JP3876295B2 - Adapter for detection switch connection - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a detection switch connection adapter used when connecting a plurality of detection switches that perform an on / off operation, and is used, for example, in series connection or parallel connection of detection switches for piston positions of a plurality of hydraulic cylinders. The
[0002]
[Prior art]
Conventionally, a detection switch is attached to a fluid pressure cylinder in order to detect its piston position.
[0003]
Usually, each detection switch is individually connected to an input terminal such as a programmable controller, but a plurality of detection switches are often connected to one input terminal. For example, in a clamp fixing device installed in a welding line of an automobile, a plurality of fluid pressure cylinders with detection switches that perform the same operation are installed. In order to detect that all the pistons of these fluid pressure cylinders have reached a predetermined set position, the respective detection switches are used in series with each other.
[0004]
FIG. 7 is a diagram showing a state in which three detection switches 80a, 80b and 80c are connected in series by a conventional connection method, and FIG. 8 is a circuit diagram showing the circuit of FIG.
As shown in FIG. 8, the three detection switches 80a, 80b, and 80c are connected to the terminals TB1 and TB2 according to an AND condition. For example, a load 81 such as a relay and a power source 82 for supplying power to the load 81 are connected to the terminals TB1 and TB2.
[0005]
Therefore, when all the three detection switches 80a, 80b, and 80c are turned on, an on signal is input to the terminals TB1 and TB2. When the three detection switches 80a, 80b, and 80c are respectively attached to the three cylinders, it is possible to confirm that all of the fluid pressure cylinders have reached the same stroke position by operating the load 81. However, if any one of the three detection switches 80a, 80b, and 80c is off, no on signal is input. Therefore, the load 81 does not operate. There are two possible causes for the load 81 not operating. One is an abnormality in the operating state of the fluid pressure cylinder. The other is that at least one of the detection switches 80a, 80b, and 80c does not turn on due to a failure cause such as disconnection.
[0006]
Whether the operating state of the fluid pressure cylinder is normal or abnormal is determined by checking whether all of the pistons of the fluid pressure cylinder have reached the set position. If there is a fluid pressure cylinder whose piston does not reach the set position, it can be determined that the operating state of the fluid pressure cylinder is abnormal.
[0007]
If the pistons of all the fluid pressure cylinders have reached the set position, there is no abnormality in the operation state of the fluid pressure cylinder, and it is considered that at least one of the detection switches 80a, 80b, 80c has failed. In this case, use a continuity tester or a tester to check the continuity of each detection switch 80a, 80b, 80c, or measure the voltage across each detection switch 80a, 80b, 80c. By doing so, it is possible to specify which of the detection switches 80a, 80b, and 80c is malfunctioning.
[0008]
FIG. 9 is a circuit diagram showing a circuit when three detection switches 90a, 90b, 90c are connected in parallel by a conventional connection method.
As shown in FIG. 9, the three detection switches 90a, 90b, 90c are connected to the terminals TB3, TB4 according to the OR condition. For example, a load 91 such as a relay and a power source 92 for supplying power to the load 91 are connected to the terminals TB3 and TB4.
[0009]
In this case, if any one of the three detection switches 90a, 90b, 90c is on, an on signal is input to the terminals TB3, TB4. When three detection switches 90a, 90b, and 90c are attached to the three cylinders, confirm that any one of the pistons of the fluid pressure cylinder has reached the set position by operating the load 91. Can do. However, when at least one of the detection switches 90a, 90b, 90c is not turned off due to a failure such as contact welding, the load 91 operates even when there is no fluid pressure cylinder reaching the set position. The operating condition of the cylinder cannot be confirmed accurately. In this case, in order to identify the malfunctioning detection switch, it is necessary to perform an operation such as testing the continuity of each detection switch after removing the connection wires between the detection switches. More work is required than in series connection.
[0010]
In addition, in a detection switch with a built-in display circuit or semiconductor circuit, when the detection switch is on, a voltage drop occurs due to the internal resistance of the detection switch. Therefore, if the number of detection switches connected in series becomes too large, the voltage drop increases, and sufficient power may not be supplied to the load, causing the load to malfunction.
