JP7028032B2 - Power supply and transformer - Google Patents

Description

The present invention relates to a power supply and a transformer comprising a core.

Conventionally, a power supply device including a core is known (see, for example, Patent Document 1).

The above-mentioned Patent Document 1 discloses a DC / DC converter (hereinafter, referred to as “converter”) including a core. The converter includes a transformer including a primary winding, a secondary winding, and a core around which the primary and secondary windings are wound, a temperature sensor, a temperature detection circuit, and switching control. A circuit is provided. The temperature sensor includes a first fixing bracket arranged on the upper surface of the transformer, a temperature sensing portion arranged on the upper surface of the first fixing bracket, and a second fixing bracket covering the upper side of the temperature sensing portion. The temperature detection circuit includes a comparator circuit, and the comparator circuit is configured to compare the voltage value of the detection signal from the temperature sensitive unit with the reference voltage. Then, the switching control circuit performs control to reduce (perform a protection operation) the primary current flowing in the primary winding based on the comparison result of the comparator circuit indicating that the temperature of the core is equal to or higher than the Curie temperature. It is configured as follows.

Japanese Unexamined Patent Publication No. 2002-281748

However, in the converter of Patent Document 1, the temperature sensor covers the first fixing bracket arranged on the upper surface of the transformer, the temperature sensing portion arranged on the upper surface of the first fixing bracket, and the upper side of the temperature sensing portion. Since it includes two fixing brackets, there is an inconvenience that the transformer becomes large in the vertical direction. Therefore, in order to prevent the transformer from becoming larger in the vertical direction, it is conceivable to arrange a temperature sensor inside the winding of the primary winding or the secondary winding. However, such a configuration requires a separate configuration for ensuring the insulation between the temperature sensor and the wiring connected to the temperature sensor and the core and the primary winding or the secondary winding. The structure becomes complicated. That is, the conventional converter (power supply device) has a problem that the transformer (transformer) becomes large or complicated when it is configured to perform a protective operation when the temperature of the transformer rises.

The present invention has been made to solve the above-mentioned problems, and one object of the present invention is a transformer even when it is configured to perform a protective operation when the temperature of the transformer rises. Is to provide a power supply and a transformer capable of suppressing the increase in size and complexity.

In order to achieve the above object, the power supply device according to the first aspect of the present invention includes a primary winding through which a primary current flows, a secondary winding through which a secondary current flows, a primary winding and a secondary winding. A transformer including a plurality of cores in which a wire is wound to form a magnetic circuit, an exciting current detector that detects an exciting current based on a primary current and a secondary current, and an exciting current that increases the exciting current. Based on this, the transformer is provided with a protection circuit unit which is a circuit that performs a protection operation for the transformer, and the transformer is filled between a plurality of cores and has an insulating resin having a thermal expansion coefficient larger than the thermal expansion coefficient of the core. In addition to including a heat-expanding member having an insulating rubber, the heat-expanding member is configured to heat-expand to increase the distance between a plurality of cores, thereby increasing the exciting current.

In the power supply device according to the first aspect of the present invention, as described above, the transformer is filled between a plurality of cores and has an insulating resin or an insulating rubber having a coefficient of thermal expansion larger than the coefficient of thermal expansion of the cores. A thermal expansion member having the above is provided. Further, the transformer is configured so that the exciting current increases as the thermal expansion member thermally expands and the distance between the plurality of cores increases. Then, the protection circuit unit is configured to perform a protection operation for the transformer based on the increase in the exciting current. As a result, when the temperature of the transformer rises, the thermal expansion member that functions as a member for ensuring the insulation between the core and the primary winding or the secondary winding thermally expands, so that the exciting current becomes large. Based on the above, it is possible to perform a protective operation against the transformer. That is, the thermal expansion member can have both a function as a member for ensuring insulation and a function as a temperature sensor without providing a dedicated temperature sensor in the transformer. Therefore, unlike the case where the dedicated temperature sensor is arranged on the upper surface of the transformer, it is possible to prevent the transformer from becoming large in size. Further, unlike the case where the dedicated temperature sensor is arranged between the core and the primary winding or the secondary winding, it is possible to suppress the complicated structure of the transformer. As a result, it is possible to prevent the transformer from becoming large and complicated even when the transformer is configured to perform a protective operation when the temperature rises.

In the power supply according to the first aspect, preferably, the thermal expansion member includes a thermosetting resin filled between the primary winding and the secondary winding and the plurality of cores. With this configuration, in a transformer, a thermosetting resin is filled between the primary winding and the secondary winding and a plurality of cores and thermoset, thereby forming the thermosetting resin as a core. A plurality of members can be easily arranged in the gap between the primary winding and the secondary winding as a member for ensuring insulation, and the exciting current is increased based on the temperature rise of the transformer. It can be easily placed between the cores.

In this case, preferably, the plurality of cores are configured as an annular core, and one core that constitutes a part of the annular core and one core that is arranged so as to face the one core and the other part of the annular core. The thermosetting resin is filled inside the annular core, including the other core that constitutes, and the transformer is one core from the inside to the outside of the annular core as the thermosetting resin thermally expands. By pressing the other core and the other core, the distance between the one core and the other core is increased. With this configuration, the thermosetting resin thermally expands, and the thermosetting resin directly presses the one core and the other core from the inside, increasing the distance between the one core and the other core. be able to. As a result, the magnetic resistance of the annular core can be increased by the thermal expansion of the thermosetting resin, so that the exciting current flowing through the transformer can be easily increased.

