JP7040765B2 - Coil unit and solenoid equipped with it - Google Patents

Description

The present invention relates to a coil unit and a solenoid provided with the coil unit, and more particularly to a coil unit having a configuration capable of dealing with a disconnection of a coil wire and a solenoid provided with the coil unit.

Equipment used to mount a coil unit and obtain operating force and heat by the magnetic field generated by the coil, such as linear solenoids, rotary solenoids, voice coil motors, linear motors, high frequency induction heaters, electromagnetic valves, etc. In various devices, the coil may be disconnected due to vibration or impact transmitted from the outside or generated by the device itself.

FIG. 11 is a cross-sectional view showing a solenoid on which a coil unit according to the prior art is mounted. In FIG. 11, 70 is a solenoid, 80 is a coil, 81 is a coil bobbin, 82 is a first flange portion, 83 is a winding body portion, 84 is a second flange portion, 85 is a first wiring hole, and 86 is a second. 87 is the first end region, 88 is the second end region, 89 is the terminal portion, 90 is the fixed magnetic pole, 91 is the movable magnetic pole, 92 is the auxiliary magnetic pole, 93 is the facing portion, and 94 is the case. , 95 is a fixing plate material, 96 is a shaft, 97 is a sleeve, 98 is a connector, and 99 is an insertion portion.

FIG. 11 shows the invention disclosed in Japanese Patent Application Laid-Open No. 2017-69301. As shown in FIG. 11, the solenoid 70 is a direct coupler type in which a connector 98 is provided in one opening of the case 94, and the insertion portion 99 can be directly connected to a connector of a mounted device (not shown). It is configured in. Direct coupler type solenoids are often used in hydraulic equipment and the like. The other opening of the case 94 is provided with a fixing plate material 95 to be fixed to the device to be mounted, and a fixed magnetic pole 90 is fitted to the fixing plate material 95. A coil 80 is provided inside the case 94, and a facing portion 93 of the auxiliary magnetic pole 92 is provided inside the coil 80. In addition, a sleeve 97 is provided inside the facing portion 93. The coil 80 is formed by winding a coil wire around the winding body portion 83 of the coil bobbin 81. The first end region 87 and the second end region 88 of the coil 80 pass through the first wiring hole 85 and the second wiring hole 86 formed in the second flange portion 84 of the coil bobbin 81. It is connected to the terminal portion 89 and another terminal portion (not shown), respectively. Therefore, it is possible to supply a current to the coil 80 by electrically connecting the connector of the device mounted on the terminal portion 89 and another terminal portion (not shown). Further, although not particularly shown, the coil unit is provided with a reverse connection prevention diode on the second flange portion 84 in order to prevent the coil 80 from being reversely connected to the power supply due to a wiring error in the assembly process or the like. It's not uncommon.

Further, the coil bobbin 81 is provided with the first flange portion 82 in contact with the fixing plate material 95 and the second flange portion 84 in contact with the auxiliary magnetic pole 92, and the case 94, the facing portion 93 of the auxiliary magnetic pole 92, and the coil bobbin 81 are provided. It is held in a state of being surrounded by the fixing plate material 95. The movable magnetic pole 91 is provided inside the sleeve 97 that is open on the fixing plate 95 side. Further, the movable magnetic pole 91 has a shaft 96 fitted in a through hole along the central axis thereof. The sleeve 97 guides the sliding of the movable magnetic pole 91. In the above configuration, when a current is supplied to the coil 80, a magnetic circuit is generated around the movable magnetic pole 91, the fixed magnetic pole 90, the case 94, and the auxiliary magnetic pole 92, and the movable magnetic pole 91 is attracted to the fixed magnetic pole 90 to be attracted to the fixed magnetic pole 90. It slides to the 90 side, and the shaft 96 also slides at the same time.

According to the above configuration, since the solenoid 70 can be directly connected to the connector of the device on which the solenoid 70 is mounted, the solenoid can be miniaturized and the work load for electrically connecting the coil 80 to the device on which the coil 80 is mounted can be realized. Has the advantage of being able to be reduced. By the way, in the solenoid 70, since the connector 98 is directly connected to the connector of the device to be mounted, the vibration and impact from the mounted device are transmitted from the connector 98 together with the fixing plate material 95. become. When a large amount of vibration or impact from the equipment mounted on the coil 80 is applied over a long period of time, the coil 80 is more likely to be disconnected. If the coil is broken, at least a part of the function as a device is lost. Therefore, especially in the device where safety is required, countermeasures against the disconnection become a big issue.

Therefore, from the viewpoint of fail-safe, for example, instead of providing only one solenoid, it is necessary to use a plurality of collective solenoids and take measures such as connecting the collective solenoid to a device to which the solenoid is mounted. However, although it is possible to ensure safety with the collective solenoid, it is a preferable solution because the solenoid becomes large and the part that receives the operating force from the solenoid becomes large in the mounted equipment. It's not a plan. In addition, even if other measures against disconnection are taken, consideration for cost becomes an inevitable issue so that the selling price of the solenoid does not fluctuate significantly.

Japanese Unexamined Patent Publication No. 2017-69301

In order to solve the above-mentioned problems, the present invention can prevent the loss of function due to the disconnection of the coil without hindering the miniaturization of the device, and the selling price does not fluctuate significantly. It is an object of the present invention to provide a coil unit having a configuration and a solenoid equipped with the coil unit.

The invention according to claim 1 is a coil unit mounted on an apparatus, in which coil wires are wound so as to form n line layers from the first layer to the n (n ≧ 2) layer. From the first group, in which the coil formed in the above direction, the diode connected in series with each other, and the resistor are grouped together, and are connected in parallel to the streak layer from the first layer to the nth layer, respectively. The operation setting element group of n groups up to the nth group and the linear layer from the first layer to the nth layer are connected in parallel, and the base electrode is connected to the first group to the first group. It is provided with n first to nth bipolar transistors connected to the midpoint between the diode and the resistor constituting the operation setting element group up to n group, a light emitting diode, and a phototransistor. The n photocouplers from the first to the nth, in which the collector electrode and the emitter electrode of the phototransistor are connected in parallel to the diode of the operation setting element group from the first group to the nth group, respectively. , Any of the light emitting diodes of the photocoupler from the first to the nth, which is connected to the light emitting diode of the photocoupler from the first to the nth and the first power source. The operation setting element group from the first group to the n group has the selection switch capable of connecting m (n> m ≧ 1) or all of the above to the first power source. The diode is arranged on the current supply side of the second power supply so that the resistor is on the current feedback side of the second power supply, and the diode is current feedback from the current supply side of the second power supply. The bipolar transistors from the first to the nth are arranged so as to be forward with respect to the direction toward the side, and the collector electrode of the first bipolar transistor supplies the current of the second power supply. In addition to being connected to the side, the collector electrodes of the bipolar transistors from the second to the nth are connected to the emitter electrodes of the bipolar transistors of the first to n-1, respectively, and the bipolar of the nth. The emitter electrode of the transistor is connected to the current feedback side of the second power supply, and is not turned on by the voltage applied from the second power supply when the linear layer connected in parallel is not broken. Moreover, when a disconnection occurs in the linear layer connected in parallel, the photo is turned on by the voltage applied from the second power source, and the first to the nth photo. In the coupler, the light emitting diode emits light by the current supplied from the first power source, the phototransistor is turned on by the light emission of the light emitting diode, the current from the second power source is amplified, and the coupler is connected in parallel. A coil unit characterized in that the bipolar transistor to which the base electrode is connected is turned on at the midpoint between the diode and the resistor constituting the operation setting element group including the diode. Is.

