JP2011033337A - Fan driving device and air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fan driving device and an air conditioner capable of stably starting a plurality of fans provided in one air passage (S). <P>SOLUTION: A fan control means (41) starts an inverter driven first fan (21). Then, when the first fan (21) reaches steady operation after passage of a predetermined delay time, the fan control means (41) starts a direct-driven second fan (22). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a fan drive device that controls drive motors for a plurality of fans provided in an air passage, and an air conditioner including the fan drive device.

  Conventionally, multi-type air conditioners and the like have used outdoor units in which a plurality of fans are housed. For example, Patent Document 1 discloses this type of outdoor unit.

  In this outdoor unit, two fans and a heat exchanger are housed in an air passage in a box-shaped casing. The casing has an air inlet on one side and an air outlet on the other side. The two fans are supported in a posture in which their axes are parallel in the vicinity of the air outlet.

JP-A-2005-121310

  In the outdoor unit as described above, a plurality of fans are operated by energizing each drive motor of the plurality of fans simultaneously. That is, in the outdoor unit, a plurality of fans are activated simultaneously to promote heat exchange between the refrigerant in the heat exchanger and the outdoor air.

  However, when such a fan is started, a relatively large starting current flows from the power source to each drive motor until each fan that has been in a stopped state is put into steady operation. In particular, in an outdoor unit or the like in which a plurality of fans are housed in one air passage, the airflow (differential pressure) generated by the rotation of one fan interferes with the other fan, and the other fan is temporarily reversed. Sometimes it rotates. Moreover, in an outdoor unit, each fan may reversely rotate by the influence of strong winds, such as a typhoon. As described above, if all fans are started simultaneously under the condition that each fan rotates in reverse, the current load of the power supply temporarily increases extremely, the power protection device etc. The fan may not start normally.

  This invention is made in view of this point, The objective is to provide the fan drive device and air conditioner which can start the several fan provided in one air path stably. is there.

  1st invention presupposes the fan drive device which controls each drive motor (23,24) of the several fan (21,22) provided in one air path (S). And this fan drive device has a fan control means (41) for starting at least two of the plurality of fans (21, 22) at different timings when starting the plurality of fans (21, 22). It is characterized by having.

  In the first invention, the plurality of fans (21, 22) provided in one air passage (S) are activated at different timings by the fan control means (41). That is, in the present invention, the starting current flows from the power source to the drive motors (23, 24) of the fans (21, 22) at different timings. Therefore, the current load of the power supply can be prevented from being extremely increased temporarily, and each fan (21, 22) can be started stably.

  In a second aspect based on the first aspect, the drive motor of the first fan (21) is composed of an inverter type drive motor (23) connected to a power source (30) via an inverter circuit (31). On the other hand, the drive motor of the second fan (22) is composed of a direct drive motor (24) directly connected to the power source (30), and the fan control means (41) is the first fan (21). ) Is started before the second fan (22). As used herein, “a direct drive motor directly connected to a power supply” means that the power supply and the direct drive motor are directly connected electrically without an inverter circuit. Of course, an electromagnetic switch, a relay, and other control circuits may be interposed between the power source and the direct drive motor.

  In the second invention, the first fan (21) is driven by the inverter type drive motor (23), while the second fan (22) is driven by the direct drive type drive motor (24). Here, if the first fan (21) and the second fan (22) are operated at the same time, the second fan (22) to which current is sent directly from the power source rather than the inverter-driven first fan (21). Often has a faster rise time. In such a case, the airflow generated with the rotation of the second fan (22) may cause the first fan (21) that has not yet reached the steady state to reversely rotate, and the first fan (21 A new problem arises that the starting current of Here, if the start-up current of the inverter-driven first fan (21) is extremely increased, the inverter circuit (31) breaks down or a protection circuit for protecting the inverter circuit (31) is activated. The first fan (21) cannot be started.

  In order to solve this problem, in the present invention, the fan control means (41) starts the inverter-driven first fan (21) before the direct-input second fan (22). . For this reason, since the first fan (21) reaches a steady operation without receiving the interference of the air flow of the second fan (22), the starting current of the first fan (21) does not increase extremely. . Therefore, the inverter-driven first fan (21) that is particularly susceptible to the start current can be started stably. On the other hand, the second fan (22) that is started after the first fan (21) is started may reversely rotate due to the airflow accompanying the rotation of the first fan (21), so the second fan (22) is started. Current will increase. However, since the second fan (22) is driven by the direct drive motor (24), the second fan (22) is less affected by the starting current than the first fan (21). Therefore, even if the starting current of the second fan (22) increases, the second fan (22) can be started stably.

  According to a third invention, in the first invention, only the drive motor (23) of the first fan (21) is provided with the drive motor (23) so that the starting current of the drive motor (23) does not exceed a specified current value. ), And the fan control means (41) starts the first fan (21) before the second fan (22). The “starting current” means a value of a current flowing from the power source to the motor from the start of the fan to the predetermined steady operation. In addition, the “protection circuit” described above causes the drive motor (23) to be forcibly stopped when the start current of the drive motor (23) exceeds a specified current value, or the start current of the drive motor (23) As the value approaches, the starting current is forcibly regulated so that the starting current does not reach the specified current value.