In a power supply device in which the distance between the one core and the other core is increased by thermally expanding the thermosetting resin and pressing the one core and the other core, the direction in which the one core and the other core are preferably close to each other is preferable. Further provided with an urging member for urging one core and at least one of the other cores, the transformer has one core and the other from the inside to the outside of the annular core due to thermal expansion of the thermosetting resin. By pressing the core against the urging force of the urging member, the distance between the one core and the other core is increased. Here, when the temperature of the transformer is rising while the temperature of the transformer is less than the upper limit of the allowable temperature, it is not necessary to perform the protective operation. In this case, it may not be preferable to increase the exciting current by increasing the distance between one core and the other core. On the other hand, in the present invention, by providing the urging member as described above, the pressing force by the thermosetting resin in the direction in which the distance between one core and the other core becomes large is relatively small, and the protective operation is performed. When it is not necessary, the urging force of the urging member can keep the distance between one core and the other core small. As a result, it is possible to appropriately protect the transformer without unnecessarily increasing the exciting current.

In the power supply device including the urging member, the thermosetting resin is preferably a resin having a curing temperature range having an upper limit value lower than the upper limit value of the allowable temperature of the transformer, and the transformer is a transformer. When the temperature is below the upper limit of the curing temperature range, the distance between one core and the other core does not change due to the urging by the urging member, and the temperature of the transformer is the upper limit of the curing temperature range. When the value is exceeded, the thermosetting resin is configured to increase the distance between the one core and the other core by pressing the one core and the other core against the urging force of the urging member. ing. With this configuration, when the temperature of the transformer reaches the upper limit of the allowable temperature of the transformer, the temperature exceeds the upper limit of the curing temperature range of the thermosetting resin. As a result, when the temperature of the transformer reaches the upper limit of the allowable temperature of the transformer, the thermosetting resin can press the one core and the other core. As a result, when the temperature of the transformer exceeds the upper limit of the allowable temperature of the transformer, the distance between one core and the other core can be increased more reliably.

In the power supply device according to the first aspect, preferably, the protection circuit unit is configured to control the drive of the switching circuit unit that supplies the primary current to the primary winding, and the thermal expansion member heats up. When the current value of the exciting current becomes equal to or greater than the threshold current value, which is the current value corresponding to the upper limit of the allowable temperature of the transformer, due to the expansion and the increase in the distance between the multiple cores, the transformer is transformed. As a protective operation for the device, it is configured to control the operation of the switching circuit unit so as to limit the current value of the primary current supplied to the primary winding or stop the supply of the primary current. ing. Here, the current value of the exciting current can be acquired (calculated) based on the current value of the primary current and the current value of the secondary current. Then, in general, in the switching circuit section provided in the power supply device, the drive is performed based on the current value of the primary current of the primary winding of the transformer and the current value of the secondary current of the secondary winding. Be controlled. That is, a general power supply device including a switching circuit unit is provided with a configuration for acquiring a current value of a primary current and a current value of a secondary current. Focusing on this, in the present invention, by configuring the protection circuit unit as described above, the exciting current can be obtained by acquiring the current value of the existing primary current and the current value of the secondary current of the power supply device. The current value can be acquired, and the operation of the existing switching circuit unit can be controlled to perform a protective operation against the transformer. As a result, it is possible to prevent the configuration of the protection circuit unit from becoming complicated because the existing configuration can be used.

In this case, preferably, the exciting current detector differs from the current value of the primary current by the current value of the secondary current multiplied by the number of turns of the primary winding and the coefficient related to the number of turns of the secondary winding. Is configured to acquire the current value of the exciting current. With this configuration, even if the number of turns of the primary winding and the number of turns of the secondary winding are different, the current value of the exciting current can be easily obtained by the exciting current detection unit.

In the power supply according to the first aspect, preferably, the thermal expansion member comprises a thermosetting silicone rubber, and the primary winding and the secondary winding include one of copper or aluminum, and a plurality of cores. Includes one of silicon steel plates or ferrites, respectively. With this configuration, the linear expansion coefficient of the thermal expansion member can be made larger than the linear expansion coefficient of both the primary winding and the secondary winding and the plurality of cores, so that the temperature of the transformer can be increased. As a result, the thermal expansion member becomes a thermal expansion amount larger than the thermal expansion amount of the primary winding, the secondary winding and the plurality of cores, so that the thermal expansion amount is easily increased due to the temperature rise of the transformer. The transformer can be easily configured so that the distance between the cores is large.

In the transformer according to the second aspect of the present invention, the primary winding through which the primary current flows, the secondary winding through which the secondary current flows, and the primary winding and the secondary winding are wound to form a magnetic circuit. A plurality of cores constituting the core and a thermal expansion member having an insulating resin or an insulating rubber arranged between the plurality of cores and having a thermal expansion coefficient larger than the thermal expansion coefficient of the core are provided, and the thermal expansion member is heated. It is configured to increase the exciting current by expanding and increasing the distance between the plurality of cores.

In the transformer according to the second aspect of the present invention, by configuring as described above, the transformer becomes larger and more complicated even when it is configured to perform a protective operation when the temperature of the transformer rises. It is possible to provide a power supply device and a transformer capable of suppressing the above.

According to the present invention, as described above, even when the transformer is configured to perform a protective operation when the temperature rises, it is possible to prevent the transformer from becoming large and complicated.

It is a block diagram which shows the whole structure of the power supply apparatus by 1st and 2nd Embodiment of this invention. It is sectional drawing which shows schematically the structure (before thermal expansion) of the transformer by 1st Embodiment of this invention. It is sectional drawing along the line 300-300 of FIG. It is sectional drawing which shows the structure (after thermal expansion) of a part of the transformer by 1st Embodiment of this invention. It is sectional drawing which shows schematically the structure (before thermal expansion) of the transformer by the 2nd Embodiment of this invention. FIG. 5 is a cross-sectional view taken along the line 400-400 of FIG. It is sectional drawing which shows typically the structure (after thermal expansion) of the transformer by the 2nd Embodiment of this invention.

Hereinafter, embodiments embodying the present invention will be described with reference to the drawings.

[First Embodiment]
(Structure of power supply)
The configuration of the power supply device 100 according to the first embodiment will be described with reference to FIGS. 1 to 4.