[0011]
Similarly, a slight leakage current occurs when the detection switch is off. Therefore, if the number of detection switches connected in parallel becomes too large, the load may malfunction due to this leakage current.
[0012]
In other words, whether the detection switches are connected in series or in parallel, the load is liable to malfunction as the number of detection switches increases.
[0013]
Therefore, when the number of fluid pressure cylinders is as large as several tens, in order to obtain the AND signal of the detection switch attached to each of these fluid pressure cylinders, it is attached to each of several tens fluid pressure cylinders Instead of connecting all the detection switches directly in series, the following method is used.
[0014]
That is, for example, as shown in FIG. 8, about three sets of detection switches connected in series are prepared, and these detection switches connected in series are connected to input terminals over a plurality of locations of the programmable controller. In this method, an AND condition is further set.
[0015]
According to this method, the voltage drop is smaller than when all tens of detection switches are directly connected in series.
In addition, in order to obtain an OR signal, a plurality of sets of three detection switches connected in parallel are prepared in the same way as in the case of series connection, and these detection switches connected in parallel are respectively connected to a plurality of locations of the programmable controller. In this method, the OR condition is further set in the programmable controller.
[0016]
According to this method, the leakage current is smaller than when all tens of detection switches are directly connected in parallel.
[0017]
[Problems to be solved by the invention]
However, in the conventional serial connection method shown in FIG. 8, when the load does not operate, the operating state of each detection switch cannot be easily confirmed.
[0018]
Further, in the conventional parallel connection method shown in FIG. 9, when the load remains in operation, the operation state of each detection switch cannot be easily confirmed.
[0019]
When the detection switches are out of order, both the detection switches are connected in series and are connected in parallel. It is necessary to check the continuity and measure the voltage for each.
[0020]
When the number of detection switches to be connected is several tens, when the detection switch fails, a lot of work time is required until the failed detection switch can be identified. During this time, the apparatus is in a dormant state, so that the operating rate of the apparatus decreases.
[0021]
In addition, when obtaining the AND signal of several tens of detection switches by the above-described method, it is necessary to connect the detection switches to many input terminals in the programmable controller. Therefore, a cost for wiring is required. Moreover, the voltage drop due to the detection switches connected in series directly is larger than the voltage drop when there is one detection switch.
[0022]
Even when obtaining the OR signal of several tens of detection switches by the above-described method, it is necessary to connect the detection switches to many input terminals in the programmable controller. Therefore, the cost for wiring is also required at this time. Further, the leakage current due to the detection switches directly connected in parallel is larger than the leakage current when there is one detection switch.
In Japanese Utility Model Laid-Open No. 57-186932 and Japanese Utility Model Laid-Open No. 61-103831, there is no description on how to deal with various power sources and how the entire apparatus is constructed.
[0023]
The present invention has been made in view of the above-described problems, and can easily check the operating state of a plurality of detection switches, and even when a plurality of detection switches connected fails, the detection switches that have failed. Can be specified in a short time, and malfunction of the load due to voltage drop and leakage current can be prevented.At the same time, it can support various power sourcesAn object of the present invention is to provide an adapter for connecting a detection switch.
[0024]
[Means for Solving the Problems]
  The connection adapter according to the invention of claim 1 is a detection switch that performs on / off operation.And the programmable controller between the detection switchAdapter for connecting a plurality of detection switches, an input terminal for receiving an on / off signal of the detection switch, and lighting according to an on / off operation of the detection switch connected to the input terminal Or an indicator lamp that turns off, and an internal switch that performs an on / off operation in response to turning on or off of the indicator lamp,Formed in a housingDetection circuit blockIs composed of multiple separable setsBased on an input unit and an on / off signal that supplies power to the input unit and is output from the input unitObtained from the logic circuit by themON / OFF signalOutsideThe output block to outputEach detection circuit blockAn output unit housed in a separate housing,The input unit and the output unit are fixed on a rail by a fixture..
[0025]
The connection adapter according to the invention of claim 2The input unit is composed of a plurality of the detection circuit blocks, and includes a plurality of the internal switches included in the input unit.AND circuitThe on / off signal obtained from the above is output to the output unit..
