JP2021007366A - Storage apparatus - Google Patents

Abstract

To provide a storage apparatus having an electric field forming device to form an electric field inside a storehouse, wherein an electric field of sufficient intensity is formed inside the storehouse.SOLUTION: An electric field forming device is provided with a plurality of electrodes (31, 32) disposed inside a storehouse (5), an AC power supply (33) connected to a power supply, and a control unit that controls voltage application to the electrodes (31, 32), and the plurality of electrodes (31, 32) are applied with AC voltages having the same frequency and different phases.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to a storage device.

Conventionally, as a storage device for storing an item such as food, a cold storage device for storing an item such as fresh food in a storage and storing it in a supercooled state is known. For example, there is known a device in which an electric field forming device is provided in a storage for storing food and a voltage is applied to a shelf in the storage (see, for example, Patent Document 1). In this device, one of the electrodes connected to the AC power supply is connected to the shelf, and the other is grounded. In this food storage, the freshness of food is maintained by the generated electric field.

Japanese Patent No. 6072957

In the above device, only one of the electrodes is connected to the shelf and the other is not connected to the shelf. Therefore, the inside of the storage may have the same potential, and the strength of the electric field may be insufficient. As a result, it becomes difficult to keep foods and other items in a supercooled state. Even when an electric field forming device is provided in a storage for storing an item at room temperature, if the strength of the electric field is insufficient, it becomes difficult to prevent the item from being damaged.

An object of the present disclosure is to form an electric field of sufficient strength in a refrigerator in a storage device equipped with an electric field forming device.

The first aspect of the present disclosure is
It is premised on a storage device including a storage (5) and an electric field forming device (30) that forms an electric field in the storage (5).

In this storage device, the electric field forming device (30) has a plurality of electrodes (31,32) (31U, 31V, 31W) arranged in the storage of the storage (5), and the electrodes (31,32). It is equipped with an AC power supply (33) connected to (31U, 31V, 31W) and a control unit (16) that controls voltage application to the electrodes (31,32) (31U, 31V, 31W).
The control unit (16) is characterized in that AC voltages having the same frequency but different phases are applied to the plurality of electrodes (31, 32) (31U, 31V, 31W).

In the first aspect, the frequencies of the AC voltages applied to the plurality of electrodes (31,32) (31U, 31V, 31W) are the same but the phases are different. Therefore, it is suppressed that the inside of the storage (5) has the same potential, and an electric field of sufficient strength is formed in the storage (5).

A second aspect of the present disclosure is, in the first aspect,
The plurality of electrodes (31, 32) (31U, 31V, 31W) are characterized in that they are arranged to face each other inside the storage (5).

In the second aspect, AC voltages having the same frequency but different phases are applied between the electrodes (31,32) (31U, 31V, 31W) facing each other inside the storage (5), and the storage (5) is sufficiently occupied. An electric field of high strength is formed.

A third aspect of the present disclosure is the first or second aspect.
The control unit (16) is characterized in that AC voltages having phases different from each other by 180 ° are applied to the plurality of electrodes (31, 32).

In the third aspect, the frequencies of the AC voltages applied to the plurality of electrodes (31, 32) are the same but the phases are different by 180 °. Then, a point at which the potential difference becomes large occurs periodically when the amplitude of the voltage waveform fluctuates, and an electric field having sufficient strength is formed in the storage (5) at that point.

A fourth aspect of the present disclosure is the third aspect.
The AC power supply (33) is a single-phase AC power supply.
The electric field forming apparatus (30) is characterized by including a circuit (40) that generates AC voltages having different phases from the single-phase AC power supply.

In the fourth aspect, AC voltages having the same frequency but different phases are generated from the single-phase AC power supply and applied between the electrodes (31, 32) to form an electric field of sufficient strength in the storage (5). ..

A fifth aspect of the present disclosure is the third aspect.
The AC power supply (33) is a three-phase AC power supply.
The electric field forming apparatus (30) is characterized by including a circuit (40) that generates AC voltages having different phases from the three-phase AC power supply.