  In the third aspect of the invention, the drive motor (23) of the first fan (21) is provided with the protection circuit (33), while the drive motor (24) of the second fan (22) is not provided with the protection circuit. Here, in the present invention, since the fan control means (41) activates the first fan (21) first, the first fan (21) is interfered by the air flow accompanying the rotation of the second fan (22). Without a steady operation. Therefore, when the first fan (21) is started, the starting current of the first fan (21) does not increase extremely, and the operation of the protection circuit of the first fan (21) can be avoided beforehand. On the other hand, if the second fan (22) is started in a state where the first fan (21) has already reached steady operation, the starting current of the second fan (22) increases. However, since the protection circuit is not provided for the second fan (22), the second fan (22) never stops.

  According to a fourth invention, in the first invention, the drive motors (23, 24) of the first fan (21) and the second fan (22) are defined by the starting currents of the drive motors (23, 24). Protection circuits (33, 34) for controlling the drive motors (23, 24) so as not to exceed the current value are provided, respectively, and the specified current value of the first fan (21) is the specified value of the second fan (22). The fan control means (41) is set to be smaller than the current value, and the first fan (21) is activated before the second fan (22).

  In the fourth invention, the protection circuits (33, 34) are provided in the drive motors (23, 24) of the first fan (21) and the second fan (22), respectively. The first fan (21) is set to have a specified current value (so-called protection value) smaller than that of the second fan (22). Here, in the present invention, since the fan control means (41) activates the first fan (21) first, as described above, the first fan (21) is activated rather than the second fan (22). Current tends to be small. Therefore, even if the protection value of the first fan (21) is set to be small, it is possible to avoid that the protection circuit (33) of the first fan (21) is activated.

  According to a fifth aspect of the present invention, when the first fan (21) and the second fan (22) are started simultaneously, the starting current of the first fan (21) is larger than the starting current of the second fan (22). The fan control means (41) starts the first fan (21) before the second fan (22).

  In the fifth invention, when the fan control means (41) starts the first fan (21) and the second fan (22) at the same time, the first fan (21) having a higher starting current is started first. Let This will be described below.

  When multiple fans (21, 22) are started at the same time, depending on the fan's ability, fan start-up characteristics, ease of interference with airflow from other fans (ease of reverse rotation), etc. Differences in fan start-up current. A fan having a high startup current under such a simultaneous startup condition can be regarded as a fan that easily increases the startup current even if each fan is started at different timings, and easily causes a failure of the drive motor.

  Therefore, the fan control means (41) of the present invention has a first fan (21) having a relatively large starting current and a second fan (22) having a relatively small starting current when compared under the simultaneous starting conditions. ) Before starting. For this reason, the first fan (21), whose starting current is relatively easy to increase, does not receive airflow interference caused by the rotation of the second fan (22), so that the starting current of the first fan (21) is further increased. The increase can be avoided.

  In a sixth aspect based on the first aspect, the drive currents of the drive motors (23, 24) are defined for the drive motors (23, 24) of the first fan (21) and the second fan (22). Protection circuits (33, 34) for controlling the drive motors (23, 24) so as not to exceed the current value are provided, respectively. When the first fan (21) and the second fan (22) are activated simultaneously, When the margin of the starting current with respect to the specified current value of the first fan (21) is smaller than the margin of the starting current with respect to the specified current value of the second fan (22), the fan control means (41) The first fan (21) is started before the second fan (22).

  In the sixth invention, if the first fan (21) and the second fan (22) are started at the same time, the fan with a smaller so-called margin is started first.

  As described above, when a plurality of fans (21, 22) are started at the same time, there is a difference in the starting current of each fan according to the characteristics of each fan. Therefore, when each fan (21, 22) is provided with a protection circuit (33, 34) in which a predetermined protection value is set, each activation is performed for the protection value of each fan (21, 22). The amount of current that can be spared is also different. That is, when the respective fans (21, 22) are simultaneously started, it is also different how much each starting current is lower than the protection value of each fan. The difference between the protection value and the starting current or the ratio of the difference to the protection value is defined as “margin”. A fan having a small margin under such simultaneous activation conditions can be regarded as a fan in which the protection circuit is easily activated even if each fan is activated at different timings.

  Therefore, the fan control means (41) of the present invention has the first fan (21) having a smaller margin when compared under the simultaneous start condition than the second fan (22) having a relatively larger margin. Also start first. For this reason, the first fan (21) in which the protection circuit (33) is easy to operate does not receive airflow interference caused by the rotation of the second fan (22). It can be avoided that the protection circuit (33) is activated due to an increase.

  According to a seventh invention, in any one of the first to sixth aspects, the fan control means (41) activates the second fan (22) after a predetermined set time has elapsed since the activation of the first fan (21). It is characterized by doing.

  In the seventh invention, the fan control means (41) activates the second fan (22) after a set time has elapsed since the activation of the first fan (21). For this reason, the start timings of the first fan (21) and the second fan (22) can be reliably shifted, and an increase in the start-up current of the first fan (21) can be reliably prevented.

  In an eighth invention according to any one of the first to sixth aspects, the fan control means (41) determines the start timing of the second fan (22) based on the rotational speed of the first fan (21). A fan drive device characterized by that.

  In the eighth invention, the fan control means (41) determines the start timing of the second fan (22) based on the rotational speed of the first fan (21) started previously. For this reason, it is possible to start the second fan (22) in a state where the first fan (21) has reached a predetermined rotation speed, and reliably prevent an increase in the starting current of the first fan (21). Can do.