The connection adapter according to the invention of claim 3 isThe input unit is composed of a plurality of the detection circuit blocks, and includes a plurality of the internal switches included in the input unit.OR circuitThe on / off signal obtained from is output to the output unit.
[0026]
  In the connection adapter according to a fourth aspect of the present invention, the input unit includes a plurality of the detection circuit blocks, and an on / off signal obtained from a plurality of logic circuits including the internal switches included in the input unit is the logic unit. From the rising edge of the on / off signal obtained from the circuit, it is turned on after a delay time t1 where t1> t0 / 2 with respect to the period t0 of the external AC magnetic field, and from the falling edge of the on / off signal obtained from the logic circuit, the alternating current It is output to the output terminal through an AC magnetic field corresponding circuit that generates a pulse signal that is turned off after a delay time t2 where t2> t0 / 2 with respect to the magnetic field period t0Thus, the influence due to the disturbance of the AC magnetic field having an external period t0 or less is eliminated.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a circuit diagram showing a circuit configuration of a connection adapter 1 for series connection according to the present invention.
[0029]
As shown in FIG. 1, the connection adapter 1 is composed of four detection circuit blocks KB11, KB12, KB13, KB14, a transistor TR1, a resistor R15, output terminals TB15, TB16, TB17, and an AC magnetic field corresponding circuit MD1. Yes.
[0030]
The detection circuit block KB11 includes an input terminal TB11, a display light emitting diode DD11, a photocoupler PC11, and a resistor R11. The input terminal TB11 is composed of two input terminals 11a and 11b.
[0031]
One input terminal 11a is connected to the common line C11 through the display light emitting diode DD11, the internal light emitting diode PD11 of the photocoupler PC11, and the resistor R11.
[0032]
Similarly to the detection circuit block KB11, the detection circuit blocks KB12 to 14 include input terminals TB12 to 14 (12a to 14a, 12b to 14b), display light emitting diodes DD12 to 14, photocouplers PC12 to 14, and resistors R12 to R14. These are provided and connected in the same manner as the detection circuit block KB11.
[0033]
The input terminals 11b to 14b are connected to each other and commonly connected to the output terminal TB17.
Each of the photocouplers PC11 to PC14 is connected in series with each other in series to form an AND circuit.
[0034]
The collector (one end of the AND circuit) of the photocoupler PC11 is connected to the common line C11. The common line C11 is connected to the output terminal TB15. The emitter of the photocoupler PC14 (the other end of the AND circuit) is connected to the base of the transistor TR1 through the resistor R15 and the AC magnetic field corresponding circuit MD1. The collector of the transistor TR1 is connected to the output terminal TB16, and the emitter is connected to the output terminal TB17.
[0035]
The AC magnetic field corresponding circuit MD1 is a circuit provided to prevent the load L1 connected to the connection adapter 1 from malfunctioning due to disturbance caused by an AC magnetic field. The connection adapter 1 is integrally configured by a synthetic resin or metal housing.
[0036]
Detection switches S11-14 that perform an on / off operation are connected to the input terminals TB11-14.
The output terminal TB15 is connected to one terminal of the load L1 and a positive electrode of the external power supply P1 for supplying power to the load L1 and the connection adapter 1. The other terminal of the load L1 is connected to the output terminal TB16. The negative terminal of the external power supply P1 is connected to the output terminal TB17.
[0037]
Next, the operation of the connection adapter 1 in FIG. 1 will be described.
When the detection switches S11 to 14 are turned on / off, the display light emitting diodes DD11 to 14 are turned on or off according to the on / off operation. At the same time, the internal light emitting diodes PD11 to 14 of the photocouplers PC11 to 14 are turned on or off, respectively.
[0038]
Here, when all of the detection switches S11 to 14 are turned on, the display light emitting diodes DD11 to 14 are all turned on. Also, all the internal light emitting diodes PD11-14 are turned on, and all the photocouplers PC11-14 are turned on. As a result, the AND circuit composed of the photocouplers PC11 to 14 is turned on, and an on signal is input to the AC magnetic field corresponding circuit MD1. The ON signal input to the AC magnetic field corresponding circuit MD1 is output to the base of the transistor TR1 after being delayed by a predetermined time t1. When the transistor TR1 is turned on, the output terminals TB16 and 17 are brought into conduction. As a result, the load L1 operates with power supplied from the external power supply P1.