In the fifth aspect, AC voltages having the same frequency but different phases are generated from the three-phase AC power supply and applied between the electrodes (31, 32) to form an electric field of sufficient strength in the storage (5). ..

A sixth aspect of the present disclosure is the first or second aspect.
The control unit (16) is characterized in that AC voltages having phases different from each other by 120 ° or 240 ° are applied to the plurality of electrodes (31U, 31V, 31W).

In the sixth aspect, the frequencies of the AC voltages applied to the plurality of electrodes (31U, 31V, 31W) are the same, but the phases are 120 ° or 240 ° different. Then, a point at which the potential difference becomes large occurs periodically when the amplitude of the voltage waveform fluctuates, and an electric field having sufficient strength is formed in the storage (5) at that point.

The seventh aspect of the present disclosure is, in any one of the first to sixth aspects,
The electric field forming apparatus (30) includes a plurality of boosting circuits (35, 36, 37) for boosting voltages having different phases.
The secondary side of each of the booster circuits (35, 36, 37) is characterized by having a voltage application terminal (35p, 36p, 37p) and a ground terminal (35g, 36g, 37g).

In the seventh aspect, voltages of the same frequency but different phases are boosted by the booster circuit (35, 36, 37) and applied to the electrodes (31, 32) (31U, 31V, 31W) and stored (5). An electric field of sufficient strength is formed inside.

The eighth aspect of the present disclosure is, in any one of the first to seventh aspects,
It is characterized by being provided with a refrigerator (10) for cooling the inside of the storage (5).

In the eighth aspect, in a storage device including a refrigerator (10) for cooling the inside of the storage (5), an electric field having sufficient strength is formed in the storage (5).

FIG. 1 is a cross-sectional view of the reefer container according to the first embodiment. FIG. 2 is a perspective view showing a container refrigerating apparatus. FIG. 3A is a cross-sectional view (a cross-sectional view taken along the line AA of FIG. 3B) obtained by cutting the container in a plane orthogonal to the longitudinal direction. FIG. 3B is a sectional view taken along line BB of FIG. 3A. FIG. 3C is a sectional view taken along line CC of FIG. 3A. FIG. 4 is a block diagram of a power supply circuit of the electric field forming apparatus. FIG. 5 is a block diagram of a power supply circuit of the electric field forming apparatus according to the second embodiment. FIG. 6 is a cross-sectional view of the reefer container according to the second embodiment. FIG. 7 is a block diagram of the power supply circuit of the electric field forming apparatus according to the modified example.

<< Embodiment 1 >>
The first embodiment will be described.

This embodiment is an example in which the storage device of the present disclosure is applied to a reefer container (1) provided with an electric field forming device (30). The reefer container (1) includes a container (5), which is a storage for storing fresh food and other items, a container (10), which is a refrigerator that regulates the temperature of the space inside the container (5). It has the above-mentioned electric field forming device (30) that forms an electric field in the container (5). In the present embodiment, the electric field forming device (30) is provided to store the fresh food in a supercooled state. The reason why fresh food is supercooled is that the fresher it is stored at a lower temperature, the more fresh it can be maintained and the growth of bacteria can be suppressed.

FIG. 1 is a schematic vertical cross-sectional view of the container refrigerating apparatus (10) and the container (5), and FIG. 2 is a schematic perspective view of the container refrigerating apparatus (10) of FIG. 1 as viewed from the outside. The container refrigerating device (10) cools the inside of the container (5) used for land transportation, marine transportation, and the like. The container refrigerating device (10) has a compressor (20), a radiator (21), an expansion valve (not shown), and an evaporator (23) to perform a refrigerating cycle operation (shown). It is equipped with. The container refrigeration system (10) is attached to the end of the container (5).