  In a ninth aspect based on any one of the first to sixth aspects, the fan control means (41) determines the start timing of the second fan (22) based on the start current of the first fan (21). It is characterized by doing.

  In the ninth invention, the fan control means (41) determines the start-up timing of the second fan (22) based on the start-up current of the first fan (21) started up earlier. For this reason, under the condition that the starting current of the first fan (21) is extremely high, the starting of the second fan (22) can be prohibited, and the starting current of the first fan (21) is further increased. Can be reliably prevented.

  In a tenth aspect based on the first aspect, the drive motor for the first fan (21) is composed of an inverter type drive motor (23) connected to a power source (30) via an inverter circuit (31). On the other hand, the drive motor of the second fan (22) is composed of a direct drive motor (24) that is directly connected to the power source (30), and the first fan (21) rotates forward from the start. If so, the fan control means (41) starts the second fan (22) before the first fan (21).

  In the tenth invention, as in the second invention, the drive motor of the first fan (21) is composed of an inverter type drive motor (23), and the drive motor of the second fan (22) is a direct drive motor. Consists of. Here, if the first fan (21) is rotated forward from the start before the first fan (21) is rotated under the influence of a strong wind caused by a typhoon or a building wind, the first fan (21) is started as it is. The DC voltage in the inverter circuit (31) of the first fan (21) may be boosted to activate the protection device. On the other hand, in the present invention, when the first fan (21) is rotating forward from before starting, the fan control means (41) starts the second fan (22) first. If it does in this way, it can receive the interference of the airflow which arises from the 2nd fan (22), and can reduce the rotational speed of the normal rotation side of the 1st fan (21). Accordingly, it is possible to avoid a problem that the DC voltage in the inverter circuit (31) of the first fan (21) is boosted when the first fan (21) is subsequently started.

  An eleventh invention is characterized in that, in the second or tenth invention, the drive motor of the first fan (21) is constituted by a brushless DC motor.

  In the eleventh invention, the inverter type drive motor of the first fan (21) is constituted by a brushless DC motor (23). Since this brushless DC motor (23) rotates a rotor with an induced voltage by a built-in magnet, for example, the starting current of the first fan (21) tends to be larger than that of an induction motor. On the other hand, in the present invention, since the start control of the first fan (21) and the second fan (22) is performed so as to reduce the start current of the first fan (21), the brushless DC motor (23 ), The first fan (21) can be started stably.

  The twelfth invention includes a casing (11), a plurality of fans (21, 22) provided in one air passage (S) provided in the casing (11), and the plurality of fans (21, 22). It is an air conditioner provided with the fan drive device (40) of any one of Claim 1 thru | or 11 which controls each drive motor (23,24).

  In the twelfth invention, the fan drive device (40) of the first to eleventh inventions described above is applied to an air conditioner. Therefore, in this air conditioner, the plurality of fans (21, 22) can be stably started.

  A thirteenth invention is the twelfth invention, comprising an outdoor unit (10) arranged outside, wherein the plurality of fans (21, 22) are air in the casing (11) of the outdoor unit (10). It is provided in the passage (S).

  In the thirteenth invention, the fan drive device (40) of the first to eleventh inventions described above is applied to an outdoor unit (10) of an air conditioner. In the outdoor unit (10), there is a high possibility that each fan (21, 22) will rotate in reverse from the start-up due to strong winds caused by typhoon or building wind. Therefore, in the outdoor unit (10), the starting current of each fan (21, 22) is likely to increase. On the other hand, in the present invention, since the starting current of each fan (21, 22) is reduced by the fan control means (41), a plurality of fans (21, 22) can be stabilized even under such adverse conditions. Can be activated.

  A fourteenth invention is the twelfth invention, comprising an indoor unit arranged indoors, wherein the plurality of fans (21, 22) are provided in an air passage (S) in a casing (11) of the indoor unit. It is characterized by being.

  In the fourteenth invention, the fan drive device (40) of the first to eleventh inventions described above is applied to an indoor unit of an air conditioner. Therefore, in this indoor unit, the plurality of fans (21, 22) can be stably started.

  In the present invention, the start timing of the plurality of fans (21, 22) is shifted by the fan control means (41). Therefore, according to the present invention, the current load of the power source does not temporarily increase extremely, and each fan (21, 22) can be stably started.

  In addition, when other control power sources are shared by the power sources of the fans (21, 22), if the fans (21, 22) are started simultaneously, the current flowing from the power source to the fans (21, 22) There may be a problem that the voltage of other control power supply or the like decreases with an increase in the voltage. On the other hand, in the present invention, since the current load of the temporary power source is suppressed by shifting the start timing of each fan (21, 22), it is possible to prevent the voltage drop of other control power sources, Other control power supplies can perform the desired control operations.

  In the second invention, the first fan (21) driven by the inverter is started before the second fan (22) driven by direct insertion. Therefore, according to the present invention, it is possible to suppress an increase in the starting current for the inverter-driven first fan (21) and to prevent a failure of the inverter circuit (31) of the first fan (21). Therefore, the first fan (21) and the second fan (22) can be stably started.

  In the third aspect of the invention, the first fan (21) having the protection circuit (33) is started before the second fan (22). In the fourth aspect of the invention, the first fan (21) having a low protection value is started before the second fan (22) having a high protection value. For this reason, according to these invention, it can prevent reliably that a protection circuit (33) will act | operate at the time of starting of a 1st fan (21). Accordingly, it is possible to improve the stability at the time of starting the first fan (21).