[0039]
When at least one of the detection switches S11-14 is off, for example, when the detection switch S11 is off and the detection switches S12-14 are on, the display light emitting diodes DD12-14 and the internal light emitting diodes PD12-14 are lit. However, the display light emitting diode DD11 and the internal light emitting diode PD11 are turned off. For this reason, the AND circuit composed of the photocouplers PC11 to 14 is not turned on. Therefore, the load L1 does not operate.
[0040]
As described above, according to the connection adapter 1, the operating states of the four detection switches S 11 to 14 can be easily confirmed by turning on or off the display light-emitting diodes DD 11 to 14.
[0041]
Further, even when a plurality of connected detection switches fail, the failed detection switch can be identified in a short time.
For example, when four detection switches S11-14 are installed for the purpose of detecting whether the pistons of all the hydraulic cylinders have reached the set position, one of the detection switches S11-14 is off. Therefore, it is assumed that the load L1 does not operate. In this case, since the display light emitting diode is turned off, it can be determined which detection switch is turned off, and the corresponding piston position of the fluid pressure cylinder is confirmed. Thereby, it is possible to easily identify the malfunction of the fluid pressure cylinder or the failure of the detection switch.
[0042]
Further, even when the detection switches S11 to 14 have a built-in display circuit or semiconductor circuit, the detection switches S11 to S14 are not connected in series with each other, so that the voltage drop does not increase. Therefore, it is possible to prevent the load L1 from malfunctioning due to a voltage drop.
[0043]
FIG. 2 is a circuit diagram showing a circuit configuration of the connection adapter 2 for parallel connection according to the present invention.
As shown in FIG. 2, the connection adapter 2 is composed of four detection circuit blocks KB21, KB22, KB23, KB24, a transistor TR2, a resistor R25, output terminals TB25, TB26, TB27, and an AC magnetic field corresponding circuit MD2. .
[0044]
The detection circuit blocks KB21 to 24 are the same components as the detection circuit blocks KB11 to 14 in the connection adapter 1, that is, input terminals TB21 to 24 (21a to 24a, 21b to 24b), display light emitting diodes DD21 to 24, respectively. , Photocouplers PC21 to PC24. Further, the connection form inside the detection circuit blocks KB21 to 24 is the same as the connection form inside the detection circuit blocks KB11 to 14 in the connection adapter 1, respectively. Further, regarding the connection form of the resistor R25, the AC magnetic field corresponding circuit MD2, the transistor TR2, and the output terminals TB25, 26, and 27, the resistor R15, the AC magnetic field corresponding circuit MD1, the transistor TR1, and the output terminals TB15, 16, in the connection adapter 1 17 is the same as the connection form.
[0045]
Each of the photocouplers PC21 to PC24 is connected in parallel to each other to form an OR circuit.
The collectors (one end of the OR circuit) of the photocouplers PC21 to PC24 are connected to the common line C21. The common line C21 is connected to the output terminal TB25. Emitters (the other ends of the OR circuit) of the photocouplers PC21 to PC24 are connected to a resistor R25.
[0046]
Similarly to the case of the connection adapter 1, detection switches S 21 to 24 that perform an on / off operation are connected to the input terminals TB 21 to 24.
The output terminal TB25 is connected to one terminal of the load L2 and the positive pole of the external power supply P2 for supplying power to the load L2 and the connection adapter 2. The other one terminal of the load L2 is connected to the output terminal TB26. The negative terminal of the external power supply P2 is connected to the output terminal TB27.
[0047]
Next, the operation of the connection adapter 2 in FIG. 2 will be described.
When any one of the detection switches S21 to S24 is turned on, the display light emitting diode corresponding to the detection switch is turned on. Further, the internal light emitting diode corresponding to the display light emitting diode is turned on. As a result, the OR circuit composed of the photocouplers PC21 to PC24 is turned on, and the on signal is input to the AC magnetic field corresponding circuit MD2. The ON signal input to the AC magnetic field corresponding circuit MD2 is output to the base of the transistor TR2 after having a delay of a predetermined time t1. When the transistor TR2 is turned on, the output terminals TB26 and 27 are brought into conduction. As a result, the load L2 operates by being supplied with electric power from the external power source P2.