The container refrigerating device (10) includes a casing (11) and a partition plate (14) provided on the back surface (inside the refrigerator) of the casing (11). At the lower part of the casing (11), a bulging portion (12) bulging inside the refrigerator is formed. The internal space (space outside the refrigerator) of the bulge (12) is configured as the storage space (S1) outside the refrigerator, and is located above the bulge (12) at the upper part of the back surface of the casing (11). An internal storage space (S2) is formed.

A compressor (20), a radiator (21), an outside fan (25), an electrical component box (15), and a controller (16) are housed in the outside storage space (S1). The outside fan (25) forms an air flow through the radiator (21). The radiator (21) is located below the outside fan (25). The compressor (20) sends the refrigerant to the radiator (21). The controller (16) is a control unit of the present disclosure that controls the operation of the container refrigeration system. The above equipment layout in the storage space outside the refrigerator (S1) is an example, and can be changed as needed.

An evaporator (23) and an internal fan (26) are installed in the internal storage space (S2). The internal fan (26) supplies the internal air to the evaporator (23), and in the evaporator (23), the refrigerant flowing through the heat transfer tube takes heat from the internal air and cools the internal air. Between the bulging portion (12) and the partition plate (14), there is an internal air flow path (S3) through which the internal air flows. The upper end of the internal air flow path (S3) communicates with the internal storage space (S2), while the lower end communicates with the internal storage space (S2).

3A is a cross-sectional view of the container (5) cut along a plane orthogonal to the longitudinal direction (cross-sectional view taken along the line AA of FIG. 3B), FIG. 3B is a cross-sectional view taken along the line BB of FIG. 3A, and FIG. 3C is FIG. 3A. It is a cross-sectional view taken along the line CC of.

The electric field forming device (30) is provided for supercooling fresh food, and has a plurality of electrodes (31, 32) for forming an electric field in the internal space of the container (5). As shown in FIGS. 3A, 3B, and 3C, a plurality of electrodes (31, 32) are provided on the left and right wall surfaces of the container (5) in the same number (6 each in the present embodiment), and the wall surface on the right side of FIG. 3A. The first electrode (31) of the above and the second electrode (32) on the left wall surface are arranged so as to face each other. The first electrode (31) and the second electrode (32) are substantially parallel. A power supply circuit (40) having an AC power supply (33) is connected to each electrode (31, 32), and a predetermined voltage is applied. Then, an electric field is formed between the electrodes (31, 32) facing each other on the left and right wall surfaces of the container (5). This makes it easier to store fresh food in a supercooled state.

The controller (16) includes a microcomputer mounted on a control board and a memory device (specifically, a semiconductor memory) for storing software for operating the microcomputer. The controller (16) controls each device of the reefer container (1) based on the operation command and the detection signal of the sensor.

As described above, the electric field forming apparatus (30) includes a plurality of electrodes (31, 32) arranged in the container (5) and an AC power supply (33, 32) connected to these electrodes (31, 32). ) And. A power supply circuit (40) that controls voltage application to the electrodes is provided in the controller (16). The controller (16) constitutes the control unit of the present disclosure. The controller (16) applies AC voltages having the same frequency but different phases to the plurality of electrodes (31, 32) via the power supply circuit (40).

FIG. 4 is a block diagram of the power supply circuit (40). The power supply circuit (40) consists of an AC power supply (33), a transformer (34) connected to the AC power supply (33) by a three-phase three-wire system, and two boosters (34) connected in parallel to the transformer (34). It has a booster circuit) (35, 36). The booster (35, 36) includes a first booster (35) and a second booster (36). The first booster (35) is connected to the first electrode (31) and the second booster (36) is connected to the second electrode (32).

The AC power supply (33) is a three-phase 400V AC power supply. The transformer (34) has a coil on the primary side and a coil on the secondary side, and generates a single-phase 400V positive potential and a negative potential on the secondary side. The first booster (35) and the second booster (36) have a coil on the primary side and a coil on the secondary side, respectively, and generate a positive potential and a negative potential of 4 kV. The voltages applied to the first electrode (31) and the second electrode (32) by this power supply circuit (40) are 180 ° out of phase with each other.