As shown in FIG. 1, the power supply device 100 transforms (steps up or down) the voltage value of the input power from the DC power supply 101, and outputs the transformed power to the load 102 as DC output power. It is configured. That is, the power supply device 100 is configured as a power conversion device (DC / DC converter). The DC power supply 101 is configured as, for example, a device that converts AC power from a commercial power source into DC power, or a power storage device (battery) that outputs DC power. The load 102 is a device or the like that operates by consuming the output power from the power supply device 100.

The power supply device 100 includes a transformer 1, a current detection unit 2, a switching circuit unit 3, a rectifier circuit unit 4, a control unit 5, a discrimination circuit 6, and wirings 7 and 8. The switching circuit unit 3 is connected to the DC power supply 101 side (primary side) of the transformer 1 via the wiring 7. Further, the rectifier circuit unit 4 is connected to the load 102 side (secondary side) of the transformer 1 via the wiring 8. Then, the switching circuit unit 3 includes a switching element, and based on the control signal (gate drive signal) from the control unit 5, the DC input power from the DC power supply 101 is turned on / off (a state of conducting and a state of disconnecting). By performing the switching), the AC power having the primary current i1 is configured to be output to the transformer 1. Further, the rectifier circuit unit 4 is configured to rectify the AC power having the secondary current i2 output from the transformer 1 to the DC output power and output it to the load 102. The rectifier circuit unit 4 may be provided with not only a rectifier circuit but also a smoothing circuit or the like. Further, the current detection unit 2 is an example of the "exciting current detection unit" in the claims. Further, the control unit 5 and the discrimination circuit 6 are examples of the "protection circuit unit" in the claims.

As shown in FIG. 2, the transformer 1 (transformer) has a primary winding 11 through which a primary current i1 flows, a secondary winding 12 through which a secondary current i2 flows, and a primary winding 11 and a secondary winding. Includes an annular core 13 around which the wire 12 is wound to form a magnetic circuit (magnetic path). Then, the transformer 1 is wound around the annular core 13 by passing the generated magnetic flux through the annular core 13 (magnetic path) due to the primary current i1 flowing through the primary winding 11. An induced electromotive force is generated in 12, and the secondary current i2 flows in the secondary winding 12. Further, the number of turns Np of the primary winding 11 is different from the number of turns Ns of the secondary winding 12. As a result, the voltage on the primary side is transformed (boosted or stepped down) to the voltage on the secondary side according to the ratio of the number of turns Np and the number of turns Ns. The term "annular core" not only means a completely closed state, but also includes a case where a plurality of cores are arranged with a gap G1 (see FIG. 4) apart from each other as described later. It is described.

<Configuration of current detector>
As shown in FIG. 1, the current detection unit 2 detects (acquires) the current value I0 of the exciting current i0 based on the current value I1 of the primary current i1 and the current value I2 of the secondary current i2. It is configured. It includes a primary current detection unit 21, a secondary current detection unit 22, a multiplier 23, and a subtractor 24. The primary current detection unit 21 is arranged in the vicinity of the wiring 7 connected to the primary winding 11, and is configured to detect the current value I1 of the primary current i1. Further, the secondary current detection unit 22 is arranged in the vicinity of the wiring 8 connected to the secondary winding 12, and is configured to detect the current value I2 of the secondary current i2. For example, the primary current detection unit 21 and the secondary current detection unit 22 are configured as current transformers. In FIG. 1, the control unit 5, the discrimination circuit 6, the multiplier 23, and the subtractor 24 are shown as functional blocks, but these are configured as electric circuits (separate hardware) for each functional block. It may be configured as one electric circuit (one hardware) having all the functional blocks.

The multiplier 23 is connected to the secondary current detection unit 22 and is configured to acquire information on the current value I2. The information of the current value I2 (and the information of the current value I1 described later) indicates, for example, the voltage value (level) or the current value I2 (current value I1) of the signal indicating the current value I2 (current value I1). It is the current value of the signal. Here, in the first embodiment, the multiplier 23 is information indicating a value obtained by multiplying the current value I2 of the secondary current i2 by a coefficient k relating to the number of turns Np of the primary winding 11 and the number of turns Ns of the secondary winding 12. It is configured to output (signal). That is, the multiplier 23 is configured to output a signal (k × I2) to the subtractor 24. The coefficient k is a value obtained by dividing Np by Ns (k = Np / Ns).

The subtractor 24 is connected to the primary current detection unit 21 and the multiplier 23, and acquires the information of the current value I1 from the primary current detection unit 21 and the signal (k × I2) from the multiplier 23. It is configured to do. Then, the subtractor 24 is configured to acquire the exciting current i0 by differentiating the value (k × I2) obtained by multiplying the current value I2 by the coefficient k from the current value I1. The subtractor 24 is configured to transmit a signal indicating the current value I0 (I0 = I1-k × I2) of the exciting current i0 to the discrimination circuit 6.

<Configuration related to protection operation>
In the first embodiment, the control unit 5 and the discrimination circuit 6 are configured to perform a protective operation against the transformer 1 based on the increase in the exciting current i0. Specifically, the discrimination circuit 6 acquires a signal indicating the current value I0 of the exciting current i0 from the subtractor 24 of the current detection unit 2, and the current value I0 of the exciting current i0 is the allowable temperature Tc of the transformer 1. It is configured to determine whether or not the threshold current value It or more, which is the current value corresponding to the upper limit value Tu of. For example, the discrimination circuit 6 includes a comparison circuit (comparator), and is configured to compare the reference information (for example, the reference voltage) indicating the threshold current value It with the signal (voltage value) indicating the current value I0. Has been done. The discrimination circuit 6 is configured to transmit the protection operation signal S1 to the control unit 5 when the current value I0 becomes equal to or higher than the threshold current value It.

The control unit 5 is configured to control the drive of the switching circuit unit 3 that supplies the primary current i1 to the primary winding 11. Then, when the protection operation signal S1 is acquired from the discrimination circuit 6, the control unit 5 limits the current value I1 of the primary current i1 supplied to the primary winding 11, or limits the current value I1 of the primary current i1. It is configured to control to stop the supply. The "limit the current value I1" means that the current value I1 is reduced, for example, by making the duty ratio of the pulse width modulation smaller than the size before acquiring the protection operation signal S1.

