KR20240008685A - Coolant control module and pump control method therefor - Google Patents

Abstract

The present invention relates to a coolant control module and a pump control method for the same, comprising: n pumps for transporting coolant; a main controller that transmits a command for the number of revolutions per minute for each of the n pumps; And a sub-controller that transmits the command received from the main controller to the n pumps, determines the possibility of resonance, and adjusts the number of revolutions per minute to prevent resonance if there is a possibility of resonance. Deterioration of noise and vibration caused by resonance when the pump is driven can be prevented.

Description

Coolant control module and pump control method for the same {COOLANT CONTROL MODULE AND PUMP CONTROL METHOD THEREFOR}

The present invention relates to a coolant control module and a pump control method for the same, and more specifically, to a coolant control module and pump control for the same to prevent noise and vibration worsening due to resonance when a plurality of pumps are driven. It's about method.

Generally, a vehicle is equipped with a coolant control module that cools the battery and electrical components using coolant cooled through a heat exchanger, and the coolant control module includes a reservoir tank that stores coolant, and a heat exchanger that exchanges heat with the coolant with the outside air or refrigerant. , a plurality of pumps that flow coolant along a flow path flowing through the reservoir tank and the heat exchanger, and a controller that controls the plurality of pumps.

Here, the controller includes a main controller and a sub-controller, and when the main controller transmits a command for the number of revolutions per minute of each of the plurality of pumps to the sub-controller, the sub-controller receives the command from the main controller. By transmitting the signal to the plurality of pumps, each of the plurality of pumps is rotated at the number of revolutions per minute commanded from the main controller through the sub-controller.

However, in the conventional coolant control module and pump control method for the same, when a plurality of pumps are driven and at least some of the pumps rotate at the same level of revolutions per minute, resonance is generated and noise and There was a problem with vibration worsening.

Republic of Korea Patent Publication No. 10-2022-0043563

Accordingly, the purpose of the present invention is to provide a coolant control module that can prevent noise and vibration worsening due to resonance when a plurality of pumps are driven, and a pump control method therefor.

The present invention, in order to achieve the above-described object, includes n pumps for transporting coolant; a main controller that transmits a command for the number of revolutions per minute for each of the n pumps; And a sub-controller that transmits the command received from the main controller to the n pumps, determines the possibility of resonance, and adjusts the number of revolutions per minute to prevent resonance if there is a possibility of resonance. to provide.

A random pump among the n pumps is called pump_a, another random pump among the n pumps is called pump_b, and the number of revolutions per minute of the pump_a of the command received by the sub-controller is RPM_a. Let the number of revolutions per minute of pump_a in the command transmitted by the sub-controller be RPM_a', and let the number of revolutions per minute of pump_b in the command received by the sub-controller be RPM_b, and let the number of revolutions per minute of pump_a in the command received by the sub-controller be RPM_b. If the revolutions per minute of the pump_b in the command is RPM_b', and the revolutions per minute separation range (RPM difference band) that prevents resonance from occurring is RPM_DB, the sub-controller determines the difference between the RPM_a and the RPM_b. If it is greater than or equal to the RPM_DB, the RPM_a may be set as RPM_a' and transmitted to the pump_a, and the RPM_b may be set as the RPM_b' and transmitted to the pump_b.

If the maximum executable number of revolutions per minute of the pump_a is Max RPM_a, the sub-controller determines that the difference between the RPM_a and the RPM_b is less than the RPM_DB, the RPM_a is greater than or equal to the RPM_b, and the Max RPM_a is equal to the RPM_b. If it is greater than or equal to the sum of the RPM_DB, the RPM_b can be set as the RPM_b' and transmitted to the pump_b, and the combined value of the RPM_b and the RPM_DB can be set as the RPM_a' and transmitted to the pump_a. .

If the difference between RPM_a and RPM_b is less than RPM_DB, RPM_a is greater than or equal to RPM_b, and Max RPM_a is less than the sum of RPM_b and RPM_DB, the Max RPM_a is converted to RPM_a'. It can be configured to transmit to the pump_a, and to transmit to the pump_b the value obtained by subtracting the RPM_DB from the Max RPM_a as the RPM_b'.

If the maximum executable number of revolutions per minute of the pump_b is Max RPM_b, the sub-controller determines that the difference between the RPM_a and the RPM_b is smaller than the RPM_DB, the RPM_a is smaller than the RPM_b, and the Max RPM_b is smaller than the RPM_a and the RPM_DB. If it is greater than or equal to the sum of the values, the RPM_a may be set as RPM_a' and transmitted to the pump_a, and the sum of the RPM_a and the RPM_DB may be set as the RPM_b' and transmitted to the pump_b.