The invention according to claim 2 is a coil unit mounted on an apparatus, in which coil wires are wound so as to form n line layers from the first layer to the n (n ≧ 4) layer. The coil formed in the above direction and the l (2 ≦ l ≦ n / 2, and l is an integer) layer adjacent to each other in the linear layer from the first layer to the j (n> j ≧ 1) layer. The streak layer is defined as k streak layer groups from the first group to the kth (k = n / m, and k is an integer obtained by rounding down fractions) group, and each of these k streak layers is divided into k streak layers. The operation setting element group of the k group from the first group to the k group and the operation setting element group from the first group to the k group, which is a group of a diode and a resistor connected in parallel and connected in series with each other. The base electrodes were connected in parallel to the linear layer group, and the base electrode was connected to the midpoint between the diode and the resistor constituting the operation setting element group from the first group to the kth group, respectively. The group includes k bipolar transistors from the first to the kth, a light emitting diode and a phototransistor, and the collector electrode and the emitter electrode of the phototransistor are the operation setting element group from the first group to the kth group. The k photocouplers from the first to the kth, which are connected in parallel to the diode, the light emitting diode of the photocoupler from the first to the kth, and the first power supply are connected to each other. At the same time, any m (k> m ≧ 1) or all of the light emitting diodes of the photocoupler from the first to the kth can be connected to the first power supply. In the operation setting element group from the first group to the k group having a selection switch, the diode is on the current supply side of the second power supply and the resistance is on the current feedback side of the second power supply. The diode is arranged so as to be in the forward direction with respect to the direction from the current supply side of the second power supply to the current feedback side, and the first to the kth are arranged. In the bipolar transistor, the collector electrode of the first bipolar transistor is connected to the current supply side of the second power supply, and the collector electrodes of the bipolar transistors from the second to the kth are from the first. The emitter electrode of the bipolar transistor of the kth k-1 is connected to the emitter electrode of the bipolar transistor, and the emitter electrode of the bipolar transistor of the kth is connected to the current feedback side of the second power supply and is connected in parallel. From the second power source when the streak layer is not broken It is not turned on by the applied voltage, and is turned on by the voltage applied from the second power source when a disconnection occurs in the linear layer connected in parallel, and the first to the k. In the photocoupler up to, the light emitting diode emits light by the current supplied from the first power source, and the phototransistor is turned on by the light emission of the light emitting diode to amplify the current from the second power source. It is characterized in that the bipolar transistor to which the base electrode is connected is turned on at the midpoint between the diode and the resistor constituting the operation setting element group including the diode connected in parallel. It is a coil unit.

The invention according to claim 3 is a coil unit mounted on an apparatus, in which coil wires are wound so as to form n line layers from the first layer to the n (n ≧ 2) layer. From the first group, in which the coil formed in the above direction, the diode connected in series with each other, and the resistor are grouped together, and are connected in parallel to the streak layer from the first layer to the nth layer, respectively. The operation setting element group of n groups up to the nth group and the linear layer from the first layer to the nth layer are connected in parallel, and the base electrode is connected to the first group to the first group. It is provided with n first to nth bipolar transistors connected to the midpoint between the diode and the resistor constituting the operation setting element group up to n group, a light emitting diode, and a phototransistor. The collector electrode and the emitter electrode of the phototransistor are connected in parallel to the diode of the operation setting element group from the first group to the h (n> h ≧ 2) group, respectively, from the first to the h. The h photocouplers, the light emitting diodes of the photocouplers from the first to the hth, and the first power source are connected, and the photocouplers of the first to the h are connected to the light emitting diode. Among the light emitting diodes, any m (h> m ≧ 1) or all of them have a selection switch that can be connected to the first power source, and the operation from the first group to the n group. The setting element group is arranged so that the diode is on the current supply side of the second power supply and the resistor is on the current feedback side of the second power supply, and the diode is on the current feedback side of the second power supply. The bipolar transistors from the first to the nth are arranged so as to be forward with respect to the direction from the supply side to the current feedback side, and the collector electrode of the first bipolar transistor is the second. The collector electrode of the bipolar transistor from the second to the nth is connected to the emitter electrode of the bipolar transistor of the first to n-1 while being connected to the current supply side of the power supply. The emitter electrode of the nth bipolar transistor is connected to the current feedback side of the second power source, and is applied from the second power source when the linear layer connected in parallel is not broken. It is not turned on by the current voltage, and is turned on by the voltage applied from the second power source when the line layer connected in parallel occurs, from the first to the h. In the photocoupler, the light emitting diode emits light by the current supplied from the first power source, and the phototransistor is turned on by the light emission of the light emitting diode to amplify the current from the second power source and parallel. The feature is that the bipolar transistor to which the base electrode is connected is turned on at the midpoint between the diode and the resistor constituting the operation setting element group including the diode to be connected. It is a coil unit.

The invention according to claim 4 is a coil unit mounted on an apparatus, in which coil wires are wound so as to form n line layers from the first layer to the n (n ≧ 4) layer. The coil formed in the above direction and the l (2 ≦ l ≦ n / 2, and l is an integer) layer adjacent to each other in the linear layer from the first layer to the j (n> j ≧ 1) layer. The streak layer is defined as k streak layer groups from the first group to the kth (k = n / m, and k is an integer obtained by rounding down fractions) group, and each of these k streak layers is divided into k streak layers. The operation setting element group of the k group from the first group to the k group and the operation setting element group from the first group to the k group, which is a group of a diode and a resistor connected in parallel and connected in series with each other. The base electrodes were connected in parallel to the linear layer group, and the base electrode was connected to the midpoint between the diode and the resistor constituting the operation setting element group from the first group to the kth group , respectively. It is provided with k bipolar transistors from the first to the kth, a light emitting diode and a phototransistor, and the collector electrode and the emitter electrode of the phototransistor are from the first group to the g (k> g ≧ 2) group . The g photocouplers from the first to g, which are connected in parallel to the diodes of the operation setting element group, and the light emitting diodes of the photocouplers from the first to the g . Of the light emitting diodes of the photocoupler from the first to the gth, any m (g> m ≧ 1) or all of them are connected to the power supply of the first power supply. In the operation setting element group from the first group to the k group, the diode is on the current supply side of the second power supply, and the resistance is on the second power supply side. The diode is arranged so as to be on the current feedback side of the above, and the diode is arranged so as to be forward with respect to the direction from the current supply side of the second power supply to the current feedback side. In the bipolar transistors up to the k-th, the collector electrode of the first bipolar transistor is connected to the current supply side of the second power supply, and the collectors of the bipolar transistors from the second to the k-th are connected. The electrodes are connected to the emitter electrodes of the first to k-1 bipolar transistors, respectively, and the emitter electrodes of the kth bipolar transistor are connected to the current feedback side of the second power supply. When the linear layer connected in parallel is not broken, the second It is not turned on by the voltage applied from the power source of the above, and is turned on by the voltage applied from the second power source when a disconnection occurs in the linear layer connected in parallel. In the photocoupler up to the gth, the light emitting diode emits light by the current supplied from the first power source, and the phototransistor is turned on by the light emission of the light emitting diode to generate the current from the second power source. The bipolar transistor to which the base electrode is connected is turned on at the midpoint between the diode and the resistor constituting the operation setting element group including the diode which is amplified and connected in parallel. It is a coil unit characterized by this.

The invention according to claim 5 is the invention according to any one of claims 1 to 4, further comprising a winding body portion formed in a substantially tubular shape, both ends of the winding body portion, or both portions thereof. It has a coil bobbin provided with a first flange portion and a second flange portion provided in a vicinity portion, and one or both of the first flange portion and the second flange portion is an edge portion. A slit is formed from the to the winding body portion or the vicinity portion thereof, and the coil is wound around the winding body portion, and any one of the linear layers from the first layer to the nth layer is formed. Both ends of the coil strips constituting the strip layer and the strips adjacent to the strip layer and portions in the vicinity thereof form the slits of the first flange portion or the second flange portion. It is a coil unit characterized in that it is led out to the opposite side to the winding body portion via the same and is connected to each other.