[0048]
When all of the detection switches S21 to 24 are off, all of the display light emitting diodes DD21 to 24 and the internal light emitting diodes PD21 to 24 are turned off. For this reason, the OR circuit composed of the photocouplers PC21 to PC24 is not turned on. Therefore, the load L2 does not operate.
[0049]
Therefore, according to the connection adapter 2, the operating states of the four detection switches S21 to 24 can be easily confirmed by turning on or off the display light emitting diodes DD21 to 24.
[0050]
In addition, even when a plurality of connected detection switches fail, when one detection switch fails, the failed detection switch can be identified in a short time.
[0051]
For example, when four detection switches S21 to 24 are installed for the purpose of detecting whether the piston of any fluid pressure cylinder has reached the set position, none of the four fluid pressure cylinders is in the set position. It is assumed that the load L2 is operating because one of the detection switches S21 to S24 is on even though it has not reached. In this case, since the light-emitting diode for display indicates which detection switch is turned on, the failed detection switch can be easily identified.
[0052]
Further, even if the detection switches S21 to 24 have a built-in display circuit or semiconductor circuit, the leakage current does not increase, so that the load L2 can be prevented from malfunctioning due to the leakage current.
[0053]
FIG. 3 is a circuit diagram showing a circuit configuration of the connection adapter 3 for mixing the serial connection and the parallel connection according to the present invention.
As shown in FIG. 3, the connection adapter 3 includes four detection circuit blocks KB31, KB32, KB33, KB34, a transistor TR3, a resistor R35, output terminals TB35 to 46, and an AC magnetic field corresponding circuit MD3.
[0054]
The detection circuit blocks KB31 to 34 are respectively the same components as the detection circuit blocks KB11 to 14 in the connection adapter 1, that is, input terminals TB31 to 34 (31a to 34a, 31b to 34b), and display light emitting diodes DD31 to 34. , Photocouplers PC31 to 34 and resistors R31 to R34. The common line is C31. Further, the connection form inside the detection circuit blocks KB31 to 34 is the same as the connection form of the detection circuit blocks KB11 to 14 in the connection adapter 1, respectively.
[0055]
Further, regarding the connection form of the AC magnetic field corresponding circuit MD3, the transistor TR3, and the output terminals TB35, 36, and 37, the resistor R15 in the connection adapter 1, the AC magnetic field corresponding circuit MD1, the transistor TR1, and the output terminals TB15, 16, and 17 It is the same as the form.
[0056]
One end of the resistor R35 is connected to the AC magnetic field corresponding circuit MD3, and the other end is connected to the output terminal TB46.
The secondary sides of the photocouplers PC31 to PC34 are connected to the output terminals TB38 to 45, respectively.
[0057]
Similarly to the case of the connection adapter 1, detection switches S31 to 34 that perform an on / off operation are connected to the input terminals TB31 to 34.
The output terminal TB35 is connected to one terminal of the load L3 and the positive electrode of the external power source P3 for supplying power to the load L3 and the connection adapter 3. The other terminal of the load L3 is connected to the output terminal TB36. The negative terminal of the external power supply P3 is connected to the output terminal TB37.
[0058]
These output terminals TB38 to 45 are respectively connected by external connection wires so that the secondary sides of the photocouplers PC31 to 34 constitute a desired logic circuit.
[0059]
The output terminals TB35 and TB46 are respectively connected to output terminals corresponding to both ends of the above-described logic circuit by external connection wires.
In FIG. 3, the output terminals TB38 and TB40, the output terminals TB39 and TB41, the output terminals TB41 and TB42, and the output terminals TB43 and TB44 are connected to each other. An AND circuit is configured with the AND circuit configured as described above.
[0060]
The logic circuit composed of the photocouplers PC31 to PC34 can be of various types by changing the connection state of the wires between the output terminals TB38 to TB45.
[0061]
Therefore, according to the connection adapter 3, various logical operation outputs can be obtained for the on / off input signals of the detection switches S31 to S34.