<Structure of annular core>
As shown in FIG. 2, the annular core 13 includes a plurality of cores. In the first embodiment, the annular core 13 includes one core 30 which constitutes a part of the annular core 13 and the other core 40 which is arranged facing the one core 30 and constitutes the other part of the annular core 13. .. Specifically, when viewed from the arrow Y1 direction side, the one core 30 and the other core 40 are each formed to have a substantially U-shape. The substantially U-shaped opening side of one core 30 and the opening side of the other core 40 are arranged so as to face each other in the Z direction (for example, in the vertical direction). That is, in the first embodiment, the annular core 13 is formed as a UU-shaped core.

Specifically, the one core 30 is composed of a first portion 31 extending in the Z direction, a second portion 32 arranged apart from the first portion 31 in the arrow X2 direction, and a substantially U-shaped one core 30. It constitutes a bottom portion and includes a connecting portion 33 connecting the first portion 31 and the second portion 32. The first portion 31 has a tip surface 31a at a tip portion on the opposite side to the connection portion 33 side. Further, the second portion 32 has a tip surface 32a arranged at a height position (position in the Z direction) substantially the same as the tip surface 31a on the side opposite to the connection portion 33 side.

The other core 40 has a first portion 41 having a tip surface 41a arranged opposite to the tip surface 31a of the first portion 31 of the one core 30, and a tip surface 32a of the second portion 32 of the one core 30. It includes a second portion 42 having a tip surface 42a arranged opposite to the first portion 41 and a connecting portion 43 connecting the first portion 41 and the second portion 42.

For example, in the normal state (when the temperature T of the transformer 1 is less than the upper limit value Ru of the curing temperature range Rt described later), the tip surface 31a and the tip surface 41a of the one core 30 and the other core 40 are close to each other. They are arranged so as to (contact) and the tip surface 32a and the tip surface 42a are close to each other (contact). Here, the distance D is assumed to mean the distance between the tip surface 31a and the tip surface 41a, or the distance between the tip surface 32a and the tip surface 42a. Further, the distance D1 is described as meaning, for example, a distance of approximately 0.

Further, the one core 30 and the other core 40 are arranged so as to be relatively movable in the Z direction in a case (not shown) or the like. That is, the one core 30 and the other core 40 are arranged so that the size of the distance D can be changed.

As shown in FIG. 3, the secondary winding 12 is wound around the outer circumferences of the first portions 31 and 41 and the second portions 32 and 42, respectively, via the adhesive tape member 14 and the thermal expansion member 50 described later. It is being turned. Further, the primary winding 11 is wound around the outside (outer circumference) of the wound secondary winding 12.

<Structure related to increasing the exciting current by thermal expansion>
As shown in FIG. 2, in the first embodiment, the transformer 1 is filled between (inside) the annular core 13 and has an insulating resin having a thermal expansion coefficient α2 larger than the thermal expansion coefficient α1 of the annular core 13. In addition to including the thermal expansion member 50 having an insulating rubber, the thermal expansion member 50 is thermally expanded and the distance D between the annular cores 13 is increased, so that the current value I0 of the exciting current i0 is increased. There is.

Specifically, in the first embodiment, the annular core 13 includes a silicon steel plate or ferrite.
The coefficient of thermal expansion (linear expansion coefficient) α1 of the annular core 13 is, for example, 10 × 10 ^-6 K or more and 20 × 10 ^-6 K or less. Further, the primary winding 11 and the secondary winding 12 include a conductor made of copper or aluminum. For example, the primary winding 11 and the secondary winding 12 contain copper, and the coefficient of thermal expansion (linear expansion coefficient) α3 is 10 × 10 ^-6 K or more and 20 × 10 ^-6 K or less. The coefficient of thermal expansion (linear expansion coefficient) α2 of the thermal expansion member 50 is larger than 20 × 10 ^-6 K and less than 1000 × 10 ^-6 K. Preferably, the coefficient of thermal expansion α2 is an order of magnitude larger than that of α1.

Further, in the first embodiment, the thermal expansion member 50 is configured as a thermosetting resin filled between the primary winding 11 and the secondary winding 12 and the annular core 13. For example, the thermal expansion member 50 contains an insulating resin or an elastomer (elastic rubber) as an insulating rubber. Preferably, the thermal expansion member 50 contains a thermosetting silicone rubber. Specifically, the thermal expansion member 50 is filled inside the annular core 13. Then, in the transformer 1, the thermal expansion member 50 thermally expands and presses the one core 30 and the other core 40 from the inside to the outside of the annular core 13, so that the distance between the one core 30 and the other core 40 is reached. It is configured so that D becomes large.

Further, the thermal expansion member 50 is filled so as to fill the space (gap) between the inside of the annular core 13 and the primary winding 11 and the secondary winding 12 when viewed from the arrow Y1 direction side. Specifically, the thermal expansion member 50 is in contact (adhesion) with the inner side surface 31b of the first portion 31 of the core 30, the inner side surface 32b of the second portion 32, and the inner side surface 33a of the connecting portion 33. On the other hand, the inner side surface 41b of the first portion 41 of the core 40, the inner side surface 42b of the second portion 42, and the inner side surface 43a of the connecting portion 43 are in contact (adhesive).

Here, in the first embodiment, the transformer 1 is configured so that the exciting current i0 increases as the distance D (distance between a plurality of cores) between the one core 30 and the other core 40 increases. There is. Specifically, as the distance D increases, the magnetic resistance in the magnetic circuit of the annular core 13 increases, and the current value I0 of the exciting current i0 increases. Here, as shown in FIG. 4, assuming that the length (length before expansion) of the thermal expansion member 50 is La1 in the direction in which the one core 30 and the other core 40 face each other (Z direction), the thermal expansion member When the temperature T1 of 50 (transformer 1) rises to the temperature T2, the dimensional change ΔLa has the relationship of the following equation (1). As a result, a gap G1 is created between the tip surfaces 31a and 41a and between the tip surfaces 32a and 42a.