The invention according to claim 6 is a solenoid provided with the coil unit according to claim 5.

According to the invention of claim 1, if the linear layers from the first layer to the nth layer are normal, none of the bipolar transistors from the first layer to the nth layer is turned on, but the first layer to the nth layer are not turned on. When a disconnection occurs in any one of the strand layers up to n layers or in a plurality of layers, the bipolar transistor corresponding to the strand layer in which the disconnection has occurred is turned on, and the next strand layer must be disconnected. A current flows through the streak layer of the cigarette, and if this streak layer is also broken, a current flows through the next bipolar transistor. Further, if the wire is broken after that, the same operation is performed. That is, when a disconnection occurs in any of the streak layers, the bipolar transistor corresponding to that streak layer functions as a bypass and the current continues to flow, so that the function is completely reduced even if the function as a coil is slightly deteriorated. You will be able to prevent it from being lost. Further, since any bipolar transistor can be turned on by operating the selection switch, it is possible to adjust so as to generate a magnetic force according to the device to be mounted. As a result, since the coil unit having the same configuration can be mounted on various devices, it is possible to reduce the manufacturing cost and suppress the increase in the selling price by mass-producing the coil unit having the same configuration.

According to the invention according to claim 2, if the linear layer groups from the first group to the k group are normal, none of the bipolar transistors from the first to the k is turned on, but from the first group. When a disconnection occurs in any one group or multiple groups of the linear layer groups up to the kth group, the bipolar transistor corresponding to the linear layer group in which the disconnection has occurred is turned on, and the next linear layer group is turned on. If there is no disconnection, a current flows through this linear layer group, and if this linear layer group is also disconnected, a current flows through the next bipolar transistor. Further, if the wire is broken after that, the same operation is performed. That is, when a disconnection occurs in any of the streak layers, the bipolar transistor corresponding to that streak layer functions as a bypass and the current continues to flow, so that the function is completely reduced even if the function as a coil is slightly deteriorated. You will be able to prevent it from being lost. Further, since any bipolar transistor can be turned on by operating the selection switch, it is possible to adjust so as to generate a magnetic force according to the device to be mounted. As a result, since the coil unit having the same configuration can be mounted on various devices, it is possible to reduce the manufacturing cost and suppress the increase in the selling price by mass-producing the coil unit having the same configuration.

According to the third aspect of the present invention, if the linear layers from the first layer to the nth layer are normal, none of the bipolar transistors from the first layer to the nth layer is turned on, but the first layer to the nth layer are not turned on. When a disconnection occurs in any one of the strand layers up to n layers or in a plurality of layers, the bipolar transistor corresponding to the strand layer in which the disconnection has occurred is turned on, and the next strand layer must be disconnected. A current flows through the streak layer of the cigarette, and if this streak layer is also broken, a current flows through the next bipolar transistor. Further, if the wire is broken after that, the same operation is performed. That is, when a disconnection occurs in any of the streak layers, the bipolar transistor corresponding to that streak layer functions as a bypass and the current continues to flow, so that the function is completely reduced even if the function as a coil is slightly deteriorated. You will be able to prevent it from being lost. Further, since any bipolar transistor can be turned on by operating the selection switch, it is possible to adjust so as to generate a magnetic force according to the device to be mounted. As a result, since the coil unit having the same configuration can be mounted on various devices, it is possible to reduce the manufacturing cost and suppress the increase in the selling price by mass-producing the coil unit having the same configuration. In addition, by providing less photocouplers than bipolar transistors, some bipolar transistors can be excluded from the target to be turned on arbitrarily, and the number of parts of the coil unit can be reduced. As a result, it is possible to further suppress the increase in the selling price of the coil unit.

According to the fourth aspect of the invention, if the streak layer groups from the g + 1 group to the k group are normal, the bipolar transistors from the g + 1 to k are not turned on, but the g + 1 group to k are not turned on. When a disconnection occurs in any one of the linear layer groups up to the group or in a plurality of layer groups, the bipolar transistor corresponding to the linear layer group in which the disconnection has occurred is turned on, and the next linear layer group is turned on. If there is no disconnection, a current flows through this linear layer group, and if this linear layer group is also disconnected, a current flows through the next dabipolar transistor. Further, if the wire is broken after that, the same operation is performed. That is, when a disconnection occurs in any of the linear layer groups, the bipolar transistor corresponding to the linear layer group functions as a bypass and the current continues to flow, so that even if the function as a coil is slightly deteriorated, the function remains. It will be possible to prevent it from being completely lost. Similarly, when a disconnection occurs in any one group or a plurality of linear layer groups from the first group to the g group, the bipolar transistor corresponding to the disconnected linear layer group is turned on. If there is no disconnection in the next linear layer group, a current flows through this linear layer group, and if this linear layer group is also disconnected, a current flows through the next bipolar transistor. Further, if the wire is broken after that, the same operation is performed. That is, when a disconnection occurs in any of the streak layers, the bipolar transistor corresponding to the streak layer functions as a bypass and the current continues to flow, so that the function is complete even if the function as a coil is slightly deteriorated. It will be possible to prevent it from being lost. Further, by providing the photocoupler less than the bipolar transistor, it is possible to exclude some bipolar transistors from the target to be arbitrarily turned on, and it is possible to reduce the number of parts of the coil unit. As a result, it is possible to further suppress the increase in the selling price of the coil unit.

According to the fifth aspect of the present invention, both ends of the coil wire and the vicinity thereof are derived on the side opposite to the winding body portion of the first flange portion or the second flange portion. A diode, a bipolar transistor, or a resistor can be arranged on the surface of the flange portion or the second flange portion opposite to the winding body portion.

According to the sixth aspect of the present invention, it is possible to provide a solenoid capable of preventing functional loss due to disconnection of the coil without hindering the miniaturization of the device.

It is a circuit diagram of the coil unit which concerns on 1st Embodiment of this invention. It is a circuit diagram (1) which shows one Example of the coil unit which concerns on 1st Embodiment of this invention. It is a circuit diagram (2) which shows one Example of the coil unit which concerns on 1st Embodiment of this invention. It is a circuit diagram (3) which shows one Example of the coil unit which concerns on 1st Embodiment of this invention. It is a circuit diagram (4) which shows one Example of the coil unit which concerns on 1st Embodiment of this invention. It is a circuit diagram which shows one Example of the coil unit which concerns on 2nd Embodiment of this invention. It is a circuit diagram which shows one Example of the coil unit which concerns on 3rd Embodiment of this invention. A common component of the coil bobbin of the coil unit according to each embodiment of the present invention is shown, (a) is a cross-sectional view, and (b) is a side view. It is sectional drawing of the coil bobbin of the coil unit which concerns on 1st Embodiment of this invention. It is sectional drawing of the coil bobbin of the coil unit which concerns on 2nd Embodiment of this invention. It is sectional drawing which shows the Lenoid which mounted the coil unit which concerns on the prior art.