  In the fifth aspect of the invention, the first fan (21) whose starting current is likely to increase is started before the second fan (22). For this reason, the first fan (21) can be stably started without further increasing the starting current of the first fan (21).

  In the sixth invention, the first fan (21) with a small margin is started before the second fan (22). For this reason, according to the present invention, it is possible to reliably prevent the protection circuit (33) of the first fan (21) from operating when the first fan (21) is started, and the first fan (21). Can be started stably.

  In the seventh invention, the start timings of the first fan (21) and the second fan (22) are shifted according to a predetermined set time. For this reason, according to the present invention, the second fan (22) can be started after the first fan (21) is reliably started up. Therefore, the reverse rotation of the first fan (21) can be avoided in advance, and an increase in the starting current of the first fan (21) can be prevented. In addition, when the first fan (21) is less susceptible to airflow interference caused by the rotation of the second fan (22), by setting the set time to a relatively short time, both fans (21, 22) It is possible to shorten the time until the steady operation.

  In the eighth invention, the second fan (22) is activated based on the rotational speed of the first fan (21). For this reason, according to the present invention, the second fan (22) can be started when the rotational speed of the first fan (21) becomes high enough. Therefore, it is possible to reliably avoid the reverse rotation of the first fan (21), and it is possible to reliably prevent an increase in the starting current of the first fan (21).

  In the ninth invention, the second fan (22) is started based on the starting current of the first fan (21). For this reason, according to this invention, a 2nd fan (22) can be started when the starting current of a 1st fan (21) becomes small. Therefore, the starting current of the first fan (21) does not increase extremely, and the first fan (21) can be started stably.

  In the tenth aspect of the invention, when the first fan (21) is rotating forward from the start-up due to strong wind or the like, the second fan (22) is started first. Therefore, according to the present invention, the rotational speed on the positive rotation side of the first fan (21) can be reduced with the air flow generated from the second fan (22), and the inverter circuit (31) of the first fan (21). The DC voltage boost can be suppressed. Therefore, it is possible to prevent the first fan (21) from being stopped by the voltage protection device or the like.

  In the eleventh invention, when the first fan (21) is driven by the brushless DC motor (23), the fan activation control according to the second invention or the tenth invention is performed. Therefore, the first fan (21) can be stably started even for the brushless DC motor (23) in which the starting current and the starting voltage are likely to increase.

  In the twelfth invention, the fan drive device (40) of the first to eleventh inventions is applied to an air conditioner. In particular, when starting the plurality of fans (21, 22) provided in the outdoor unit (10) according to the thirteenth aspect of the invention, the starting currents of the fans (21, 22) are affected by strong winds such as typhoons. However, according to the thirteenth invention, the fans (21, 22) can be stably started even under such an adverse condition. In the fourteenth invention, the plurality of fans (21, 22) provided in the indoor unit can be stably started. Therefore, according to the twelfth to fourteenth aspects, the air conditioner can be operated reliably, and the reliability of the air conditioner can be ensured.

It is a schematic block diagram of the outdoor unit of the air conditioner which concerns on embodiment. It is a control circuit diagram of a drive motor. It is a time chart explaining the starting control operation of the fan by the fan control means which concerns on embodiment. It is a schematic block diagram of the outdoor unit after the 1st fan starting and before the 2nd fan starting. It is a schematic block diagram of the outdoor unit after a 2nd fan start-up. 10 is a time chart for explaining a fan start-up control operation by a fan control unit according to Modification 1;

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  As shown in FIG. 1, the fan drive device (40) which concerns on this embodiment controls the several fan (21, 22) mounted in the outdoor unit (10) of an air conditioner.

  The outdoor unit (10) includes a box-shaped casing (11). A first suction port (12) and a second suction port (13) are formed in the left and right side surfaces of the casing (11), respectively. On the other hand, at the upper part of the casing (11), a first outlet (14) is formed near the first inlet (12), and a second outlet (15) is formed near the second inlet (13). Has been. In the casing (11), one air passage (S) communicating with each inlet (12, 13) and each outlet (14, 15) is formed.

  The air passage (S) in the casing (11) has a first heat exchanger (16) in the vicinity of the first suction port (12) and a second heat exchanger (in the vicinity of the second suction port (13)). 17) are installed. Each heat exchanger (16, 17) is connected to the indoor unit of the air conditioner by a refrigerant pipe (not shown). That is, in this air conditioner, a refrigerant circuit is configured in which a refrigerant circulates and performs a refrigeration cycle. Each of the heat exchangers (16, 17) functions as a condenser that imparts the heat of condensation of the refrigerant to the outdoor air, or an evaporator that removes the heat of evaporation of the refrigerant from the outdoor air.

  The first fan (21) and the second fan (22) are provided in parallel in the left-right direction in the air passage (S) in the casing (11). That is, the first fan (21) and the second fan (22) are arranged in parallel with each other with respect to one air passage (S). The first fan (21) is provided near the inside of the first air outlet (14), and the second fan (22) is provided near the inside of the second air outlet (15). That is, the first fan (21) and the second fan (22) are provided in the air passage (S) so as to correspond to the air outlets (14, 15). Each fan (21, 22) sucks outdoor air from each suction port (12, 13) into the air passage (S) in the casing (11), and the outdoor air is sent to each outlet (14, 15). The ventilation means which discharges to the outdoors from is comprised.

