arranged at a position corresponding to the earth terminal hole 185B formed on the rear surface of the second inner body 185. Here, the first earth terminal 71, the second earth terminal 72, and the earth pin terminal 19 are electrically connected. The base member 73 may be provided as a separate member for the first ground terminal 71 and the second ground terminal 72.

(2.2) Operation Description When the outlet 1 of this embodiment is installed on the construction surface 100 and an electric wire W1 from an external power source 5 is connected to the power terminal 4 and the earth terminal 7 of the first connection part 8, the power supply circuit 22 supplies operating voltage to the processing part 10 and the temperature measurement part 9, etc., and the abnormality detection part 101 and the control part 102 of the processing part 10 start operating.

The operation of the processing unit 10 of the outlet 1 will now be described with reference to Figs. 10 to 12. Fig. 11 shows the time changes in temperature T1 of the load terminal 3 on the L pole side, temperature T2 of the load terminal 3 on the N pole side, temperature T3 of the power terminal 4 on the L pole side, temperature T4 of the power terminal 4 on the N pole side, and the difference value ΔT1 when tracking occurs. Note that Fig. 11 shows the temperature changes when a tracking state is simulated by dripping ammonium chloride onto the load terminal 3 every 5 seconds.

The processing unit 10 takes in temperature detection signals from the first temperature detection unit 91 and the second temperature detection unit 92 every time a predetermined measurement period (e.g., 1 second) elapses, and acquires the temperatures T1, T2 of the two load terminals 3 and the temperatures T3, T4 of the two power supply terminals 4 (step ST1). At this time, the abnormality detection unit 101 acquires the detection result of the temperature T1 of the load terminal 3 on the L pole side from the second temperature detection unit 921, acquires the detection result of the temperature T2 of the load terminal 3 on the N pole side from the second temperature detection unit 922, and stores the detection results in memory. In addition, the abnormality detection unit 101 acquires the detection result of the temperature T3 of the power supply terminal 4 on the L pole side from the first temperature detection unit 911, acquires the detection result of the temperature T4 of the power supply terminal 4 on the N pole side from the first temperature detection unit 912, and stores the detection results in memory.

When the abnormality detection unit 101 acquires the temperatures T1 to T4, it determines the maximum value Max(T1, T2) of the temperatures T1, T2 of the two load terminals 3 as the load terminal temperature, and the minimum value Min(T3, T4) of the temperatures T3, T4 of the two power supply terminals 4 as the power supply terminal temperature. Then, the abnormality detection unit 101 calculates the difference value ΔT1 between the load terminal temperature and the power supply terminal temperature (step ST2). Here, the difference value ΔT1 = Max(T1, T2) - Min(T3, T4).

Then, the anomaly detection unit 101 compares the difference value ΔT1 with a predetermined threshold value Tth1 (step ST3).

If the difference value ΔT1 is smaller than the threshold value Tth1 (step ST3: No), the anomaly detection unit 101 determines that tracking is not occurring and terminates the process.

On the other hand, if the difference value ΔT1 is equal to or greater than the threshold value Tth1 (step ST3: Yes), the abnormality detection unit 101 determines that tracking has occurred (including tracking is occurring). Thus, in this embodiment, the second temperature detection unit 92 measures the temperature at each of the multiple load terminals 3. Then, if the difference value ΔT1 between the load terminal temperature, which is any of the temperatures of the multiple load terminals 3 measured by the second temperature detection unit 92, and the power terminal temperature is equal to or greater than the first threshold value Tth1, the abnormality detection unit 101 detects that tracking has occurred. The abnormality detection unit 101 calculates the difference value ΔT1 between the load terminal temperature, which is any of the temperatures of the multiple load terminals 3, and the power terminal temperature, and detects the presence or absence of tracking based on the magnitude of this difference value ΔT1, so that tracking can be detected more reliably even when the outlet 1 has multiple load terminals 3.

The abnormality detection unit 101 obtains a difference value ΔT1 between the load terminal temperature, which is the maximum value among the temperatures T1 and T2 of the multiple load terminals 3, and the power terminal temperature, and compares this difference value ΔT1 with the first threshold value Tth1. In other words, the load terminal temperature is one temperature that is equal to or greater than the median value among the temperatures of the multiple load terminals 3 measured by the second temperature detection unit 92. The median value is, for example, the average value of the multiple load terminal temperatures, but it may also be the median value. The abnormality detection unit 101 detects the presence or absence of tracking based on the temperature of the load terminal 3 at which the difference value ΔT1 between the power terminal temperature and the temperature of the multiple load terminals 3 is the largest, so that it is possible to reduce tracking detection misses.