First, in order to make it easier to understand the contents of the coil lines shown in FIGS. 8 to 10 of the present case, the coil bobbin is emphasized to be considerably thicker than the diameter and length of the coil bobbin. There is. In the coil unit of each embodiment of the present invention, a coil bobbin may be provided, or conversely, a so-called air-core coil or a bobbinless coil, which is not provided with a coil bobbin, may be provided. In addition, it may be a molded coil in which all or part of the coil wire is sealed in the resin. Further, although the coil line described in each drawing of the present case is described as having a circular cross-sectional shape, it may have any shape such as a so-called flat wire, a square wire, or a hexagonal wire. Further, any cross-sectional shape or manufacturing method may be used as long as it can be used as a coil wire, for example, by rolling a wiring printed on a flexible substrate into a cylindrical shape and superimposing a plurality of sheets to form a coil. .. Further, in the following description, the "wire layer" is a circular shape or a cylindrical shape formed by spirally winding a coil wire (sometimes referred to as a coil wire) for a predetermined number of turns. It is a layer (which may be formed in the shape of a square cylinder, etc.), and is also called "rare" or "layer". Further, the streak layer is often formed by winding a coil streak for several tens of turns, but it may be formed only for one turn. Further, in the present specification and the claims of the present application, there is a part described as "adjacent" such as "adjacent l (2≤l≤n / 2 and l is an integer) layer". "Adjacent" in these means that the streaks are in contact with each other. For example, when l is 2, the first layer, the second layer, the third layer, the fourth layer, and the fifth layer. And the 6th layer, or when m is 4, the 1st to 4th layers, the 5th to 8th layers, and the 9th layer. A series of layers having a relationship such as the streak layer up to the twelfth layer is referred to as "adjacent (stripe layer)". In other words, "adjacent" means, for example, when m = 4, the second line layer one above (outside) and the third line above (outside) one with respect to a certain line layer. A continuous four-layered streak layer formed by winding a coil streak and then winding it repeatedly, such as a strip layer and a fourth striation layer above (outside) the streak layer. Can be defined as referring to the state of. In addition, in the coil unit according to each of the following embodiments, the coil unit having 7 linear layers is described, but it may have 20 layers, 30 layers, or more layers. .. The coil unit according to each of the following embodiments is not particularly limited in use, but is particularly suitable for a linear solenoid, a voice coil motor, a heater, and the like.

The coil unit according to the first embodiment of the present invention will be described. FIG. 1 is a circuit diagram of a coil unit according to the first embodiment of the present invention. In FIG. 1, 10 is a coil unit, 20 is a drive streak layer selection section, 21 is a coil section, D1 to Dn are diodes, Is1 and Is2 are constant current power supplies, L1 to Ln are streak layers, and LEDs 1 to LEDn emit light. Diodes, PC1 to PCn are photocouplers, PTR1 to PTRn are phototransistors, R1 to Rn are resistors, SW is a selection switch, and TR1 to TRn are bipolar transistors.

As shown in FIG. 1, the coil unit 10 according to the first embodiment includes a drive line layer selection unit 20 and a coil unit 21. From the viewpoint of fail-safe, the drive line layer selection unit 20 and the coil unit 21 are electrically insulated by photocouplers PC1 to PCn including light emitting diodes LEDs 1 to LEDn and phototransistors PTR1 to PTRn, respectively. Further, the drive line layer selection unit 20 uses the constant current power supply Is1 as a power source, and the coil unit 21 uses the constant current power source Is2 as a power source, and constitutes circuits of different systems from each other. Further, the linear layers L1 to Ln of the coil portion 21 will be described later. It is a streak layer in one coil. In one coil, the length of the coil strips constituting each strip layer gradually increases from the lower (inner) layer to the upper (outer) layer. Therefore, the strength of the magnetic field generated by each streak layer also gradually increases from the lower (inner) layer to the upper (outer) layer. The constant current power supply Is1 and the constant current power supply Is2 do not constitute the coil unit 10. It is desirable that the drive line layer selection unit 20 is incorporated in a coil bobbin constituting the coil unit 21 as described later, and the drive line layer selection unit 20 and the coil unit 21 are integrated. PC1 to PCn are composed of separate light emitting diodes and phototransistors, and the drive line layer selection section 20 and the coil section 21 are physically completely separated and arranged close to each other. There may be.

The constant current power supply Is1 and the constant current power supply Is2 supply a constant current to the drive line layer selection unit 20 and the coil unit 21. It is particularly desirable that the power supply of the coil unit 21 is a constant current power supply from the viewpoint of suppressing self-induction in the linear layers L1 to Ln, and the power supply of the drive linear layer selection unit 20 also has a circuit configuration. It can be said that a constant current power supply is desirable because it can be simplified. Further, in this embodiment, by providing two power supplies, the constant current power supply Is1 and the constant current power supply Is2, when an abnormality occurs in one power supply, the circuit corresponding to the other is affected. It is configured to be preventable. Although it is possible to provide one constant current power supply, it is desirable to provide it separately from the viewpoint of fail-safe. Further, the constant current power supply Is1 may be shared with the control power supply when the mounted device has a control power supply. Further, the constant current power source Is2 may be shared with the power source for power (driving) when the mounted device has a power source for power (driving).

The drive line layer selection unit 20 includes a selection switch SW and light emitting diodes LEDs 1 to LEDn of the photocouplers PC1 to PCn. The selection switch SW is a switch having mechanical contacts from 0 to n. When 0 is selected in the selection switch SW, the current from the constant current power supply Is1 does not flow to any of the photocouplers PC1 to PCn, so that all the light emitting diodes LEDs 1 to LEDn do not emit light, and eventually all the photos. The phototransistors PTR1 to PTRn of the couplers PC1 to PCn remain in the off state and do not change. Therefore, since none of the bipolar transistors TR1 to TRn is turned on, a current flows through all of the linear layers L1 to Ln. In this state, when nm is selected in the selection switch SW, a current flows from the constant current power supply Is1 to the photocouplers PC1 to PCn-m, the light emitting diodes LEDs 1 to LEDn-m emit light, and these phototransistors PTR1 to PTRn -M turns on. As a result, the bipolar transistors TR1 to TRn-m are also turned on, so that no current flows through the linear layers L1 to Ln-m, but flows through the bipolar transistors TR1 to TRn-m. That is, when nm is selected in the selection switch SW, not only the linear layer Ln-m corresponding to the nm but also all the linear layers from the linear layer L1 to the linear layer Ln-m. It operates so that no current flows. A table that summarizes the above operations is shown at the bottom of FIG.

The selection switch SW is not a mechanical one, and a selection switch may be configured by combining a switch IC, a MOSFET, or the like. In this case, a current may flow through any one or a plurality of photocouplers PC1 to PCn, for example, only the PC3 or selectively flow through the PC1, PC2, and PC5. With this configuration, as described above, the strength of the magnetic field generated by the streak layers L1 to Ln of the coil is different, so that the magnitude of the magnetic field of the required coil unit 10 (for example, a linear solenoid or a voice coil) is required. It is also possible to select a combination of linear layers through which a current flows in the control unit of the device according to the thrust) in the case of a motor, and input this selection result to the drive linear layer selection unit 20 when the coil unit 10 is operated. It will be possible. From another point of view, when it is required to generate a magnetic field of a certain strength with respect to the coil unit 10, a switch having a mechanical contact is provided, and a specific contact is provided at the time of manufacturing the coil unit 10. When it is required to change the time generated by the coil unit 10 according to the size of the load and the change in the ambient temperature, a selection switch is provided by combining a switch IC, MOSFET, etc. It can be said that it is preferable to be able to switch the switch at any time from the control unit of.

As will be described later, the coil portion 21 includes one coil formed by winding a coil wire around one coil bobbin, and the wire layers L1 to Ln constitute the wire layer of this coil. When you are doing it. In addition, the streak layers L1 to Ln are divided into streak layers and then connected to each other. Further, as will be described later, it is also possible to combine a predetermined number of adjacent linear layers into one linear layer group, divide the linear layers into one, and then connect them to each other. The linear layer L1 is the uppermost (outer) layer, the linear layer L2 and the linear layer L3 are the lower (inner) layers in this order, and the linear layer Ln is the lowest (inner) layer. On the contrary, the linear layer Ln is the uppermost (outer) layer, and the lower (inner) layer is in the order of the linear layer Ln-1 and the linear layer Ln-2. , The linear layer L1 may be the lowermost (inner) layer. Regardless of the order, the linear layers L1 to Ln are always connected in series. Further, this coil is connected to the constant current power supply Is2 and generates a magnetic field when a current is supplied from the constant current power supply Is2.