That is, when the distance D at the temperature T1 is D1, the distance D2 at the temperature T2 is D1 + ΔLa. As a result, in the exciting inductance L ₀ of the transformer 1, μ ₀ is the magnetic permeability of the vacuum, S is the cross-sectional area of the annular core 13 with respect to the magnetic path, Lb1 is the magnetic path length of the annular core 13, and μ _r is the annular core 13. Assuming that the relative permeability and Lb2 are the length of the gap G1 of the annular core 13 (the size is twice the distance D), there is a relationship of the following equation (2). Therefore, as the distance D (gap length Lb2) increases, the magnetization current component of the exciting current i0 of the transformer 1 increases. That is, the larger the distance D, the larger the exciting current i0.

As shown in FIG. 2, in the first embodiment, the adhesive tape member 14 is arranged so as to cover the annular core 13 on the outer periphery of the annular core 13 (from one core 30 to the other core 40). The adhesive tape member 14 is configured as, for example, a vinyl tape. For example, as shown in FIG. 4, the adhesive tape member 14 is formed in a film shape having a thickness t1 and is smaller than the thickness t2 of the first portions 31 and 41 (second portions 32 and 42) in the X direction. .. The adhesive tape member 14 is configured to be elastically deformable, and is configured to urge (pull) one core 30 toward the other core 40 by an urging force fa, and the other core 40. On the other hand, the core 30 side is configured to be urged (pulled) by the urging force fa. That is, the transformer 1 is configured to be urged by the adhesive tape member 14 in the direction in which the one core 30 and the other core 40 approach each other (the direction in which the distance D becomes smaller) by the urging force fa. The adhesive tape member 14 is an example of the "urging member" in the claims.

Here, in the first embodiment, when the temperature T of the transformer is equal to or less than the upper limit value Ru of the curing temperature range Ra of the thermal expansion member 50, the core 30 is urged by the adhesive tape member 14. When the temperature T of the transformer 1 exceeds the upper limit value Ru of the curing temperature range Ra, the thermal expansion member 50 is configured so that the distance D between the core 40 and the other core 40 does not change. By pressing the core 40 against the urging force fa by the adhesive tape member 14, the distance D between the one core 30 and the other core 40 is increased.

Specifically, the upper limit value Ru of the curing temperature range Ra of the thermal expansion member 50 is lower than the upper limit value Tu of the allowable temperature Tc of the transformer 1. Then, when the temperature T of the thermal expansion member 50 exceeds the upper limit value Ru of the curing temperature range Ra, the thermal expansion member 50 generates stress (thermal stress) toward the outside of the thermal expansion member 50. In this case, the thermal expansion member 50 arranged inside the annular core 13 presses the annular core 13 outward. Specifically, the thermal expansion member 50 presses the inner side surfaces 31b, 32b, 33a, 41b, 42b, and 43a toward the outside. Here, the pressing force on the inner side surfaces 31b and 32b presses the core 30 integrally formed in the direction of the arrow X1 and the direction of the arrow X2, and cancels each other out. Further, the pressing force on the inner side surfaces 41b and 42b presses the other core 40 integrally formed in the direction of arrow X1 and the direction of arrow X2, and cancels each other out.

As a result, as shown in FIG. 4, the inner side surface 33a of the one core 30 is pressed by the thermal expansion member 50 in the direction of the arrow Z1 with the pressing force fb, and the inner surface 43a of the other core 40 is arrowed by the thermal expansion member 50. It is pressed by the pressing force fb in the Z2 direction. Therefore, in the transformer 1, when the temperature T of the thermal expansion member 50 exceeds the upper limit value Ru of the curing temperature range Ra, the thermal expansion member 50 causes the one core 30 and the other core 40 to move away from each other (distance D). Is configured to be pressed by the pressing force fb (in the direction in which the temperature increases).

Then, when the pressing force fb by the thermal expansion member 50 exceeds the urging force fa by the adhesive tape member 14, the distance D between the one core 30 and the other core 40 becomes large, and the distance D between the tip surfaces 31a and 41a becomes large. A gap G1 is formed between the tip surfaces 32a and 42a.

(Operation of power supply)
Next, the operation of the power supply device 100 according to the first embodiment will be described with reference to FIGS. 2 and 4.

<When the transformer temperature T is less than or equal to the upper limit Ru of the curing temperature range Ra>
As shown in FIG. 2, the pressing force fb (stress) at which the thermal expansion member 50 presses the one core 30 and the other core 40 does not exceed the urging force fa by the adhesive tape member 14, and the one core 30 and the other core 40 The distance D is in the state of D1. In this case, the exciting current i0 detected by the current detection unit 2 is less than the threshold current value It, and the protection operation signal S1 is not transmitted from the discrimination circuit 6 to the control unit 5. In this case, the switching circuit unit 3 is normally operated (the primary current i1 is not limited).

<When the temperature T of the transformer is larger than the upper limit Ru of the curing temperature range Ra and equal to or less than the upper limit Tu of the allowable temperature Tc>
As shown in FIG. 4, the pressing force fb (stress) at which the thermal expansion member 50 presses the one core 30 and the other core 40 exceeds the urging force fa by the adhesive tape member 14, and the distance between the one core 30 and the other core 40. D is larger than D1. In this case, the exciting current i0 detected by the current detection unit 2 increases, while the exciting current i0 becomes less than the threshold current value It, and the protection operation signal S1 is not transmitted from the discrimination circuit 6 to the control unit 5. In this case, the switching circuit unit 3 is normally operated (the primary current i1 is not limited).