Moreover, even if various ON / OFF input signals of the detection switches S31 to 34 are subjected to various logical operations by various logic circuits, the operating state of the detection switches S31 to 34 can be easily confirmed. Even if the detection switches S31 to 34 fail, the failed detection switch can be identified in a short time, and the load L3 malfunctions due to the voltage drop or leakage current of the detection switches S31 to 34. Can be prevented.
[0062]
When the detection switch is turned on / off by a magnetic field like a reed switch and used in an environment with an AC magnetic field disturbance, the detection switch may malfunction due to the AC magnetic field disturbance.
[0063]
The on / off signal when the detection switch malfunctions is taken into the connection adapter. The on / off signal is output from the output terminal after a logical operation is performed by a logic circuit in the connection adapter, but if it is output as it is, the load also malfunctions.
[0064]
In order to prevent the load from malfunctioning due to malfunction of the detection switch, in the connection adapters 1 to 3, the AC magnetic field corresponding circuits MD1 to MD3 are connected to the input sides of the transistors TR1 to TR3, respectively.
[0065]
FIG. 4 is a circuit diagram showing circuits of AC magnetic field corresponding circuits MD1 to MD3.
As shown in FIG. 4, the AC magnetic field corresponding circuits MD1 to MD3 are composed of two input blocks SI1 and SI2, two delay blocks DL1 and DL2, an inverter IV1 and an RS flip-flop FF1, an input terminal T1, and an output terminal T2. The The delay block DL1 is an ON delay circuit, and the delay block DL2 is an OFF delay circuit. The input terminal T1 is connected to one end of resistors R15, R25, R35 in the connection adapters 1-3. The output terminal T2 is connected to the bases of the transistors TR1-3 in the connection adapters 1-3.
[0066]
Taking the case where the pulse signal PL1 is applied to the input terminal T1 as an example, the operation of the AC magnetic field corresponding circuits MD1 to MD3 will be described.
The pulse signal PL1 is input to the delay block DL1 through the input block SI1. Then, the signal is input to the inverter IV1 after a delay time t1, and after being logically inverted by the inverter IV1, is input to the set side S of the RS flip-flop FF1. Therefore, the holding signal RT1 rises from the output side Q of the RS flip-flop FF1 with a delay time t1 from the rise of the pulse signal PL1.
[0067]
The pulse signal PL1 is input to the delay block DL2 through the input block SI2. Then, the signal is input to the reset side R of the RS flip-flop FF1 after a delay time t2. Therefore, the holding signal RT1 output to the output side Q of the RS flip-flop FF1 falls with a delay time t2 after the falling of the pulse signal PL1.
[0068]
If the delay times t1 and t2 are t1> t0 / 2 and t2> t0 / 2 with respect to the period t0 of the pulse signal PL1, respectively, the holding signal RT1 always remains off with respect to the input of the pulse signal PL1. .
[0069]
When the disturbance of the external AC magnetic field is caused by a 50 Hz or 60 Hz AC power source, the period of the AC magnetic field is 16 milliseconds or 20 milliseconds. However, the period at which the magnetic sensor operates is one half of the AC magnetic field.
[0070]
Therefore, if the delay blocks DL1 and DL2 are set to about 30 milliseconds, for example, so that the above-described delay times t1 and t2 are larger than 10 milliseconds, a signal that is turned on / off within a pulse width time within 10 milliseconds is obtained. Even when applied to the input terminal T1, the holding signal RT1 of the RS flip-flop FF1 is not output.
[0071]
Therefore, even if the detection switch malfunctions due to disturbance of an AC magnetic field of 50 Hz or 60 Hz, the load does not malfunction.
Even if chattering occurs in the detection switch, the operation of the load does not become unstable. There is no malfunction.
[0072]
Only one AC magnetic field corresponding circuit MD1 to 3 is provided for each of the connection adapters 1 to 3, and it is possible to prevent a malfunction of the load due to a malfunction of all the detection switches connected to the connection adapters 1 to 3. it can.
[0073]
Therefore, it is not necessary to provide the detection switch with a function that can cope with an AC magnetic field, and an inexpensive detection switch having a small outer dimension can be used.
FIG. 5 is a view showing the appearance of the connection adapter 4 in which the input unit and the output unit according to the present invention are separable.