Further, for the linear layers L1 to Ln, an operation setting element group including diodes D1 to Dn and resistors R1 to Rn is connected in parallel between the collector electrode and the emitter electrode of the bipolar transistors TR1 to TRn, respectively. .. Further, the base electrodes of the bipolar transistors TR1 to TRn are connected to the midpoints of the diodes D1 to Dn and the resistors R1 to Rn, respectively. In addition, in the bipolar transistors TR1 to TRn, the voltage applied to the operation setting element group including the diodes D1 to Dn and the resistors R1 to Rn is applied when the linear layers L1 to Ln connected in parallel are disconnected. As the voltage rises, the voltage between the base electrode and the emitter electrode also rises, and a current flows between the collector electrode and the emitter electrode, in other words, the bipolar transistor corresponding to the broken streak layer is turned on. That is, although it depends on the characteristics of the coils composed of the linear layers L1 to Ln, the characteristics of the bipolar transistors TR1 to TRn, and the ambient temperature, for example, for the linear layers L1 to L10 of 10 layers, the bipolar transistors TR1 to TR10 and the diode D1 When the operation setting element group including the resistors R1 to R10 is provided in parallel, the applied voltage before the disconnection is about 0.1 V, and after the disconnection, the applied voltage rises to about 0.6 V. In this way, the voltage applied to the bipolar transistor corresponding to the broken streak layer greatly rises, so that the bipolar transistor is turned on and the bipolar transistor becomes a current path instead of the coil.

The operation setting element group consisting of the diodes D1 to Dn and the resistors R1 to Rn are arranged in series with each other, and the diodes D1 to Dn are arranged on the current supply side of the constant current power supply Is2 and the resistors R1 to Rn are arranged on the current feedback side. There is. The resistors R1 to Rn have a forward characteristic such that the bipolar transistors TR1 to TRn are turned on when the linear layers L1 to Ln connected in parallel are disconnected. In addition, it prevents a reverse current from flowing due to self-induction of the linear layers L1 to Ln. The resistors R1 to Rn have a resistance value at which no current flows through the diodes D1 to Dn. That is, the operation setting element group including the diodes D1 to Dn and the resistors R1 to Rn has a function of setting the operation of the coil unit 21. Each of the bipolar transistors connected in parallel has a resistance value to be turned on when any of the linear layers L1 to Ln is not broken. The diodes D1 to Dn are all resistors, that is, they can be configured by two resistors in which the operation setting element group is connected in series, but the characteristics of the phototransistors PTR1 to PTRn and the linear layer From the viewpoint of preventing the flow of reverse current due to self-induction of L1 to Ln, a configuration in which a diode and a resistance are connected in series is highly desirable.

As described above, the phototransistors PTR1 to PTRn of the photocouplers PC1 to PCn are connected in parallel to the diodes D1 to Dn. Further, the phototransistors PTR1 to PTRn are turned on when the light emitting diodes LEDs1 to LEDn emit light, and the bipolar transistors TR1 to TRn are further turned on. Therefore, when the photocouplers PC1 to PCn operate, the bipolar transistors TR1 to TRn are turned on regardless of the presence or absence of disconnection of the linear layers L1 to Ln. With this configuration, any of the bipolar transistors TR1 to TRn can be turned on by operating the selection switch SW, so that the coil unit 10 generates a magnetic force according to the device to be mounted. It will be possible to adjust. As a result, since the coil unit having the same configuration can be mounted on various devices, it is possible to reduce the manufacturing cost and suppress the increase in the selling price by mass-producing the coil unit having the same configuration. In addition, the coil unit can be made redundant by mounting a coil unit that exceeds the originally required number of streak layers, that is, has an excessive streak layer. To explain by giving an example, where a coil with 26 streaks is originally required, a coil unit having a coil with 30 streaks is intentionally mounted, and then only on the 26 streaks. Use by passing an electric current. When a disconnection occurs in the four layers, a magnetic field of the required strength can be obtained by passing a current through the four layers that are not in use, and the number of strands required under normal conditions is required. By passing a current only through the layer, it is possible to obtain a magnetic field of the required strength and not to generate a magnetic field of excessive strength at the same time.

Subsequently, one embodiment of the coil unit according to the first embodiment of the present invention will be described. FIG. 2 is a circuit diagram (1) showing an embodiment of the coil unit according to the first embodiment of the present invention. In FIG. 2, 11 is a coil unit, 22 is a drive line layer selection part, 23 is a coil part, D5 to D7 are diodes, L5 to L7 are line layers, LEDs 5 to LED7 are light emitting diodes, and PC5 to PC7 are photocouplers. , PTR5 to PTR7 are phototransistors, R5 to R7 are resistors, SW is a selection switch, TR5 to TR7 are bipolar transistors, and other reference numerals are the same as those in FIG. Further, FIG. 3 is a circuit diagram (2) showing an embodiment of the coil unit according to the first embodiment of the present invention. The reference numerals used in FIG. 3 are all the same as those used in FIG. Further, FIG. 4 is a circuit diagram (3) showing an embodiment of the coil unit according to the first embodiment of the present invention. The reference numerals used in FIG. 4 are all the same as those used in FIG. In addition, FIG. 5 is a circuit diagram (4) showing an embodiment of the coil unit according to the first embodiment of the present invention. The reference numerals used in FIG. 5 are all the same as those in FIG. Further, FIG. 8 shows a common component of the coil bobbin of the coil unit according to each embodiment of the present invention, (a) is a cross-sectional view, and (b) is a side view. In FIG. 8, 40 is a coil bobbin, 41 is a first flange portion, 42 is a second flange portion, 43 is a winding body portion, 44 is a first slit, 45 is a second slit, and 46 is a third slit. , 47 is a fourth slit, 48 is a hollow portion, 49 is a coil, and other reference numerals are the same as those in FIG. 2. Further, FIG. 9 is a cross-sectional view of the coil bobbin of the coil unit according to the first embodiment of the present invention. In FIG. 9, 50 is a coil, 51 is a first out-licensing part of the first linear layer, 52 is a first out-licensing part of the second streak layer, and 53 is a first out-licensing part of the third streak layer. 54 is the first derivation part of the fourth streak layer, 55 is the first derivation part of the fifth streak layer, 56 is the first derivation part of the sixth streak layer, and 57 is the seventh streak layer. 1 is the first out-licensing part, 61 is the second out-licensing part of the first streak layer, 62 is the second out-licensing part of the second streak layer, 63 is the second out-licensing part of the third streak layer, and 64 is. The second derivation part of the fourth streak layer, 65 is the second derivation part of the fifth streak layer, 66 is the second derivation part of the sixth streak layer, and 67 is the second derivation part of the seventh streak layer. 2 It is a derivation part, and the other reference numerals are the same as those in FIG.

As shown in FIG. 2, the coil unit 11 which is an embodiment of the coil unit according to the first embodiment provides a detour circuit at the time of disconnection with respect to the seven-layer linear layers L1 to L7 of the coil portion 23. In order to form the bipolar transistors TR1 to TR7, an operation setting element group including diodes D1 to D7 and resistors R1 to R7 is provided. Further, in order to adjust the number of energized layers of the linear layers L1 to L7, photocouplers PC1 to PC7 provided with light emitting diodes LEDs1 to LED7 and phototransistors PTR1 to PTR7 are provided, and the drive linear layer selection unit 22 is further provided. A selection switch SW is provided. The above configuration is only one embodiment of the coil unit according to the first embodiment. For example, in the case of a coil of a linear solenoid or a voice coil motor, the coil has 20 or 30 layers. Alternatively, the number of layers is often higher than this. Further, if it is a coil of an induction heating device (IH), an element constituting a resonance circuit may be provided in the drive line layer selection unit 22 or the coil unit 23.