The first booster (35) and the second booster (36) each have a voltage application terminal (35p, 36p) and a ground terminal (35g, 36g) on the secondary side. The positive potential side of the AC voltage generated by the power supply circuit (40) and having a phase difference of 180 ° is applied from the voltage application terminal (35p) of the first booster (35) to the first electrode (31), and the negative potential side is the second. It is applied to the second electrode from the voltage application terminal (36p) of the booster (36).

-Driving operation-
<Operation of refrigeration equipment>
The operation of the container refrigerating device (10) is started by activating the compressor (20), the external fan (25), and the internal fan (26). In the refrigerant circuit of the container refrigerating device (10), the discharged refrigerant of the compressor (20) is sent to the radiator (21). In this radiator (21), the refrigerant circulating inside exchanges heat with the outside air sent by the outside fan (25). As a result, the refrigerant dissipates heat to the outside air.

The refrigerant radiated by the radiator (21) is depressurized by the expansion valve and then sent to the evaporator (23). In this evaporator (23), the refrigerant circulating inside exchanges heat with the air inside the refrigerator sent by the fan (26) inside the refrigerator. As a result, the refrigerant absorbs heat from the internal air and evaporates, and the internal air is cooled. As shown in FIG. 1, the air inside the refrigerator flows into the storage space (S2) inside the refrigerator from above the partition plate (14) and passes through the evaporator (23). The air inside the refrigerator is cooled by the evaporator (23) and then returns to the inside of the refrigerator from the lower side of the partition plate (14). The refrigerant vaporized in the evaporator (23) is sucked into the compressor (20) and compressed again.

<Action of electric field forming device>
In the electric field forming apparatus (30), the operation of the power supply circuit (40) is controlled by the controller (16), and the frequencies of the power supply circuit (40) to the first electrode (31) and the second electrode (32) are the same. AC voltages that are 180 ° out of phase are applied. The voltage application terminal (35p) of the first booster (35) is connected to the first electrode (31), and the voltage application terminal (36p) of the second booster (36) is connected to the second electrode (32). Will be done. In this embodiment, the applied voltage is a maximum of 4 kV, and the phases differ from each other by 180 °. Therefore, a potential difference of up to 8 kV is generated between the first electrode (31) and the second electrode (32).

Due to this potential difference, an electric field is formed in the container (5). The formation of an electric field makes it easier to maintain the freshness of fresh food stored in the container (5). The freshness of the fresh food is maintained because the electric field allows the fresh food to be stored in a supercooled state.

-Effect of Embodiment 1-
In the present embodiment, in a storage device including a container (5) and an electric field forming device (30) that forms an electric field in the container (5), the electric field forming device (30) is inside the container (5). A plurality of electrodes (31,32) arranged in, an AC power supply (33) connected to the electrodes (31,32), and a control unit (16) for controlling voltage application to the electrodes (31,32). And have. The control unit (16) is configured to apply AC voltages having the same frequency but different phases to the plurality of electrodes (31, 32).

Conventionally, in a storage device such as a reefer container that cools the inside of a storage to store items such as fresh food, a plurality of electrodes that form an electric field in the storage so as to keep the fresh food in a supercooled state and maintain freshness. There is one with. In the conventional storage device, only one of the output terminals of the AC power supply is connected to the electrode (for example, a shelf provided in the refrigerator), and the other is not connected to the electrode (for example, Japanese Patent Application Laid-Open No. 2012-39978). .. Further, there is also a configuration in which only one of the output terminals of the AC power supply is connected to the electrode and the other is grounded (for example, Japanese Patent Application Laid-Open No. 2002-364966).

In these device configurations, there is no potential difference between the electrodes, or the potential difference is small, so that a sufficient electric field is not formed in the refrigerator. As a result, the freshness-preserving effect of fresh food is reduced. Further, in order to form a sufficient electric field, it is necessary to increase the output voltage.