[0074]
As shown in FIG. 5, the connection adapter 4 includes an input unit NY4 and an output unit SY4 that are housed in a housing. These are fixed on a rail of a terminal block (not shown) so as to be sandwiched from both sides by two fixing brackets FB1 and FB2. The input unit NY4 and the output unit SY4 can be separated at the boundary line BL4.
[0075]
The input unit NY4 includes detection circuit blocks KB41 to 44. The detection circuit blocks KB41 to 44 are composed of the same components as the detection circuit blocks KB11 to 14 in the connection adapter 1. Display light emitting diodes DD41 to 44 are attached to the tops of the detection circuit blocks KB41 to 44, respectively. Detection switches S41 to S44 that perform on / off operations are connected to the input terminals TB41 to 44, respectively. A load and a power source are connected to the output terminals TA45 to 47 of the output unit SY4. The output unit SY4 includes an output block SB5 that is a circuit similar to the circuit including the resistor R15 of the connection adapter 1 illustrated in FIG. 1, the AC magnetic field corresponding circuit MD1, the transistor TR1, and the output terminals TB15 to TB17. .
[0076]
The input unit NY4 includes a unit fixed type and a unit separated type. In the unit fixed type, the detection circuit blocks KB41 to 44 are integrated, but in the unit separation type, the detection circuit blocks KB41 to 44 are separated one by one from the boundary lines BL1 to BL3. can do.
[0077]
In the unit-separated type input unit, it is only necessary to attach a necessary number of detection circuit blocks according to the number of detection switches connected to the input unit.
[0078]
That is, the number of detection switches and the number of detection circuit blocks can be matched. Therefore, there is no unused detection circuit block, and the connection adapter can be used effectively.
[0079]
The input unit NY4 and the output unit SY4, and the input unit NY4 in the case of the unit separation type, are electrically connected at a contact portion such as a connector (not shown) to constitute a circuit as shown in FIGS. ing.
[0080]
The connection adapters 1 to 4 described above are all connection adapters for DC power. That is, the power source connected to the connection adapters 1 to 4 is a DC power source, and the load is a load that is operated by the DC power source.
[0081]
When the power source to be connected is an AC power source and the load is a load operated by the AC power source, it is necessary to use a connection adapter for the AC power source.
The connection adapters 1 to 4 for the DC power supply can be used as connection adapters for the AC power supply by using the photocouplers and transistors in the connection adapters 1 to 4 as bidirectional thyristors. In this case, it is necessary to replace the photocouplers with bidirectional thyristors by the number of detection circuit blocks.
[0082]
Next, a description will be given of a method in which the connection adapter for the DC power supply is changed to the connection adapter for the AC power supply without replacing the photocoupler in the detection circuit block with the bidirectional thyristor.
[0083]
FIG. 6 is a circuit diagram showing a circuit configuration of the connection adapter 5 in the connection adapter 4 when the output unit SY4 for DC power supply is replaced with an output unit SY5 for AC power supply.
[0084]
As shown in FIG. 6, in the output unit SY5, a bidirectional thyristor TC5 is provided instead of the transistor in the output unit SY4. An AC / DC converter AD is provided between the output terminal TB55 and a common line CC5 that supplies DC power to the input unit NY4.
[0085]
The DC power used in the input unit NY4 can be obtained from the AC power supply P5 via the AC / DC converter AD. Therefore, the photocoupler in the input unit NY4 need not be a bidirectional thyristor.
[0086]
That is, in the connection adapter 4, the connection adapter 5 that can handle AC power supply can be obtained simply by replacing the output unit SY4 for DC power supply with the output unit SY5 for AC power supply.
[0087]
In each of the embodiments described above, the number of detection circuit blocks is four and the number of detection switches connected to these detection circuit blocks is four. However, the number may be three or less, or five or more.
[0088]
In addition, the configurations, shapes, dimensions, and circuit configurations of the connection adapters 1 to 5 can be various other than those described above.
[0089]
【The invention's effect】
Claims 1 to4According to the invention, it is possible to easily confirm the operating state of a plurality of detection switches, and even when a plurality of detection switches connected to each other fails, it is possible to identify the detection switch that has failed. Yes, it is possible to prevent malfunction of the load due to voltage drop and leakage current.