A configuration common to the coils of the coil unit according to the embodiment of the present invention will be described. As shown in FIG. 8, the coil wire is wound around the winding body portion 43 so as to be in contact with each other between the first flange portion 41 and the second flange portion 42 of the coil bobbin 40, and the first coil 49 is formed. Line L1, 2nd line layer L2, 3rd line layer L3, 4th line layer L4, 5th line layer L5, 6th line layer L6 and 7th line The strip layers L7 are formed so as to be laminated. Further, the first flange portion 41 and the second flange portion 42 are formed with a first slit 44 and a second slit 45, and a third slit 46 and a fourth slit 47. The first slit 44 and the second slit 45, and the third slit 46 and the fourth slit 47 are cut at positions facing each other through the hollow portion 48 and up to the winding body portion 43. Is formed in. Further, in the hollow portion 48 of the winding body portion 43, for example, a movable magnetic pole, a permanent magnet, a rotor, a heating target, and the like are arranged according to the equipment to be mounted. The above configuration is the same in other embodiments described below.

As described above, the first slit 44 and the second slit 45, and the third slit 46 and the fourth slit 47 are deeply cut so as to reach the winding body portion 43, and thus the configuration described below will be described. Can be easily realized. That is, as shown in FIG. 9, the coil 50 of the coil unit 11 has a first linear layer L1, a second linear layer L2, a third linear layer L3, a fourth linear layer L4, and a third. The first lead-out portion 51 of the first linear layer, which is one end of the linear layer L5, the sixth linear layer L6, and the seventh linear layer L7 and the vicinity thereof, is the second. First out-licensing part 52 of the streak layer, first out-licensing part 53 of the third streak layer, first out-licensing part 54 of the fourth streak layer, first out-licensing part 55 of the fifth streak layer, first The first lead-out portion 56 of the streak layer 6 and the first lead-out portion 57 of the seventh streak layer are led out to the outside via the third slit 46 of the second flange portion 42, respectively. Similarly, the first linear layer L1, the second linear layer L2, the third linear layer L3, the fourth linear layer L4, the fifth linear layer L5, and the sixth linear layer L6. And the other end of the 7th streak layer L7 and its vicinity, the 2nd derivation part 61 of the 1st streak layer, the 2nd derivation part 62 of the 2nd streak layer, and the 3rd streak. The second derivation part 63 of the layer, the second derivation part 64 of the fourth streak layer, the second derivation part 65 of the fifth streak layer, the second derivation part 66 and the seventh of the sixth streak layer. The second lead-out portion 67 of the streak layer is led out to the outside via the first slit 44 of the first flange portion 41, respectively. Therefore, although not particularly shown, it is possible to easily connect the bipolar transistors TR1 to TR7, the diodes D1 to D7, the resistors R5 to R7, and the like to these out-licensing units. As a result, a small substrate is attached to either or both of the first flange portion 41 and the second flange portion 42, and all the coil units 11 such as the photocouplers PC1 to PC7 and the selection switch SW have on this substrate. It can be easily realized that the element of the above is attached to the coil bobbin 40.

Further, the operation of this embodiment will be described. In the configuration described above, as shown in FIG. 2, when the contact 0 of the selection switch SW is selected, all the streak layers from the lowermost (inner) L1 to the uppermost (outer) L7 are formed. Current flows. Further, as shown in FIG. 3, when the contact 1 of the selection switch SW is selected, a current flows through the lowermost (inner) linear layer other than L1. Further, as shown in FIG. 4, when the contact 4 of the selection switch SW is selected, no current flows through the linear layers L1 to L4, and current flows only through the linear layers L5 to L7. On the contrary, from the top (outside) to the bottom (inside), the first strip layer L1 to the seventh strip layer L7 may be formed. In this case, the streak layer through which the current flows when the selection switch SW is created, for example, when the contact 1 is selected, the current flows through the streak layer other than the seventh streak layer L7 on the uppermost side (outer side). For example, the streak layer selected by the selection switch SW is reversed. In addition, as shown in FIG. 5, when a disconnection occurs in the linear layer L3, the bipolar transistor TR3 is immediately turned on and becomes a current detour. It should be noted that the linear layer through which the current flows can be similarly selected for the contacts 2, 3, 5 to 7 of the selection switch SW not described above, and even when the linear layers L1, L2 and L4 to L7 are disconnected. The bipolar transistors TR1, TR2, and TR4 to TR7 are turned on to form a current detour. Further, as described above, when it is required to change the generation time of the coil unit 10 according to a change in the load size or the atmospheric temperature, a switch IC, a MOSFET, or the like is combined instead of the selection switch SW. It is also possible to provide a selection switch so that the switch can be switched at any time from the control unit of the device.

In the above configuration, if the linear layers L1 to the linear layer Ln of the coil 50 are normal, none of the bipolar transistors TR1 to TR7 is turned on, but the linear layers from the linear layer L1 to the linear layer Ln are not turned on. If a disconnection occurs in any one of the layers or a plurality of layers, the bipolar transistors TR1 to TR7 corresponding to the disconnected linear layer are turned on, and if there is no disconnection in the next linear layer, the bipolar transistors TR1 to TR7 are turned on. A current flows through this streak layer, and if this streak layer is also broken, a current flows through the next bipolar transistor. Further, if the wire is broken after that, the same operation is performed. That is, when a disconnection occurs in any of the streak layers, the bipolar transistor corresponding to that streak layer functions as a bypass and the current continues to flow, so that the function is completely reduced even if the function as a coil is slightly deteriorated. You will be able to prevent it from being lost. Further, since any of the bipolar transistors TR1 to TR7 can be turned on by operating the selection switch SW, it is possible to adjust so as to generate a magnetic force according to the device to be mounted. As a result, since the coil unit 11 having the same configuration can be mounted on various devices, it is possible to reduce the manufacturing cost and suppress the increase in the selling price by mass-producing the coil unit 11 having the same configuration.

Next, the coil unit according to the second embodiment of the present invention will be described. FIG. 6 is a circuit diagram showing an embodiment of the coil unit according to the second embodiment of the present invention. In FIG. 6, 12 is a coil unit, 24 is a drive streak layer selection section, 25 is a coil section, L1 to L8 are streak layers, SW is a selection switch, and other reference numerals are the same as those in FIG. .. Further, FIG. 10 is a cross-sectional view of the coil bobbin of the coil unit according to the second embodiment of the present invention. In FIG. 10, 30 is a coil, 31 is a lead-out portion of the first striation layer, 32 is a lead-out portion of the second striation layer, 33 is a lead-out portion of the third striation layer, and 34 is a fourth line. Derivation part of the streak layer, 35 is the derivation part of the 5th streak layer, 36 is the derivation part of the 6th streak layer, 37 is the derivation part of the 7th streak layer, 38 is the derivation part of the 8th streak layer. The other reference numerals are the same as those shown in FIG.