  A first motor (23) is connected to the first fan (21) via a drive shaft, and a second motor (24) is connected to the second fan (22) via a drive shaft. Each motor (23, 24) constitutes a drive means for driving each fan (21, 22). In the present embodiment, each motor (23, 24) is constituted by a three-phase induction motor.

  As shown in FIG. 2, the first motor (23) and the second motor (24) are connected in parallel to the power source (30). An inverter circuit (31) is connected between the first motor (23) and the power source (30). That is, the 1st motor (23) comprises the inverter type drive motor which makes variable the air volume of a 1st fan (21).

  On the other hand, the second motor (24) and the power source (30) are directly connected without an inverter circuit. That is, the second motor (24) constitutes a motor (a direct drive motor) that performs a direct drive. An electromagnetic switch (32) for switching ON / OFF of the second motor (24) is connected between the second motor (24) and the power source (30).

  The first motor (23) is provided with a first protection circuit (33), and the second motor (24) is provided with a second protection circuit (34). Each protection circuit (33, 34) has motor protection means for controlling each motor (23, 24) so that the starting current of each motor (23, 24) does not exceed a predetermined specified current value (so-called protection value). It is composed. Specifically, each protection circuit (33, 34) of the present embodiment forcibly stops each motor (23) when the instantaneous starting current of each motor (23, 24) reaches the protection value. . In addition, the protection level of each protection circuit (23, 24) is different between the inverter-driven first motor (23) and the direct drive-driven second motor (24). That is, since the first motor (23) is connected to the power source (30) via the inverter circuit (31), the first protection circuit (33) is surely prevented in order to prevent failure of the inverter circuit (31). Is set smaller than the protection value of the second protection circuit (34).

  Moreover, the fan drive device (40) of this invention is provided between the power supply (30) and each motor (23, 24). The fan driving device (40) includes fan control means (41) for controlling the motors (23, 24) of the fans (21, 22). This fan control means (41) improves the stability at the start of each fan (21, 22) by shifting the start timing of the first fan (21) and the second fan (22) from each other. ing.

-Fan startup control operation-
Next, the control operation at the time of starting each fan (21, 22) by the fan control means (41) will be described. In this outdoor unit (10), both the first fan (21) and the second fan (22) are operated to simultaneously exchange heat between the outdoor air and the refrigerant in each heat exchanger (16, 17). Driving is possible.

  The fan control means (41) of the present embodiment starts the second fan (22) after a predetermined set time (delay time) has elapsed since the start of the first fan (21), so that the first fan (21) And the start timing of the second fan (22) are shifted.

  Specifically, as shown in FIG. 3, first, the fan control means (41) activates only the first fan (21). As a result, the rotational speed of the first fan (21) gradually increases. And outdoor air is suck | inhaled from the 1st suction inlet (12) in the casing (11), and this outdoor air is discharged | emitted from a 1st blower outlet (14).

  On the other hand, when only the first fan (21) is activated in this way, the air pressure in the air passage becomes slightly lower than the air pressure outside the casing (11). For this reason, as shown in FIG. 4, outdoor air is suck | inhaled in a casing (11) also from a 2nd blower outlet (15). As a result, the second fan (22) positioned in the vicinity of the second outlet (15) rotates in the direction opposite to the rotation direction during normal operation. Therefore, as shown in FIG. 3, after the first fan (21) is started, the reverse rotation speed of the second fan (22) increases as the rotation speed of the first fan (21) increases.

  Thereafter, when a predetermined delay time has elapsed since the start of the first fan (21), the fan control means (41) starts the second fan (22). When the second fan (22) is activated, the rotation direction of the second fan (22) shifts from reverse rotation to normal rotation. And when several seconds pass after starting of a 2nd fan (22), both a 1st fan (21) and a 2nd fan (22) will reach a steady operation. As a result, as shown in FIG. 5, the outdoor air sucked into the casing (11) from the suction ports (12, 13) passes through the heat exchangers (16, 17) and then flows into the corresponding blowers. It is discharged from the outlet (14, 15) to the outside.

  As described above, in the fan activation control operation described above, the first fan (21) and the second fan (22) are activated at different timings by the fan control means (41). Here, if the first fan (21) and the second fan (22) are started at the same time, the starting currents of both fans (21, 22) increase at the same time, so the current load of the power source (30) is also temporarily increased. May increase significantly. On the other hand, in the fan start-up control operation of this embodiment, the start-up current flows from the power source (30) to the motors (23, 24) of the fans (21, 22) at different timings. The load does not increase excessively temporarily. Therefore, it is possible to reliably avoid the operation of the protection device of the power source (30) or the voltage drop of other control power sources sharing the power source (30).

  In particular, when strong winds blow due to typhoons, or when strong winds blow into the outdoor unit (10) due to building winds, etc., the fans (21, 22) may rotate in reverse before starting. In this case, the starting current of each fan (21, 22) may further increase. However, by shifting the activation timing of the fans (21, 22) in this way, the fans (21, 22) can be stably activated even under such adverse conditions.