[0090]
Therefore, by using the connection adapter according to the present invention, when a large number of detection switches are connected to the input terminals of the programmable controller, the number of input terminals to be used can be greatly reduced, and the number of input terminals is small. A small and inexpensive programmable controller can be used.
Moreover, it can be set as the adapter for connection which can respond | correspond to various power supplies by changing an output unit into what can respond to a different power supply.
[0091]
According to the invention of claim 4When,It is possible to prevent the malfunction of the load due to the malfunction of the plurality of detection switches caused by the disturbance of the AC magnetic field and the malfunction of the load due to the chattering of the detection switches at low cost.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing a circuit configuration of a connection adapter for series connection according to the present invention.
FIG. 2 is a circuit diagram showing a circuit configuration of a connection adapter for parallel connection according to the present invention.
FIG. 3 is a circuit diagram showing a circuit configuration of a connection adapter for mixing serial connection and parallel connection according to the present invention.
FIG. 4 is a circuit diagram showing a circuit of an AC magnetic field compatible circuit.
FIG. 5 is a diagram showing an appearance of a connection adapter in which an input unit and an output unit according to the present invention are separable.
FIG. 6 is a circuit diagram showing a circuit configuration of a connection adapter when an output unit for DC power is replaced with an output unit for AC power.
FIG. 7 is a diagram showing a state in which three detection switches are connected in series by a conventional connection method.
8 is a circuit diagram showing the circuit of FIG.
FIG. 9 is a circuit diagram showing a circuit when three detection switches are connected in parallel by a conventional connection method;
[Explanation of symbols]
1-5 Connection adapter
S11-14, S21-24, S31-34, S41-44 Detection switch
TB11-14, TB21-24, TB31-34, TB41-44 Input terminal
11a-14a, 21a-24a, 31a-34a, 41a-44a Input terminal
11b-14b 21b-24b, 31b-34b, 41b-44b Input terminal
TB15-17, TB25-27, TB35-46, TA45-47, TB55-57 Output terminal
DD11-14, DD21-24, DD31-34, DD41-44 Light emitting diode for display (indicator lamp)
PC11-14, PC21-24, PC31-34 Photocoupler (internal switch)
KB11-14, KB21-24, KB31-34, KB41-44 Detection circuit block
MD1-3, 5 AC magnetic field compatible circuit
NY4 input unit
SB5 output block
SY4,5 output unit

Claims (4)

Between a detection switch that performs an on / off operation and a programmable controller, an adapter for connection of a detection switch used when connecting a plurality of the detection switches,
An input terminal for capturing an on / off signal of the detection switch, an indicator lamp that is turned on or off in accordance with an on / off operation of the detection switch connected to the input terminal, and an on / off operation in accordance with the on or off of the indicator lamp An input unit constituted by a plurality of separable detection circuit blocks formed by being housed in a housing .
An output block that supplies power to the input unit and outputs an on / off signal obtained from a logic circuit based on the on / off signal output from the input unit to the outside is housed in a housing separate from the detection circuit blocks. An output unit,
Consists of
The input unit and the output unit are fixed on a rail by a fixture,
An adapter for connecting a detection switch. Wherein the input unit includes a plurality of said outputs an on-off signal obtained from the AND circuit by internal switches to the output unit, according to claim 1 detection switch of the connection adapter according included in the input unit. Wherein the input unit includes a plurality of said outputs an on-off signal obtained from the OR circuit by the internal switch to the output unit, according to claim 1 detection switch of the connection adapter according included in the input unit. The input unit is composed of a plurality of the detection circuit blocks, and an on / off signal obtained from a plurality of logic circuits including the internal switches included in the input unit is generated from the rise of the on / off signal obtained from the logic circuit. It is turned on after a delay time t1 where t1> t0 / 2 with respect to the period t0 of the alternating magnetic field, and t2> t0 / 2 with respect to the period t0 of the alternating magnetic field from the fall of the on / off signal obtained from the logic circuit. Is output to the output terminal through an AC magnetic field corresponding circuit that generates a pulse signal that is turned off after the delay time t2, and the influence of disturbance of an AC magnetic field having an external period t0 or less is removed.
The adapter for detecting a switch according to claim 1.

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