As shown in FIG. 6, the coil unit 12 according to the second embodiment of the present invention includes 14 layers of the linear layers L1 to L8 in the coil portion 25, and the linear layers L1 and L2 and the strands are provided. Layers L3 and L4, striation layers L5 and L6, striation layers L7 and L8 are each grouped into one group of striations, and a detour is formed for these four groups of striation layers at the time of disconnection. An operation setting element group including bipolar transistors TR1 to TR4, diodes D1 to D4, and resistors R1 to R4 is provided. Further, in order to adjust the number of energized groups of the four linear layer groups, photocouplers PC1 to PC4 provided with light emitting diodes LEDs 1 to LED4 and phototransistors PTR1 to PTR4 are provided, and a drive linear layer selection unit 22 is further provided. Is provided with a selection switch SW. Further, as shown in FIG. 10, in the coil 30, the lead-out portion 31 of the first strip layer, the lead-out portion 32 of the second strip layer, the lead-out portion 33 of the third strip layer, and the fourth wire Derivation section 34 of the streak layer, derivation section 35 of the fifth streak layer, derivation section 36 of the sixth streak layer, lead section 37 of the seventh streak layer, and lead section 38 of the eighth streak layer. Is led out from the second flange portion 42 side to the outside. Since the coil 30 has two linear layers as one group, it is not necessary to derive the coil 30 from the first flange portion 41 side. The other configurations of the drive line layer selection unit 24 and the coil unit 25 are the same as those of the coil unit 11.

As described above, in the coil unit 12 according to the second embodiment of the present invention, the two strip layers are set as one group, and the bipolar transistors TR1 to TR4 are used for the four strip layer groups. Since the operation setting element group consisting of the diodes D1 to D4 and the resistors R1 to R4, the photocouplers PC1 to PC4 provided with the light emitting diodes LEDs1 to LED4 and the phototransistors PTR1 to PTR4 are provided, the current bypass circuit is provided for two layers. This is a configuration suitable for applications in which miniaturization is particularly required because the number of parts can be significantly reduced, although the reliability of the coil unit is slightly reduced.

Further, the coil unit according to the third embodiment of the present invention will be described. FIG. 7 is a circuit diagram showing an embodiment of the coil unit according to the third embodiment of the present invention. In FIG. 7, 13 is a coil unit, 26 is a drive line layer selection unit, 27 is a coil unit, SW is a selection switch, and other reference numerals are the same as those in FIG. 2.

The coil unit 13 according to the third embodiment has a configuration in which the photocouplers PC6 and PC7 are excluded from the coil unit 11. For example, when the strength of the magnetic field generated by the linear layers L6 and L7 is required at least, the number of parts to be provided can be reduced by not providing the photocouplers PC6 and PC7. On the other hand, since the diodes D6 and D7, the resistors R6 and R7, and the bipolar transistors TR6 and TR7 are provided in the same configuration as the coil unit 11, a current detour is secured when the linear layers L6 and L7 are disconnected. .. The other configurations of the drive line layer selection unit 26 and the coil unit 27 are the same as those of the coil unit 11.

The coil unit 13 according to the third embodiment of the present invention can reduce the number of parts to be provided by not providing the photocouplers PC6 and PC7, and one or more of the linear layers L1 to L7. Similar to the coil unit 11, the advantage that the function is not completely lost even if the electric wire is generated in the layer is obtained. Therefore, although the reliability of the coil unit is slightly lowered, the number of parts can be significantly reduced, and the configuration is suitable for applications in which miniaturization is particularly required.

The present invention is not limited to the contents described above, and the scope described in each claim is, for example, applying the coil bobbin of FIG. 8 (b) to the bobbin of the coil unit shown in FIG. 7 (a). It can be applied to various solenoids as long as it does not deviate from.

10 Coil unit 11 Coil unit 12 Coil unit 13 Coil unit 20 Drive streak layer selection section 21 Coil section 22 Drive streak layer selection section 23 Coil section 24 Drive streak layer selection section 25 Coil section 26 Drive streak layer selection section 27 Coil part 30 Coil 31 Derivation part of the first streak layer 32 Derivation part of the second streak layer 33 Derivation part of the third streak layer 34 Derivation part of the fourth streak layer 35 Fifth streak Layer derivation part 36 6th streak layer derivation part 37 7th streak layer derivation part 38 8th streak layer derivation part 40 Coil bobbin 41 1st flange part 42 2nd flange part 43 winding Body 44 1st slit 45 2nd slit 46 3rd slit 47 4th slit 48 Hollow part 49 Coil 50 Coil 51 1st lead-out part of 1st streak layer 52 1st of 2nd streak layer 1 Derivation part 53 First derivation part of the third streak layer 54 First derivation part of the fourth streak layer 55 First derivation part of the fifth streak layer 56 First derivation of the sixth streak layer Part 57 1st out-licensing part of the 7th streak layer 61 2nd out-licensing part of the 1st streak layer 62 2nd out-licensing part of the 2nd streak layer 63 2nd out-out part of the 3rd streak layer 64 2nd derivation part of the 4th streak layer 65 2nd derivation part of the 5th streak layer 66 2nd derivation part of the 6th streak layer 67 2nd derivation part of the 7th streak layer 70 solenoid 80 Coil 81 Coil bobbin 82 1st flange 83 Winding body 84 2nd flange 85 1st wiring hole 86 2nd wiring hole 87 1st end area 88 2nd end area 89 Terminal part 90 Fixed Pole 91 Movable magnetic pole 92 Auxiliary magnetic pole 93 Opposing part 94 Case 95 Fixing plate 96 Shaft 97 Sleeve 98 Connector 99 Insertion part

Claims (6)