  Also, if the first fan (21) and the second fan (22) are started simultaneously, the second fan (22) in which current flows directly from the power source (30) rather than the inverter driven first fan (21). The rise time is often faster. In such a case, the air flow generated with the rotation of the second fan (22) causes the first fan (21) that has not yet reached steady operation to reversely rotate, and the first fan (21) is activated. The current may increase extremely. As described above, in the first fan (21) driven by the inverter, the protection value of the first protection circuit (33) is set to be low in order to prevent a failure of the inverter circuit (31). For this reason, when the starting current of the first fan (21) is extremely increased for the above-described reason, the first protection circuit (33) is operated relatively easily, and the first fan (21) cannot be started. Problems also arise.

  On the other hand, in the fan start-up control operation of this embodiment, the fan control means (41) starts the inverter-driven first fan (21) before the direct-insertion-driven second fan (22). . For this reason, since the first fan (21) reaches a steady operation without receiving the interference of the air flow of the second fan (22), the starting current of the first fan (21) does not increase extremely. . Therefore, the inverter-driven first fan (21) that is particularly susceptible to the start current can be started stably.

  On the other hand, the second fan (22) activated after the first fan (21) is activated may reversely rotate due to the air flow accompanying the rotation of the first fan (21), as shown in FIG. Therefore, the starting current of the second fan (22) increases. However, the second fan (22) is driven by the direct drive motor (24), and the protection value of the second protection circuit (34) is set higher. Therefore, even if the starting current of the second fan (22) increases, the second protection circuit (34) does not operate. Therefore, when the fan start control operation of the present embodiment is performed, both the first fan (21) and the second fan (22) can be started stably.

  The delay time from when the first fan (21) is activated to when the second fan (22) is activated is preset in the fan driving device (40). This delay time is obtained, for example, experimentally according to the installation status of the outdoor unit (10) and the characteristics of the fans (21, 22). For example, as this delay time, the time from the start of the first fan (21) to the steady operation, the time that the first fan (21) does not reversely rotate even if the second fan (22) starts. Alternatively, a time is set such that the starting current of the first fan (21) does not reach the protection value of the first protection circuit (33). Specifically, the delay time is preferably in the range of 1 second to 20 seconds, and more preferably in the range of 10 seconds to 20 seconds.

-Effect of the embodiment-
In the above embodiment, the start timing of the plurality of fans (21, 22) is shifted by the fan control means (41). Therefore, the current load of the power source (30) does not increase temporarily, and each fan (21, 22) can be started stably. Moreover, it is possible to prevent the entire air conditioner from being disabled by reliably starting the fans (21, 22) in this way.

  Also. In the above-described embodiment, the inverter-driven first fan (21) is started before the direct drive-driven second fan (22). Accordingly, an increase in the starting current for the inverter-driven first fan (21) can be suppressed, and a failure of the inverter circuit (31) can be reliably prevented. In addition, when the first fan (21) is started, it is possible to reliably prevent the first protection circuit (33) from operating and the first fan (21) from stopping.

  Furthermore, in the said embodiment, the starting timing of a 1st fan (21) and a 2nd fan (22) is shifted using the preset delay time. For this reason, the second fan (22) can be started after the first fan (21) has reliably reached steady operation, and an increase in the starting current of the first fan (21) can be reliably prevented.

-Modification of fan start-up control operation-
In the fan drive device (40) according to the above-described embodiment, the startup control of the fan may be performed as follows.

<Modification 1>
The fan control means (41) of Modification 1 determines the start timing of the second fan (22) based on the rotational speed of the first fan (21) that has been started first.

  Specifically, a predetermined activation determination rotational speed as shown in FIG. 6 is preset in the fan control means (41) of the first modification. First, the fan control means (41) activates the first fan (21) first. As a result, the rotational speed of the first fan (21) gradually increases. At this time, the second fan (22) rotates in the reverse direction as in the above embodiment.

  Thereafter, when the first fan (21) approaches steady operation and the rotational speed of the first fan (21) exceeds the activation determination rotational speed, the fan control means (41) activates the second fan (22). To do. When the second fan (22) is activated, the rotation direction of the second fan (22) shifts from reverse rotation to normal rotation. And if several seconds pass after starting a 2nd fan (22), a 1st fan (21) and a 2nd fan (22) will be in a steady operation. As a result, as shown in FIG. 5, the outdoor air sucked into the casing (11) from the suction ports (12, 13) passes through the heat exchangers (16, 17) and then flows into the corresponding blowers. It is discharged from the outlet (14, 15) to the outside.

  As described above, in the first modification, the second fan (22) is started based on the rotational speed of the first fan (21). For this reason, also in this modified example 1, the second fan (22) can be started when the rotation speed of the first fan (21) becomes high enough. Therefore, it is possible to reliably avoid the reverse rotation of the first fan (21), and it is possible to reliably prevent an increase in the starting current of the first fan (21).

  Note that the activation determination rotational speed for determining the activation timing of the second fan (22) is experimentally determined according to the installation status of the outdoor unit (10) and the characteristics of the fans (21, 22), for example. It is As the activation determination rotation speed, it is desirable to set a predetermined rotation speed on the positive rotation side of the first fan (21), and this activation determination rotation speed is the rotation at the time of steady operation of the first fan (21). It is good also as speed. Furthermore, if the first fan (21) can be reliably started, a predetermined rotation speed on the reverse rotation side of the first fan (21) may be set as the start determination rotation speed.