In this embodiment, the first temperature detection unit 91 detects the temperature at each of the multiple power terminals 4. The abnormality detection unit 101 determines the minimum value of the temperatures T3, T4 of the multiple power terminals 4 measured by the first temperature detection unit 91 as the power terminal temperature, and detects the presence or absence of tracking based on the magnitude of the difference value dT1 between the load terminal temperature and the power terminal temperature. Since the abnormality detection unit 101 determines the difference value ΔT1 using the minimum value of the temperatures T3, T4 of the multiple power terminals 4 as the power terminal temperature, it is possible to determine the change in the load terminal temperature relative to the power terminal temperature, which is close to the ambient temperature of the outlet 1, as the difference value ΔT1, and detect the presence or absence of tracking based on this difference value ΔT1.

When the abnormality detection unit 101 detects the occurrence of tracking, the control unit 102 outputs a cutoff command to the opening/closing unit 12 based on the detection result of the abnormality detection unit 101, and executes a cutoff process to open the two contacts of the opening/closing unit 12 (step ST4). When the two contacts of the opening/closing unit 12 are opened, the power supply from the external power source 5 to the load appliance 2 is cut off. Note that when the two contacts of the opening/closing unit 12 are open, the upper end of the operating member 13 rotates around the axis at the bottom of the operating member 13 and protrudes forward, as shown in FIG. 4.

The control unit 102 also outputs a notification command to the notification unit 11 based on the detection result of the abnormality detection unit 101. When the notification unit 11 receives the notification command from the control unit 102, it performs a notification process to notify the occurrence of tracking (step ST5). In the notification unit 11, the display unit 14 notifies the occurrence of tracking by turning on or blinking at least one of the first indicator light 141 and the second indicator light 142. In other words, the notification unit 11 displays the detection result of the abnormality detection unit 101 on the display unit 14, and the user can visually confirm the detection result of the abnormality detection unit 101. In addition, the notification unit 11 notifies the occurrence of tracking by sounding the buzzer 15, and the user can confirm the detection result of the abnormality detection unit 101 by sound.

When the user who has confirmed the notification from the notification unit 11 presses the switch 16, an operation signal is input from the switch 16 to the control unit 102, and the control unit 102 stops the notification process by the notification unit 11 in response to the operation signal from the switch 16.

In addition, after the user has confirmed the notification from the notification unit 11 and resolved the cause of the tracking, if the user tilts the upper end of the operating member 13 backward until it is flush with the front surface of the housing 1A (the position shown in FIG. 3), the two contacts of the opening/closing unit 12 close and the power supply from the external power source 5 to the load device 2 is resumed.

(3) Modifications The above embodiment is merely one of various embodiments of the present disclosure. The above embodiment can be modified in various ways depending on the design, etc., as long as the object of the present disclosure can be achieved.

Below, we will list some variations of the above embodiment. The variations described below can be applied in appropriate combinations.

The outlet 1 in the present disclosure includes a computer system, for example, in the processing unit 10. The computer system is mainly composed of a processor and a memory as hardware. The processor executes a program recorded in the memory of the computer system, thereby realizing the function of the processing unit 10 in the present disclosure. The program may be pre-recorded in the memory of the computer system, provided through an electric communication line, or provided by recording it in a non-transitory recording medium such as a memory card, an optical disk, or a hard disk drive that can be read by the computer system. The processor of the computer system is composed of one or more electronic circuits including a semiconductor integrated circuit (IC) or a large-scale integrated circuit (LSI). The integrated circuits such as IC or LSI referred to here are called different names depending on the degree of integration, and include integrated circuits called system LSI, VLSI (Very Large Scale Integration), or ULSI (Ultra Large Scale Integration). Furthermore, a field-programmable gate array (FPGA), which is programmed after the manufacture of the LSI, or a logic device capable of reconfiguring the connection relationship inside the LSI or reconfiguring the circuit partition inside the LSI, can also be adopted as a processor. The multiple electronic circuits may be integrated into one chip, or may be distributed across multiple chips. The multiple chips may be integrated into one device, or may be distributed across multiple devices. The computer system referred to here includes a microcontroller having one or more processors and one or more memories. Therefore, the microcontroller is also composed of one or more electronic circuits including a semiconductor integrated circuit or a large-scale integrated circuit.