There are other conventional devices in which the output terminals of the AC power supply are connected to the electrodes, respectively (for example, Japanese Patent No. 6144068). However, in this case, since the secondary side of the power supply device is not grounded, the voltage to ground becomes unstable. As a result, the intended electric field may not be generated.

As described above, in the conventional apparatus, for example, even if the potential difference between the electrodes is 4 kV, one electrode is not always plus 2 kV and the other electrode is minus 2 kV, and one electrode is 0 kV and the other electrode is the other. There is a risk of imbalance that causes the electrodes to reach -4 kV.

On the other hand, in the present embodiment, the frequencies of the AC voltages applied to the first electrode (31) and the second electrode (32) are the same, but the phases are different. Therefore, a sufficient potential difference is formed between the electrodes (31, 32) in the container (5), and the potential imbalance is also suppressed. Therefore, an electric field of sufficient strength is formed in the container (5). As a result, the effect of maintaining the freshness of products such as fresh food can be enhanced.

In the present embodiment, a plurality of first electrodes (31) and second electrodes (32), respectively, are arranged to face each other inside the container (5). Further, the first electrode (31) is provided on one wall surface of the container (5), and the second electrode (32) is provided on the other wall surface of the container (5). According to this configuration, when an AC voltage having the same frequency but a different phase of 180 ° is applied to the first electrode (31) and the second electrode (32), the container (5) has a sufficient strength in the refrigerator. The electric field is formed almost uniformly. Therefore, it is possible to suppress a bias in the freshness-maintaining effect of the fresh food (6) loaded in the refrigerator.

In particular, in the present embodiment, AC voltages having phases different from each other by 180 ° are applied to the first electrode (31) and the second electrode (32). According to this configuration, when the amplitude of the AC voltage waveform fluctuates, points where the potential difference becomes the maximum of 8 kV are periodically generated. Therefore, an electric field of sufficient strength is formed in the container (5).

In this embodiment, the AC power supply (33) is a three-phase AC power supply, and the electric field forming device (30) includes a power supply circuit (40) that generates AC voltages having different phases from the three-phase AC power supply (33). There is. Further, the power supply circuit (40) is configured by using a transformer (34) and a first booster (35) and a second booster (36) connected in parallel to the transformer (34). According to this configuration, it is possible to create a high voltage of alternating current having the same frequency but different phases by 180 ° with a simple configuration. As a result, an electric field of sufficient strength can be formed in the storage (5) with a simple configuration.

In the present embodiment, the first booster (35) and the second booster (36) have a voltage application terminal (35p, 36p) and a ground terminal (35g, 36g), respectively. Then, the voltage application terminals (35p, 36p) are connected to the respective electrodes (31, 32), while the ground terminals (35g, 36g) are connected to the ground point of the reference potential (casing of the container (5)).

According to this embodiment, one terminal on the secondary side of the power supply circuit (40) is connected to each electrode (31, 32), and the other terminal is grounded to be connected between the electrodes (31, 32). The potential difference is stable, and the potential difference between each electrode (31, 32) and the grounding point is also stable. Therefore, the electric field formed in the container (5) is stable. Further, by grounding the other side of the secondary side of the power supply circuit (40), it becomes difficult for electric charges to be accumulated in the electrodes (31, 32), and it is possible to prevent the potential difference between the electrodes (31, 32) from becoming too large. ..

Further, according to the present embodiment, the voltage to ground of the electrodes (31, 32) (potential difference between the electrodes (31, 32) and the container (5)) is smaller than the voltage between the electrodes. As a result, it is not necessary to provide a large amount of insulating material, so that the cost required for insulation can be suppressed.

<< Embodiment 2 >>
The second embodiment will be described.

The second embodiment is an example in which the configuration of the electric field forming apparatus (30) is different from that of the first embodiment. Specifically, the second embodiment has a different configuration of the power supply circuit (40) from the first embodiment. In the second embodiment, AC voltages having phases 120 ° or 240 ° different from each other are applied to the plurality of electrodes.