<When the temperature T of the transformer exceeds the upper limit value Tu of the allowable temperature Tc>
The pressing force fb on which the thermal expansion member 50 presses the one core 30 and the other core 40 exceeds the urging force fa by the adhesive tape member 14, and the distance D between the one core 30 and the other core 40 is larger than D1 (for example, for example). To D2). In this case, the exciting current i0 detected by the current detection unit 2 becomes equal to or higher than the threshold current value It, and the protection operation signal S1 is transmitted from the discrimination circuit 6 to the control unit 5. Then, the control unit 5 limits the magnitude of the current value I1 of the primary current i1 output from the switching circuit unit 3, or the output of the primary current i1 is stopped.

[Effect of the first embodiment]
In the first embodiment, the following effects can be obtained.

In the first embodiment, as described above, the transformer 1 is filled between a plurality of cores of the annular core 13 and has an insulating resin having a coefficient of thermal expansion α2 larger than the coefficient of thermal expansion α1 of the annular core 13. A thermal expansion member 50 having an insulating rubber is provided. Further, the transformer 1 is configured so that the exciting current i0 increases as the thermal expansion member 50 thermally expands and the distance D between the one core 30 and the other core 40 increases. Then, the control unit 5 and the discrimination circuit 6 are configured to perform a protective operation against the transformer 1 based on the increase in the exciting current i0. As a result, when the temperature T of the transformer 1 rises, the thermal expansion member 50 that functions as a member for ensuring the insulation between the annular core 13 and the primary winding 11 or the secondary winding 12 is thermally expanded. By doing so, the protection operation for the transformer 1 can be performed based on the fact that the exciting current i0 becomes large. That is, without providing the transformer 1 with a dedicated temperature sensor, the thermal expansion member 50 can have both a function as a member for ensuring insulation and a function as a temperature sensor. Therefore, unlike the case where the dedicated temperature sensor is arranged on the upper surface of the transformer 1, it is possible to prevent the transformer 1 from becoming large in size. Further, unlike the case where the dedicated temperature sensor is arranged between the annular core 13 and the primary winding 11 or the secondary winding 12, the structure of the transformer 1 can be suppressed from becoming complicated. As a result, it is possible to prevent the transformer 1 from becoming large and complicated even when the protection operation is performed when the temperature T of the transformer 1 rises.

Further, in the first embodiment, as described above, the thermal expansion member 50 includes the thermosetting resin filled between the primary winding 11 and the secondary winding 12 and the annular core 13. As a result, in the transformer 1, the thermosetting resin is filled between the primary winding 11 and the secondary winding 12 and the annular core 13 and thermoset to heat the annular core 13. It can be easily arranged as a member for ensuring insulation in the gap between the primary winding 11 and the secondary winding 12, and the exciting current i0 is applied based on the rise in the temperature T of the transformer 1. It can be easily arranged between the annular core 13 and the annular core 13 so as to be large.

Further, in the first embodiment, as described above, the annular core 13 is arranged with the one core 30 constituting a part of the annular core 13 and the other core 30 facing each other to form the other part of the annular core 13. On the other hand, a core 40 is provided. The thermal expansion member 50 is filled inside the annular core 13, and the transformer 1 is thermally expanded by the thermal expansion member 50 and presses the one core 30 and the other core 40 from the inside to the outside of the annular core 13. As a result, the distance D between the one core 30 and the other core 40 is configured to be large. As a result, the thermal expansion member 50 thermally expands, so that the thermal expansion member 50 directly presses the one core 30 and the other core 40 from the inside, and the distance D between the one core 30 and the other core 40 is increased. can do. As a result, the magnetic resistance of the annular core 13 can be increased by the thermal expansion of the thermal expansion member 50, so that the exciting current i0 flowing through the transformer 1 can be easily increased.

Further, in the first embodiment, as described above, the adhesive tape urges the transformer 1 to urge at least one of the one core 30 and the other core 40 in the direction in which the one core 30 and the other core 40 approach each other. A member 14 is further provided. The transformer 1 is thermally expanded by the thermal expansion member 50 and presses the one core 30 and the other core 40 from the inside to the outside of the annular core 13 against the urging force fa by the adhesive tape member 14. The distance D between the one core 30 and the other core 40 is increased. As a result, when the pressing force fb by the thermal expansion member 50 in the direction in which the distance D between the one core 30 and the other core 40 increases is relatively small and it is not necessary to perform a protective operation, the urging force fa by the adhesive tape member 14 Therefore, the state (D1) in which the distance D between the one core 30 and the other core 40 is small can be maintained. As a result, the protection operation for the transformer 1 can be appropriately performed without unnecessarily increasing the exciting current i0.

Further, in the first embodiment, as described above, the thermal expansion member 50 is configured as a resin having a curing temperature range Ra having an upper limit value Ru lower than the upper limit value Tu of the allowable temperature Tc of the transformer 1, and transforming. The vessel 1 is configured so that the distance D between the one core 30 and the other core 40 does not change due to the urging by the adhesive tape member 14 when the temperature T of the transformer 1 is equal to or less than the upper limit value Ru of the curing temperature range Ra. At the same time, when the temperature T of the transformer 1 exceeds the upper limit value Ru of the curing temperature range Ra, the thermal expansion member 50 resists the urging force fa by the adhesive tape member 14 with the one core 30 and the other core 40. The distance D between the one core 30 and the other core 40 is increased by pressing the core 30. As a result, when the temperature T of the transformer 1 becomes the upper limit value Tu of the allowable temperature Tc of the transformer 1, the temperature exceeds the upper limit value Ru of the curing temperature range Ra of the thermal expansion member 50. Therefore, when the temperature T of the transformer 1 reaches the upper limit value Tu of the allowable temperature Tc of the transformer 1, the thermal expansion member 50 can press the one core 30 and the other core 40. .. As a result, when the temperature T of the transformer 1 exceeds the upper limit value Tu of the allowable temperature Tc of the transformer 1, the distance D between the one core 30 and the other core 40 can be increased more reliably.