<Modification 2>
The fan control means (41) of Modification 2 determines the start timing of the second fan (22) based on the starting current of the first fan (21) that has been started first. Specifically, the fan control means (41) of the second modified example stabilizes the starting current of the first fan (21) at a relatively low level after the first fan (21) is started, and the first fan (21). When becomes a steady operation, the second fan (22) is started. For this reason, in the second modification, the second fan (22) can be started after the first fan (21) is completely in steady operation, and the starting current of the first fan (21) is increased. Can be reliably prevented.

<Modification 3>
For the first fan (21) and the second fan (22) of the above embodiment, when the first fan (21) is rotating forward from the start due to the influence of strong wind, the direct drive motor (24) The second fan (22) driven by the motor may be driven before the first fan (21) driven by the inverter type drive motor (23). In this case, if the first fan (21) is started as it is in the normal rotation state, the DC voltage in the inverter circuit (31) of the first motor (23) is boosted, and voltage protection operation is performed. May cause the first motor (23) to stop, but by starting the second fan (22) first, the first fan (22) is activated by the air flow accompanying the rotation of the second fan (22). 21) The rotational speed on the positive rotation side can be reduced. Therefore, even if the first fan (21) is started after that, it is possible to prevent the DC voltage in the inverter circuit (31) of the first motor (23) from being boosted.

-Control example with other fan combinations-
In the above embodiment, the first fan (21) is started before the second fan (22) in the combination of the first fan (21) driven by the inverter and the second fan (22) driven directly by the inverter. I have to. However, regardless of the drive method of each fan (21, 22), such as when each fan (21, 22) is inverter-driven or when both fans (21, 22) are both direct drive The start timing of each fan (21, 22) can be shifted as follows.

<Modification 4>
For example, when the protection circuit (33) is provided only for the first fan (21) and the protection circuit is not provided for the second fan (22), the fan control means (41) is provided with the first fan (21). ) The second fan (22) is started before. As a result, the first fan (21) reaches a steady operation without being interfered with the airflow accompanying the rotation of the second fan (22). Therefore, when the first fan (21) is activated, the activation current of the first fan (21) does not increase extremely, and the operation of the protection circuit of the first fan (21) can be avoided. On the other hand, if the second fan (22) is activated while the first fan (21) has already reached steady operation, the activation current of the second fan (22) will increase. However, since the protection circuit is not provided for the second fan (22), the second fan (22) never stops.

<Modification 5>
About the first fan (21) and the second fan (22), after relatively evaluating the magnitudes of the starting currents of both, the first fan (21) or the second fan (22) is started first. It can also be determined experimentally. Specifically, first, the first fan (21) and the second fan (22) are simultaneously started on a trial basis, and the starting currents of both fans (21, 22) are measured. In this case, it is desirable that the first fan (21) and the second fan (22) are both started from a stopped state or started forcibly reversely rotated by wind or the like. Here, if the starting current of the first fan (21) is larger than the starting current of the second fan (22), the first fan (21) is considered to have a characteristic that the starting current is relatively likely to increase. be able to. Therefore, in this case, the first fan (21) is started before the second fan (22). In this way, the first fan (21), whose starting current is relatively likely to increase, does not receive airflow interference caused by the rotation of the second fan (22), so the starting current of the first fan (21) Can be prevented from further increasing.

<Modification 6>
For the first fan (21) and the second fan (22), each of which is provided with a protection circuit (33, 34), after relatively evaluating the degree of margin of the starting current with respect to both protection values, It can also be determined experimentally whether the first fan (21) or the second fan (22) is activated first. Specifically, first, the first fan (21) and the second fan (22) are simultaneously started on a trial basis, and the starting currents of both fans (21, 22) are measured. In this case, it is desirable to start after both the first fan (21) and the second fan (22) are started from a stopped state or forcedly reversely rotated by wind or the like. Then, the margin of each fan (21) is obtained from the starting current of each fan (21, 22) and each protection value. This margin indicates how much the starting current is below the protection value of each fan. Specifically, the margin is obtained as a difference between the protection value and the starting current, or a ratio of the difference to the protection value.

  Here, if the margin of the first fan (21) is smaller than the margin of the second fan (22), the first fan (21) has a characteristic that the protection circuit (33) is easy to operate. Can be considered. Therefore, in this case, the first fan (21) is started before the second fan (22). For this reason, the first fan (21) in which the protection circuit (33) is easy to operate does not receive airflow interference caused by the rotation of the second fan (22). It can be avoided that the protection circuit (33) is activated due to an increase.

  In Modifications 5 and 6, both fans (21, 22) are activated simultaneously to determine the characteristics of the activation currents of both fans (21, 22). However, each fan (21, 22) may be started independently under the same conditions, and the starting current characteristics of each fan (21, 22) may be obtained.

<< Other Embodiments >>
The fan drive device (40) of the above-described embodiment may be configured as follows.

  In the fan start-up control of the above-described embodiment, after the first fan (21) is started up, the rotational speed of the first fan (21) is adjusted according to the air volume of the second fan (22) to be started thereafter, You may make it perform control which keeps the total air volume at the time of a standup of both fans (21, 22) constant.

  In the above-described embodiment, only the example of the two fans (21, 22) has been described. However, the above-described fan activation control operation can be performed in three or more fans. In this case, each fan may be activated at different timings, or after one fan is activated, the remaining two fans may be activated simultaneously.