As shown in FIG. 5, this power supply circuit (40) includes a three-phase 400V AC power supply (33), a first booster (35), a second booster (36), and a third booster (37). ) And. The coil on the primary side of the first booster (35) is connected to the R-phase power line and the S-phase power line of the AC power supply (33). The coil on the secondary side of the first booster (35) is connected to a voltage application terminal (35p) connected to the U-phase electrode (31U) and a ground terminal (35g) to be grounded.

The coil on the primary side of the second booster (36) is connected to the S-phase power line and the T-phase power line of the AC power supply (33). The coil on the secondary side of the second booster (36) is connected to a voltage application terminal (36p) connected to the V-phase electrode (31V) and a ground terminal (36g) to be grounded.

The coil on the primary side of the third booster (37) is connected to the T-phase power line and the R-phase power line of the AC power supply (33). The coil on the secondary side of the third booster (37) is connected to a voltage application terminal (37p) connected to the W phase electrode (31W) and a ground terminal (37g) to be grounded.

In the second embodiment, as shown in FIG. 6, in the plurality of electrodes arranged in the refrigerator of the container (5), the U-phase electrode (31U) and the V-phase electrode (31V) face each other, and the V-phase electrode (31V) and the W-phase electrode (31W) are opposed to each other, and the W-phase electrode (31W) and the U-phase electrode (31U) are arranged to face each other. According to this arrangement, the voltages applied to the electrodes facing each other have the same frequency and are 120 ° out of phase with each other. The voltages applied to these three types of electrodes (31U, 31V, 31W) are all out of phase.

Other configurations of this second embodiment are the same as those of the first embodiment.

In the electric field forming apparatus (30), the operation of the power supply circuit (40) is controlled by the controller (16), and the frequencies of the power supply circuit (40) to the first electrode (31) and the second electrode (32) are the same. AC voltages with different phases of 120 ° or 240 ° are applied. The voltage application terminal (35p) of the first booster (35) is connected to the first electrode (31), and the voltage application terminal (36p) of the second booster (36) is connected to the second electrode (32). Will be done.

In this embodiment, the frequencies of the AC voltages applied to the plurality of electrodes (31U, 31V, 31W) are the same but the phases are 120 ° or 240 ° different. Then, a point at which the potential difference becomes large is periodically generated while the amplitude of the voltage waveform fluctuates, and an electric field having sufficient strength is formed in the storage (5) at that point.

Due to this potential difference, a stable electric field having the desired strength is formed in the container (5). Therefore, it becomes easy to maintain the freshness of the fresh food stored in the container (5).

<< Other Embodiments >>
The above embodiment may have the following configuration.

For example, the power supply circuit (40) of the electric field forming apparatus (30) may be configured to generate AC voltages having different phases from the single-phase AC power supply (33) as shown in FIG. In FIG. 7, the power supply circuit (40) has a first booster (35) and a second booster (36) in addition to a single-phase 100V AC power supply (33). The first booster (35) and the second booster (36) apply, for example, an AC voltage of plus 6 kV to the first electrode (31) and an AC voltage of minus 6 kV to the second electrode (32). ..

According to this configuration, a potential difference of up to 12 kV is generated between the electrodes (31, 32) of the container (5). Due to this potential difference, an electric field is formed in the container (5). The formation of an electric field makes it easier to maintain the freshness of fresh food stored in the container (5).

In each of the above embodiments, voltages having different phases of 180 °, 120 °, or 240 ° are applied to the plurality of electrodes (31,32) (31U, 31V, 31W), but the plurality of electrodes (31U, 31V, 31W) have different phases. 31,32) The voltage applied to (31U, 31V, 31W) may differ from the above value if there is a phase difference. Even in that case, the points at which the potential reaches the maximum appear at different timings at multiple electrodes (31,32) (31U, 31V, 31W), so an electric field with sufficient strength is obtained compared to the case where the voltages are in phase. Can be formed. Further, in each of the above embodiments and modifications, the voltage applied to the plurality of electrodes is not limited to 4 kV or 6 kV. For example, it may be changed between 0.5 kV and 10 kV.