Further, in the first embodiment, as described above, the control unit 5 and the discrimination circuit 6 are configured to control the drive of the switching circuit unit 3 that supplies the primary current i1 to the primary winding 11. As the thermal expansion member 50 thermally expands and the distance D between the one core 30 and the other core 40 increases, the current value I0 of the exciting current i0 corresponds to the upper limit value Tu of the allowable temperature Tc of the transformer 1. When the threshold current value It or more, which is a value, is reached, the current value of the primary current i1 supplied to the primary winding 11 is limited or the primary current is limited as a protection operation for the transformer 1. It is configured to control the operation of the switching circuit unit 3 so as to stop the supply of i1. As a result, the current value I0 of the exciting current i0 can be acquired and the existing switching can be obtained by the configuration of acquiring the current value I1 of the existing primary current i1 and the current value I2 of the secondary current i2 of the power supply device 100. The operation of the circuit unit 3 can be controlled to perform a protective operation against the transformer 1. As a result, it is possible to prevent the configuration of the power supply device 100 from becoming complicated because the existing configuration can be used.

Further, in the first embodiment, as described above, the current detection unit 2 has the current value I1 of the primary current i1 to the current value I2 of the secondary current i2, the number of turns Np of the primary winding 11 and the secondary winding. By multiplying the value (k × I2) obtained by multiplying the coefficient k with respect to the number of turns Ns of the wire 12 by the difference (I1-k × I2), the current value I0 of the exciting current i0 is acquired. As a result, even when the number of turns Np of the primary winding 11 and the number of turns Ns of the secondary winding 12 are different, the current value I0 of the exciting current i0 can be easily obtained by the current detection unit 2.

[Second Embodiment]
Next, the configuration of the power supply device 200 of the second embodiment will be described with reference to FIGS. 1 and 5 to 7. The second embodiment is different from the configuration according to the first embodiment in which the transformer 1 provided with the U-U-shaped annular core 13 is provided, and includes the transformer 201 provided with the EI-shaped annular core 213. .. The same configuration as that of the first embodiment is shown with the same reference numerals in the drawings, and the description thereof will be omitted.

As shown in FIG. 1, in the second embodiment, the power supply unit 200 includes a transformer 201. As shown in FIG. 5, the transformer 201 includes a primary winding 211, a secondary winding 212, an annular core 213, an adhesive tape member 214, and a thermal expansion member 250. The annular core 213 includes one core 230 formed in a substantially E shape when viewed from the side in the direction of arrow Y1, and the other core 240 arranged facing the one core 230 and formed in a substantially I shape. .. The thermal expansion member 250 is filled between the primary winding 211 and the secondary winding 212 and the annular core 213 inside the annular core 213. Further, the adhesive tape member 214 is arranged so as to cover the periphery of the annular core 213.

On the other hand, the core 230 is arranged in the direction of the arrow X1 of the central leg portion 231 protruding toward the other core 240 side, and the first leg portion 232 protruding toward the other core 240 side, and the arrow of the central leg portion 231. It includes a second leg portion 233 arranged in the X2 direction and projecting toward the core 240, and a connecting portion 234 connecting the central leg portion 231, the first leg portion 232, and the second leg portion 233. Then, as shown in FIG. 6, the primary winding 211 and the secondary winding 212 are respectively wound around the central leg portion 231.

As shown in FIG. 7, the thermal expansion member 250 thermally expands when the temperature T of the transformer 201 rises, so that the connection portion 234 of the core 230 is connected from the inside to the outside of the annular core 213 (arrow Z2). On the directional side), the inner side surface 241 of the core 240 is pressed by the pressing force fb1 against the urging force fa1 by the adhesive tape member 214, and the inner side surface 241 of the other core 240 is moved from the inside to the outside (arrow Z1 direction side) of the annular core 213. It is configured to be pressed by the pressing force fb1 against the urging force fa1 by the adhesive tape member 214.

As a result, when the temperature T of the transformer 201 (thermal expansion member 250) exceeds the upper limit value Tu of the allowable temperature Tc of the transformer 201, the tip surface 231a of the central leg portion 231 and the tip surface of the first leg portion 232 The distance D11 between the tip surface 233a of the second leg portion 233 and the side surface portion 242 of the other core 240 increases to D12 due to the thermal expansion of the thermal expansion member 250, and the current value of the exciting current i0 in the transformer 201. I0 becomes large. In this case, the control unit 5 and the discrimination circuit 6 are configured to perform a protective operation against the transformer 201. Further, the other configurations of the second embodiment are the same as the configurations of the first embodiment.

[Effect of the second embodiment]
In the second embodiment, as described above, one core 230 is formed in a substantially E shape, and the other core 240 is formed in a substantially I shape. Thereby, the present invention can be easily applied to the transformer 201 including the annular core 213 having the EI shape. The other effects of the second embodiment are the same as the effects of the first embodiment.

[Modification example]
It should be noted that the embodiments disclosed this time are exemplary in all respects and are not considered to be restrictive. The scope of the present invention is shown by the scope of claims rather than the description of the above-described embodiment, and further includes all modifications (modifications) within the meaning and scope equivalent to the scope of claims.

For example, in the above embodiment, an example is shown in which the transformer is configured as a transformer having an annular core having a UU shape or an EI shape, but the present invention is not limited thereto. That is, the annular core may be formed so as to have a shape other than the UU shape or the EI shape. For example, the annular core may be formed in an annular shape, an EE shape, a UI shape, or the like.

Further, in the above embodiment, an example in which the annular core is composed of two cores (one core and the other core) is shown, but the present invention is not limited to this. That is, the annular core may be composed of a plurality of cores of three or more.

Further, in the above embodiment, an example in which a control unit and a discrimination circuit are configured as a protection circuit unit is shown, but the present invention is not limited to this. For example, even if a circuit breaker is provided between the DC power supply and the switching circuit section, the connection between the DC power supply and the switching circuit section may be cut off by the circuit breaker based on the protection operation signal from the discrimination circuit. good.

Further, in the above embodiment, an example in which a thermosetting silicone rubber is used as the thermal expansion member is shown, but the present invention is not limited to this. For example, as the thermal expansion member, a material other than thermosetting silicone rubber may be used as long as it has electrical insulation and thermal expansion characteristics. For example, the thermal expansion member may be made of a resin other than a thermosetting resin or rubber.