  In the above-described embodiment, the inverter-driven first motor (23) is constituted by a three-phase induction motor, but a brushless DC motor may be used instead. Since this brushless DC motor rotates the rotor with an induced voltage generated by a built-in magnet, the starting current is particularly likely to increase. However, the above-described fan starting control can effectively suppress an increase in the starting current of the brushless DC motor. . In the above-described embodiment, the direct drive second motor (24) is configured by a three-phase induction motor, but a single-phase induction motor (for example, a tap motor) may be used instead.

  In addition, the protection circuit (33, 34) of the embodiment described above forcibly stops the fan when the startup current of the fan exceeds the protection value. Instead, the startup current of the fan is protected. In order to approach the value, the rotation speed of the fan may be forcibly decreased so that the starting current does not exceed the protection value. Further, specific examples of the protection circuit for the inverter type drive motor (23) described above include an instantaneous overcurrent protection device, an overload protection device, a stall prevention protection device, and the like, while the direct drive type drive motor (24) Examples of the protection circuit include an overcurrent relay and a breaker.

  Furthermore, in the above-described embodiment, the plurality of fans (21, 22) in the outdoor unit (10) of the air conditioner are controlled by the fan driving device (40) according to the present invention. However, for example, for an indoor unit such as a fan filter unit provided in a room of a semiconductor manufacturing factory, a plurality of fans (21, 22) are provided in the air passage (S) in the casing (11) of the indoor unit, and each fan The start control of (21, 22) may be performed by the fan drive device (40).

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for the fan drive device that controls the drive motors of a plurality of fans provided in the air passage and the air conditioner including the fan drive device.

10 Outdoor unit (air conditioner)
11 Casing
21 First fan
22 Second fan
23 First motor (drive motor)
24 Second motor (drive motor)
40 Fan drive unit
41 Fan control means S Air passage

Claims (14)

A fan driving device for controlling each driving motor (23, 24) of a plurality of fans (21, 22) provided in one air passage (S),
And a fan control means (41) for starting at least two of the plurality of fans (21, 22) at different timings when starting the plurality of fans (21, 22). Fan drive device. In claim 1,
The drive motor of the first fan (21) is composed of an inverter type drive motor (23) connected to a power source (30) via an inverter circuit (31),
The drive motor of the second fan (22) is composed of a direct drive motor (24) connected directly to the power source (30),
The fan control means (41) starts the first fan (21) before the second fan (22), and the fan driving device according to claim In claim 1,
Only the drive motor (23) of the first fan (21) is provided with a protection circuit (33) for controlling the drive motor (23) so that the starting current of the drive motor (23) does not exceed a specified current value. ,
The fan control means (41) starts the first fan (21) before the second fan (22), and the fan driving device according to claim In claim 1,
The drive motors (23, 24) of the first fan (21) and the second fan (22) are connected to the drive motors (23, 24) so that the starting currents of the drive motors (23, 24) do not exceed a specified current value. , 24) are respectively provided with protection circuits (33, 34),
The specified current value of the first fan (21) is set smaller than the specified current value of the second fan (22),
The fan control means (41) starts the first fan (21) before the second fan (22), and the fan driving device according to claim In claim 1,
When the first fan (21) and the second fan (22) are started simultaneously, the starting current of the first fan (21) becomes larger than the starting current of the second fan (22). (41) The fan drive device characterized by starting a 1st fan (21) before a 2nd fan (22). In claim 1,
The drive motors (23, 24) of the first fan (21) and the second fan (22) are connected to the drive motors (23, 24) so that the starting currents of the drive motors (23, 24) do not exceed a specified current value. , 24) are respectively provided with protection circuits (33, 34),
When the first fan (21) and the second fan (22) are started at the same time, the starting current margin with respect to the specified current value of the first fan (21) is the starting current with respect to the specified current value of the second fan (22). The fan driving device (41), wherein the fan control means (41) starts the first fan (21) before the second fan (22) when the margin is less than the margin of the second fan (22). In any one of Claims 1 thru | or 6,
The fan control device (41) is characterized in that the second fan (22) is activated after a predetermined set time has elapsed since the activation of the first fan (21). In any one of Claims 1 thru | or 6,
The fan control device (41) determines the start timing of the second fan (22) based on the rotational speed of the first fan (21). In any one of Claims 1 thru | or 6,
The fan control means (41) determines the start timing of the second fan (22) based on the start current of the first fan (21). In claim 1,
The drive motor of the first fan (21) is composed of an inverter type drive motor (23) connected to a power source (30) via an inverter circuit (31),
The drive motor of the second fan (22) is composed of a direct drive motor (24) connected directly to the power source (30),
The fan control means (41) starts the second fan (22) before the first fan (21) when the first fan (21) is rotating forward before starting. Fan drive device. In claim 2 or 10,
The drive motor for the first fan (21) comprises a brushless DC motor (23).   The casing (11), a plurality of fans (21, 22) provided in one air passage (S) provided in the casing (11), and the drive motors (23) of the plurality of fans (21, 22) 24) The air conditioner comprising the fan drive device (40) according to any one of claims 1 to 11, which controls the air conditioner. In claim 12,
It is equipped with an outdoor unit (10) that is placed outdoors,
The air conditioner, wherein the plurality of fans (21, 22) are provided in an air passage (S) in a casing (11) of the outdoor unit (10). In claim 12,
An indoor unit arranged indoors,
The air conditioner, wherein the plurality of fans (21, 22) are provided in an air passage (S) in a casing (11) of the indoor unit.

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