A coil unit mounted on a device
A coil formed by winding coil strips from the first layer to the nth (n ≧ 2) layer so as to form n strip layers.
A group of diodes and resistors connected in series with each other, and n groups from the first group to the nth group connected in parallel to the linear layers from the first layer to the nth layer, respectively. Operation setting element group and
The diode is connected in parallel to the linear layer from the first layer to the nth layer, and the base electrode constitutes the operation setting element group from the first group to the nth group. Nth bipolar transistor from the first to the nth connected to the midpoint of the resistor and the resistor, respectively.
A light emitting diode and a phototransistor are provided, and a collector electrode and an emitter electrode of the phototransistor are connected in parallel to the diode of the operation setting element group from the first group to the nth group, respectively. N photocouplers up to the nth and
Any of the light emitting diodes of the photocoupler from the first to the nth, which is connected to the light emitting diode of the photocoupler from the first to the nth and the first power source. It has a selection switch in which m (n> m ≧ 1) or all of them can be connected to the first power source.
In the operation setting element group from the first group to the n group, the diode is arranged on the current supply side of the second power supply, and the resistance is arranged on the current feedback side of the second power supply. , The diode is arranged so as to be forward with respect to the direction from the current supply side of the second power supply to the current feedback side.
In the bipolar transistor from the first to the nth, the collector electrode of the first bipolar transistor is connected to the current supply side of the second power supply, and the second to the nth bipolar transistor is connected to the current supply side. The collector electrodes of the bipolar transistors are connected to the emitter electrodes of the first to n-1 bipolar transistors, respectively, and the emitter electrodes of the nth bipolar transistors are connected to the current feedback side of the second power supply. When the linear layers connected in parallel were not disconnected, the strands were not turned on by the voltage applied from the second power source, and the linear layers connected in parallel were disconnected. Sometimes turned on by the voltage applied from the second power source,
In the photocoupler from the first to the nth, the light emitting diode emits light by the current supplied from the first power source, and the phototransistor is turned on by the light emission of the light emitting diode to turn on the second power source. The bipolar transistor to which the base electrode is connected is turned on at the midpoint between the diode and the resistor constituting the operation setting element group including the diode connected in parallel by amplifying the current from the diode. A coil unit characterized by being made in this way. A coil unit mounted on a device
A coil formed by winding coil strips from the first layer to the nth (n ≧ 4) layer so as to form n strip layers.
The first group of the linear layers of the adjacent l (2 ≦ l ≦ n / 2 and l is an integer) layer in the linear layer from the first layer to the j (n> j ≧ 1) layer. The kth linear layer group from the kth (k = n / m, and k is an integer obtained by rounding off fractions) to the kth group, and these k linear layer groups are connected in parallel and are connected to each other. The operation setting element group of k group from the first group to the k group, which is a group of integers and resistors connected in series,
The diode which is connected in parallel to the linear layer group from the first group to the k group and whose base electrode constitutes the operation setting element group from the first group to the k group. The k bipolar transistors from the first to the kth connected to the midpoint between the resistor and the resistor, respectively.
A light emitting diode and a phototransistor are provided, and a collector electrode and an emitter electrode of the phototransistor are connected in parallel to the diode of the operation setting element group from the first group to the kth group, respectively. With k photocouplers up to the kth
Any of the light emitting diodes of the photocoupler from the first to the kth, which is connected to the light emitting diode of the photocoupler from the first to the kth and the first power source. It has a selection switch in which m (k> m ≧ 1) or all of them can be connected to the first power source.
In the operation setting element group from the first group to the k group, the diode is arranged on the current supply side of the second power supply, and the resistance is arranged on the current feedback side of the second power supply. , The diode is arranged so as to be forward with respect to the direction from the current supply side of the second power supply to the current feedback side.
In the bipolar transistor from the first to the kth, the collector electrode of the first bipolar transistor is connected to the current supply side of the second power source, and the second to the kth is the same. The collector electrode of the bipolar transistor is connected to the emitter electrode of the bipolar transistor of the first to k-1 respectively, and the emitter electrode of the bipolar transistor of the kth is connected to the current feedback side of the second power supply. When the linear layers connected in parallel were not disconnected, the strands were not turned on by the voltage applied from the second power source, and the linear layers connected in parallel were disconnected. Sometimes turned on by the voltage applied from the second power source,
In the photocoupler from the first to the kth, the light emitting diode emits light by the current supplied from the first power source, and the phototransistor is turned on by the light emission of the light emitting diode to turn on the second power source. The bipolar transistor to which the base electrode is connected is turned on at the midpoint between the diode and the resistor constituting the operation setting element group including the diode connected in parallel by amplifying the current from the diode. A coil unit characterized by being made in this way. A coil unit mounted on a device
A coil formed by winding coil strips from the first layer to the nth (n ≧ 2) layer so as to form n strip layers.
A group of diodes and resistors connected in series with each other, and n groups from the first group to the nth group connected in parallel to the linear layers from the first layer to the nth layer, respectively. Operation setting element group and
The diode is connected in parallel to the linear layer from the first layer to the nth layer, and the base electrode constitutes the operation setting element group from the first group to the nth group. Nth bipolar transistor from the first to the nth connected to the midpoint of the resistor and the resistor, respectively.
A light emitting diode and a phototransistor are provided, and the collector electrode and the emitter electrode of the phototransistor are parallel to the diode of the operation setting element group from the first group to the h (n> h ≧ 2) group, respectively. The h photocouplers from the first to the connected h
Any of the light emitting diodes of the photocoupler from the first to the h, which are connected to the light emitting diode of the photocoupler from the first to the h and the first power source. It has a selection switch in which m (h> m ≧ 1) or all of them can be connected to the first power source.
In the operation setting element group from the first group to the n group, the diode is arranged on the current supply side of the second power supply, and the resistance is arranged on the current feedback side of the second power supply. , The diode is arranged so as to be forward with respect to the direction from the current supply side of the second power supply to the current feedback side.
In the bipolar transistors 1 to n, the collector electrode of the first bipolar transistor is connected to the current supply side of the second power supply, and the bipolar transistor is connected to the current supply side.
The collector electrodes of the bipolar transistors from the second to the nth are connected to the emitter electrodes of the bipolar transistors of the first to n-1 respectively, and the emitter electrodes of the bipolar transistors of the nth are the first. It was connected to the current feedback side of the power supply of 2, and was not turned on by the voltage applied from the second power supply when the linear layer connected in parallel was not broken, and was connected in parallel. When a disconnection occurs in the strip layer, it is turned on by the voltage applied from the second power source.
In the photocoupler from the first to the hth, the light emitting diode emits light by the current supplied from the first power source, and the phototransistor is turned on by the light emission of the light emitting diode to turn on the second power source. The bipolar transistor to which the base electrode is connected is turned on at the midpoint between the diode and the resistor constituting the operation setting element group including the diode connected in parallel by amplifying the current from the diode. A coil unit characterized by being made in this way. A coil unit mounted on a device
A coil formed by winding coil strips from the first layer to the nth (n ≧ 4) layer so as to form n strip layers.
The first group of the linear layers of the adjacent l (2 ≦ l ≦ n / 2 and l is an integer) layer in the linear layer from the first layer to the j (n> j ≧ 1) layer. The kth linear layer group from the kth (k = n / m, and k is an integer obtained by rounding off fractions) to the kth group, and these k linear layer groups are connected in parallel and are connected to each other. The operation setting element group of k group from the first group to the k group, which is a group of integers and resistors connected in series,
The diode which is connected in parallel to the linear layer group from the first group to the k group and whose base electrode constitutes the operation setting element group from the first group to the k group. The k bipolar transistors from the first to the kth connected to the midpoint between the resistor and the resistor, respectively.
A light emitting diode and a phototransistor are provided, and the collector electrode and the emitter electrode of the phototransistor are parallel to the diode of the operation setting element group from the first group to the g (k> g ≧ 2) group , respectively. With g photocouplers from the first to the g connected,
Any of the light emitting diodes of the photocoupler from the first to the gth, which is connected to the light emitting diode of the photocoupler and the first power source, and from the first to the g . It has a selection switch in which m (g> m ≧ 1) or all of them can be connected to the first power source.
In the operation setting element group from the first group to the k group, the diode is arranged on the current supply side of the second power supply, and the resistance is arranged on the current feedback side of the second power supply. , The diode is arranged so as to be forward with respect to the direction from the current supply side of the second power supply to the current feedback side.
In the bipolar transistor from the first to the kth, the collector electrode of the first bipolar transistor is connected to the current supply side of the second power source, and the second to the kth is the same. The collector electrode of the bipolar transistor is connected to the emitter electrode of the bipolar transistor of the first to k-1 respectively, and the emitter electrode of the bipolar transistor of the kth is connected to the current feedback side of the second power supply. When the linear layers connected in parallel were not disconnected, the strands were not turned on by the voltage applied from the second power source, and the linear layers connected in parallel were disconnected. Sometimes turned on by the voltage applied from the second power source,
In the photocoupler from the first to the gth, the light emitting diode emits light by the current supplied from the first power source, and the phototransistor is turned on by the light emission of the light emitting diode to turn on the second power source. The bipolar transistor to which the base electrode is connected is turned on at the midpoint between the diode and the resistor constituting the operation setting element group including the diode connected in parallel by amplifying the current from the diode. A coil unit characterized by being made in this way. Further, it has a coil bobbin having a winding body portion formed in a substantially cylindrical shape, and a first flange portion and a second flange portion provided at both ends of the winding body portion or in the vicinity thereof.
One or both of the first flange portion and the second flange portion is formed with a slit extending from the edge portion to the winding body portion or the vicinity portion.
The coil is wound around the winding body portion, and among the linear layers from the first layer to the nth layer, one of the linear layers and the linear adjacent to the linear layer. Both end portions of the coil strips constituting the layer and portions in the vicinity thereof are led out to the opposite sides of the winding body portion via the slits of the first flange portion or the second flange portion, respectively, and each other. The coil unit according to any one of claims 1 to 4, wherein the coil unit is connected. A solenoid comprising the coil unit according to claim 5.

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