In the above embodiment, the abnormality detection unit 101 may detect that tracking has occurred if the first difference value ΔT1 is equal to or greater than the first threshold value Tth1 and the second difference value ΔT2 is equal to or greater than the second threshold value Tth2, which is smaller than the first threshold value Tth1. The first difference value ΔT1 is the difference value between one first load terminal temperature that is equal to or greater than the median value among the temperatures of the multiple load terminals 3 and the power terminal temperature. The second difference value ΔT2 is the difference value between one second load terminal temperature that is less than the median value among the temperatures of the multiple load terminals 3 and the power terminal temperature. FIG. 12 shows an example of the measurement results of the temperatures T1 and T2 of the two load terminals 3 and the temperatures T3 and T4 of the two power terminals 4 when tracking has occurred. At time t1, the abnormality detection unit 101 determines the temperature T1 that is equal to or greater than the median value among the temperatures T1 and T2 of the two load terminals 3 as the first load terminal temperature, and the temperature T2 that is less than the median value as the second load terminal temperature. At time t1, the abnormality detection unit 101 determines the temperature T4, which is the lowest value among the temperatures T3 and T4 of the two power terminals 4, as the power terminal temperature. The abnormality detection unit 101 then obtains the difference value between the first load terminal temperature (temperature T1) and the power terminal temperature (temperature T4) as the first difference value ΔT1, and obtains the difference value between the second load terminal temperature (temperature T2) and the power terminal temperature (temperature T4) as the second difference value ΔT2. The abnormality detection unit 101 detects whether tracking has occurred by comparing the first difference value ΔT1 with a first threshold value Tth1 and comparing the second difference value ΔT2 with a second threshold value Tth2. Specifically, the abnormality detection unit 101 detects that tracking has occurred when the first difference value ΔT1 becomes equal to or greater than the first threshold value Tth1 and the second difference value ΔT2 becomes equal to or greater than the second threshold value Tth2. The anomaly detection unit 101 detects that tracking has occurred only when both of these conditions are met, reducing the possibility of tracking being overlooked while also reducing false positives.

It is preferable that the first load terminal temperature is the highest value among the temperatures of the multiple load terminals 3, and the second load terminal temperature is the lowest value among the temperatures of the multiple load terminals 3, thereby suppressing erroneous detection of tracking.

In the above embodiment, when comparing two values such as temperature measurement results, "greater than" may be "greater than or equal to." In other words, whether or not a comparison of two values includes cases where the two values are equal can be changed arbitrarily depending on the setting of a reference value, etc., so there is no technical difference between "greater than" and "greater than or equal to." Similarly, "less than or equal to" may be "less than."

The outlet 1 may also have multiple pairs of load terminals 3 of opposite polarity and multiple first connection parts 8 to which the plugs 21 of the load devices 2 are connected.

(4) Summary As described above, the outlet (1) of the first aspect includes a plurality of load terminals (3), a plurality of power terminals (4), a plurality of power supply paths (L1), a first temperature detection unit (91), a second temperature detection unit (92), and an abnormality detection unit (101). A plurality of contacts (211) of a plug (21) of a load appliance (2) are connected to the plurality of load terminals (3). A plurality of power supply lines (51) from an external power source (5) are connected to the plurality of power supply terminals (4). A plurality of power supply paths (L1) connect between the plurality of load terminals (3) and the plurality of power supply terminals (4). The first temperature detection unit (91) measures the power supply terminal temperature of at least one of the plurality of power supply terminals (4). The second temperature detection unit (92) measures the load terminal temperature of at least one of the plurality of load terminals (3). An abnormality detection unit (101) detects the presence or absence of tracking based on the magnitude of the difference value (ΔT1, ΔT2) between the load terminal temperature and the power supply terminal temperature.

According to this aspect, the anomaly detection unit (101) detects the presence or absence of tracking based on the magnitude of the difference value (ΔT1, ΔT2) between the load terminal temperature and the power supply terminal temperature, so that it becomes easier to detect the presence or absence of tracking even if the temperature rise in the load terminal temperature due to the occurrence of tracking is small. Therefore, it is possible to reduce the missed detection of tracking.

In the second embodiment of the outlet (1), in the first embodiment, the second temperature detection unit (92) measures the temperature at each of the multiple load terminals (3). The abnormality detection unit (101) detects that tracking has occurred if the difference value (ΔT1) between the load terminal temperature, which is at least one of the temperatures of the multiple load terminals (3) measured by the second temperature detection unit (92), and the power terminal temperature is equal to or greater than the first threshold value (Tth1).

This aspect can reduce tracking detection misses.

In the third embodiment of the outlet (1), in the second embodiment, the load terminal temperature is one temperature that is equal to or greater than the median value among the temperatures of the multiple load terminals (3) measured by the second temperature detection unit (92).

This aspect can reduce tracking detection misses.