Further, in the above embodiment, an example in which the thermal expansion member is filled between the primary winding and the secondary winding and the annular core and cured is shown, but the present invention is not limited to this. For example, the cured thermal expansion member may be placed inside the annular core.

Further, in the above embodiment, an example is shown in which the distance between one core and the other core changes from D1 (D11) to D2 (D12), which is substantially 0, but the present invention is not limited to this. In the annular core in which a gap is formed in advance between one core and the other core, the transformer is configured so that the distance becomes larger due to the thermal expansion of the thermal expansion member from the state where the distance is larger than about 0. May be good.

Further, in the above embodiment, an example in which the adhesive tape member is used as the urging member is shown, but the present invention is not limited to this. For example, a cushion material may be used as the urging member, or a spring member may be used.

Further, in the above embodiment, the current value of the exciting current is different from the value obtained by multiplying the current value of the primary current by the current value of the secondary current and the coefficient related to the number of turns of the primary winding and the number of turns of the secondary winding. Although the example obtained by the above is shown, the present invention is not limited to this. For example, the current value of the exciting current may be obtained by using a table or the like in which the current value of the primary current and the current value of the secondary current and the current value of the exciting current are associated with each other.

Further, in the above embodiment, an example is shown in which the distance between one core and the other core does not change when the temperature of the transformer is equal to or less than the upper limit of the curing temperature range, but the present invention is limited to this. I can't. For example, if there is little problem in increasing the exciting current, the distance between one core and the other core may be changed when the temperature of the transformer is equal to or less than the upper limit of the curing temperature range.

Further, in the above embodiment, as a protection operation, an example of limiting the current value of the primary current or stopping the supply of the primary current has been shown, but the present invention is not limited to this. For example, a circuit breaker or the like may be provided on the secondary side of the transformer to configure the power supply device so as to stop the output of the secondary current.

1,201 Transformer 2 Current detector (excitation current detector)
3 Switching circuit section 5 Control section (protection circuit section)
6 Discrimination circuit (protection circuit section)
11,211 Primary winding 12,212 Secondary winding 13,213 Circular core 14,214 Adhesive tape member (urgency member)
30, 230 One core 40, 240 The other core 50, 250 Thermal expansion member 100, 200 Power supply

Claims (9)

A transformer including a primary winding through which a primary current flows, a secondary winding through which a secondary current flows, and a plurality of cores in which the primary winding and the secondary winding are wound to form a magnetic circuit. With a vessel
An exciting current detection unit that detects an exciting current based on the primary current and the secondary current,
A protection circuit unit, which is a circuit that performs a protection operation for the transformer based on the increase in the exciting current, is provided.
The transformer is filled between the plurality of cores, includes a thermal expansion member having an insulating resin or an insulating rubber having a thermal expansion coefficient larger than the thermal expansion coefficient of the core, and the thermal expansion member includes the thermal expansion member. A power supply device configured to increase the exciting current by thermally expanding and increasing the distance between the plurality of cores. The power supply device according to claim 1, wherein the thermal expansion member includes the primary winding and a thermosetting resin filled between the secondary winding and the plurality of cores. The plurality of cores are configured as an annular core, and one core constituting a part of the annular core and the one core arranged opposite to the one core form the other part of the annular core. On the other hand, including the core
The thermosetting resin is filled inside the annular core and is filled.
In the transformer, the thermosetting resin thermally expands and presses the one core and the other core from the inside to the outside of the annular core, so that the distance between the one core and the other core is reached. The power supply device according to claim 2, wherein the power supply device is configured to be large. Further provided with an urging member for urging at least one of the one core and the other core in a direction in which the one core and the other core approach each other.
In the transformer, the thermosetting resin thermally expands and presses the one core and the other core from the inside to the outside of the annular core against the urging force of the urging member. The power supply device according to claim 3, wherein the distance between the one core and the other core is increased. The thermosetting resin is a resin having a curing temperature range having an upper limit value lower than the upper limit value of the allowable temperature of the transformer.
The transformer is configured so that the distance between the one core and the other core does not change due to the urging by the urging member when the temperature of the transformer is equal to or lower than the upper limit of the curing temperature range. At the same time, when the temperature of the transformer exceeds the upper limit of the curing temperature range, the thermosetting resin presses the one core and the other core against the urging force of the urging member. The power supply device according to claim 4, wherein the distance between the one core and the other core is increased. The protection circuit unit is configured to control the drive of the switching circuit unit that supplies the primary current to the primary winding, and the thermal expansion member thermally expands to support the plurality of cores. When the current value of the exciting current becomes equal to or greater than the threshold current value, which is the current value corresponding to the upper limit of the allowable temperature of the transformer due to the increase in the distance, as a protective operation for the transformer. , The operation of the switching circuit unit is controlled so as to limit the current value of the primary current supplied to the primary winding or stop the supply of the primary current. The power supply device according to any one of claims 1 to 5. The exciting current detection unit differs from the current value of the primary current by the value obtained by multiplying the current value of the secondary current by the number of turns of the primary winding and the coefficient related to the number of turns of the secondary winding. The power supply device according to claim 6, wherein the power supply device is configured to acquire a current value of the exciting current. The thermal expansion member contains a thermosetting silicone rubber and contains.
The primary winding and the secondary winding include one of copper or aluminum.
The power supply device according to any one of claims 1 to 7, wherein the plurality of cores each include one of a silicon steel plate and a ferrite. With the primary winding through which the primary current flows,
The secondary winding through which the secondary current flows and the secondary winding
A plurality of cores in which the primary winding and the secondary winding are wound to form a magnetic circuit,
It is provided with a thermal expansion member arranged between the plurality of cores and having an insulating resin or an insulating rubber having a coefficient of thermal expansion larger than the coefficient of thermal expansion of the core.
A transformer configured to increase the exciting current by thermally expanding the thermal expansion member and increasing the distance between the plurality of cores.

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