In the above embodiment, the phases of the voltages applied to the plurality of electrodes (31, 32) (31U, 31V, 31W) may be all different or some may be different. As an example in which the phases of the voltages applied to the plurality of electrodes are partially different, for example, in FIG. 3C, the opposing electrodes (31) arranged in odd numbers from the front (left direction in the figure) of the container (5) are arranged. It is possible to have the same phase and to have different phases of the opposing electrodes (31) arranged at even numbers. In this way, even if the phases of the voltages applied to some of the plurality of electrodes (31,32) (31U, 31V, 31W) are different, the inside of the refrigerator will not be in the same phase, so compared to the conventional one. It is possible to form an electric field of sufficient strength.

Further, the storage device provided with the electric field forming device (30) of the present disclosure is not limited to the reefer container used for land transportation and sea transportation, and may be a stationary storage device.

The electric field forming device (30) of the present disclosure is not only applied to a storage device (cold storage device) that cools the inside of a refrigerator and stores the goods, but may be applied to a storage device that stores the goods at room temperature. .. Even in a storage device for storing an item at room temperature, it is possible to prevent the item from being damaged by providing an electric field forming device having a plurality of electrodes having different voltage phases.

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the claims. In addition, the above embodiments and modifications may be appropriately combined or replaced as long as they do not impair the functions of the present disclosure.

As described above, the present disclosure is useful for storage devices.

1 Reefer container (storage device)
5 container (storage)
16 Controller (control unit)
30 Electric field forming device
31 First electrode
32 Second electrode
31U U phase electrode
31V V phase electrode
31W W phase electrode
33 AC power supply (three-phase AC power supply, single-phase AC power supply)
35 1st booster (1st booster circuit)
36 Second booster (second booster circuit)
37 Third booster (third booster circuit)
35p voltage application terminal
35g ground terminal
36p voltage application terminal
36g ground terminal
37p voltage application terminal
37g ground terminal
40 power circuit

Claims (8)

A storage device including a storage (5) and an electric field forming device (30) that forms an electric field in the storage (5).
The electric field forming apparatus (30) includes a plurality of electrodes (31,32) (31U, 31V, 31W) arranged in the storage (5), and the electrodes (31,32) (31U, 31V, It is equipped with an AC power supply (33) connected to 31W) and a control unit (16) that controls voltage application to the electrodes (31,32) (31U, 31V, 31W).
The control unit (16) is a storage device characterized in that AC voltages having the same frequency but different phases are applied to the plurality of electrodes (31, 32) (31U, 31V, 31W). In claim 1,
A storage device characterized in that the plurality of electrodes (31, 32) (31U, 31V, 31W) are arranged to face each other inside the storage (5). In claim 1 or 2,
The control unit (16) is a storage device characterized in that AC voltages having phases different from each other by 180 ° are applied to the plurality of electrodes (31, 32). In claim 3,
The AC power supply (33) is a single-phase AC power supply.
The electric field forming device (30) is a storage device including a circuit (40) that generates AC voltages having different phases from the single-phase AC power supply. In claim 3,
The AC power supply (33) is a three-phase AC power supply.
The electric field forming device (30) is a storage device including a circuit (40) that generates AC voltages having different phases from the three-phase AC power supply. In claim 1 or 2,
The control unit (16) is a storage device characterized in that AC voltages having phases different from each other by 120 ° or 240 ° are applied to the plurality of electrodes (31U, 31V, 31W). In any one of claims 1 to 6,
The electric field forming apparatus (30) includes a plurality of boosting circuits (35, 36, 37) for boosting voltages having different phases.
A storage device characterized in that the secondary side of each of the booster circuits (35, 36, 37) has a voltage application terminal (35p, 36p, 37p) and a ground terminal (35g, 36g, 37g). In any one of claims 1 to 7,
A storage device including a refrigerator (10) for cooling the inside of the storage (5).

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