In the fourth aspect of the outlet (1), in the second aspect, the anomaly detection unit (101) detects that tracking has occurred if the first difference value (ΔT1) is equal to or greater than the first threshold value (Tth1) and the second difference value (ΔT2) is equal to or greater than the second threshold value (Tth2) that is smaller than the first threshold value (Tth1). The first difference value (ΔT1) is the difference value between one first load terminal temperature that is equal to or greater than the median value among the temperatures of the multiple load terminals (3) and the power terminal temperature. The second difference value (ΔT2) is the difference value between one second load terminal temperature that is less than the median value among the temperatures of the multiple load terminals (3) and the power terminal temperature.

This aspect can reduce tracking detection misses.

In the fifth aspect of the outlet (1), in the fourth aspect, the first load terminal temperature is the highest value among the temperatures of the multiple load terminals (3), and the second load terminal temperature is the lowest value among the temperatures of the multiple load terminals (3).

This aspect can reduce tracking detection misses.

In the sixth aspect of the outlet (1), in any of the first to fifth aspects, the first temperature detection unit (91) measures the temperature at each of the multiple power terminals (4). The power terminal temperature is the minimum value of the temperatures of the multiple power terminals (4) measured by the first temperature detection unit (91).

This aspect can reduce tracking detection misses.

The seventh aspect of the outlet (1) is any one of the first to sixth aspects, and further includes an opening/closing unit (12) that cuts off the power supply path (L1) when the abnormality detection unit (101) detects the occurrence of tracking.

According to this embodiment, if tracking occurs, the power supply to the load device (2) can be cut off.

The outlet (1) of the eighth aspect further includes a notification unit (11) that notifies the detection result of the abnormality detection unit (101) in any of the first to seventh aspects.

According to this aspect, the detection result of the anomaly detection unit (101) can be notified to the outside.

The ninth aspect of the outlet (1) is the eighth aspect, in which the notification unit (11) displays the detection result of the abnormality detection unit (101) on the display unit (14).

According to this aspect, the detection result of the anomaly detection unit (101) can be visually notified.

Not limited to the above aspects, various configurations (including modified examples) of the outlet (1) according to the embodiment can be embodied as a control method for the outlet (1), a (computer) program, or a non-transitory recording medium on which a program is recorded, etc.

The configurations according to the second to ninth aspects are not essential to the outlet (1) and may be omitted as appropriate.

Reference Signs List 1 Socket 2 Load device 3 Load terminal 4 Power terminal 5 External power source 11 Notification section 12 Opening/closing section 14 Display section 21 Plug 51 Power supply line 91 First temperature detection section 92 Second temperature detection section 101 Abnormality detection section 210 Contact L1 Power supply path

Claims (6)

a plurality of load terminals to which a plurality of contacts of a plug of a load device are respectively connected;
a plurality of power supply terminals to which a plurality of power supply lines from an external power supply are respectively connected;
a plurality of power supply paths respectively connecting between the plurality of load terminals and the plurality of power supply terminals;
a first temperature detection unit that measures a temperature of at least one of the plurality of power supply terminals;
A second temperature detection unit that measures a load terminal temperature of at least one of the plurality of load terminals;
an abnormality detection unit that detects whether or not tracking is present based on a magnitude of a difference value between the load terminal temperature and the power supply terminal temperature,
the second temperature detection unit measures a temperature at each of the plurality of load terminals;
The abnormality detection unit
a first difference value, which is a difference value between one first load terminal temperature, which is equal to or greater than an intermediate value among the temperatures of the plurality of load terminals measured by the second temperature detection unit, and the power supply terminal temperature, is equal to or greater than a first threshold value; and
If a second difference value, which is a difference value between one second load terminal temperature that is less than the intermediate value among the temperatures of the plurality of load terminals and the power supply terminal temperature, is equal to or greater than a second threshold value that is smaller than the first threshold value,
Detect that tracking has occurred,
Electrical outlet. the first load terminal temperature is a maximum value among the temperatures of the plurality of load terminals, and the second load terminal temperature is a minimum value among the temperatures of the plurality of load terminals;
2. The outlet according to claim 1. the first temperature detection unit measures a temperature at each of the plurality of power supply terminals;
the power supply terminal temperature is a minimum value among the temperatures of the plurality of power supply terminals measured by the first temperature detection unit;
3. The socket according to claim 1 or 2. and an opening/closing unit that cuts off the power supply path when the abnormality detection unit detects the occurrence of tracking.
The socket according to any one of claims 1 to 3. A notification unit that notifies the detection result of the abnormality detection unit.
The socket according to any one of claims 1 to 4. The notification unit causes a display unit to display a detection result of the abnormality detection unit.
6. The outlet according to claim 5.

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