If the difference between the RPM_a and the RPM_b is less than the RPM_DB, the RPM_a is less than the RPM_b, and the Max RPM_b is less than the sum of the RPM_a and the RPM_DB, the sub-controller sets the Max RPM_b to the RPM_b'. It can be configured to transmit to pump_b and transmit to pump_a the value obtained by subtracting the RPM_DB from the Max RPM_b as the RPM_a'.

The sub-controller may be configured to report commands sent to the n pumps to the main controller.

In addition, the present invention includes a first command step in which the sub-controller receives a command for the number of revolutions per minute of each of the n pumps transmitted by the main controller; And a second command step in which the sub-controller transmits the command received from the main controller to the n pumps, determines the possibility of resonance, and adjusts the number of revolutions per minute to prevent resonance if there is a possibility of resonance. Provides a pump control method including:

A random pump among the n pumps is called pump_a, another random pump among the n pumps is called pump_b, and the number of revolutions per minute of the pump_a of the command received by the sub-controller is RPM_a. Let the number of revolutions per minute of pump_a in the command transmitted by the sub-controller be RPM_a', and let the number of revolutions per minute of pump_b in the command received by the sub-controller be RPM_b, and let the number of revolutions per minute of pump_a in the command received by the sub-controller be RPM_b. If the revolutions per minute of the pump_b of the command is RPM_b', and the revolutions per minute separation range (RPM difference band) that prevents resonance from occurring is RPM_DB, the second command step is performed between the RPM_a and the RPM_b. It may include a first decision step of comparing the car and the RPM_DB.

The second command step may further include a second decision step of comparing the RPM_a and the RPM_b, if it is determined in the first decision step that the difference between the RPM_a and the RPM_b is smaller than the RPM_DB.

If the maximum executable number of revolutions per minute of the pump_a is Max RPM_a, the second command step is: If the RPM_a is determined to be greater than or equal to the RPM_b in the second determination step, the Max RPM_a is set to the RPM_b and the A third decision step of comparing RPM_DB with the combined value may be further included.

In the second command step, if it is determined in the third decision step that the Max RPM_a is greater than or equal to the sum of the RPM_b and the RPM_DB, the RPM_b is determined to be the RPM_b', and the sum of the RPM_b and the RPM_DB is determined. In the first decision step of determining RPM_a' and the third decision step, if it is determined that the Max RPM_a is less than the sum of the RPM_b and the RPM_DB, the Max RPM_a is determined as the RPM_a', and the Max RPM_a It may further include a second decision step of determining the value obtained by subtracting the RPM_DB as the RPM_b'.

If the maximum executable number of revolutions per minute of the pump_b is Max RPM_b, the second command step is: If the RPM_a is determined to be less than the RPM_b in the second determination step, the Max RPM_b is set to the RPM_a and the RPM_DB. A fourth judgment step of comparing the combined value may be further included.

In the second command step, if it is determined in the fourth decision step that the Max RPM_b is greater than or equal to the sum of the RPM_a and the RPM_DB, the RPM_a is determined to be the RPM_a', and the sum of the RPM_a and the RPM_DB is determined. If it is determined that the Max RPM_b is less than the sum of the RPM_a and the RPM_DB in the third decision step and the fourth decision step of determining RPM_b', the Max RPM_b is determined to be the RPM_b', and the Max RPM_b It may further include a fourth decision step of determining the value obtained by subtracting the RPM_DB as the RPM_a'.

In the second command step, if the difference between the RPM_a and the RPM_b is determined to be greater than or equal to the RPM_DB in the first decision step, the fifth command step determines the RPM_a as the RPM_a' and determines the RPM_b as the RPM_b'. A decision step may be further included.

The coolant control module and pump control method for the same according to the present invention include n pumps for transporting coolant; a main controller that transmits a command for the number of revolutions per minute for each of the n pumps; And a sub-controller that transmits the command received from the main controller to the n pumps, determines the possibility of resonance, and adjusts the number of revolutions per minute to prevent resonance if there is a possibility of resonance. Deterioration of noise and vibration caused by resonance when the pump is driven can be prevented.

1 is a schematic diagram showing a pump and controller of a coolant control module according to an embodiment of the present invention;
FIG. 2 is a flowchart showing resonance avoidance control logic performed in the sub-controller of FIG. 1.

Hereinafter, the coolant control module and pump control method for the same according to the present invention will be described in detail with reference to the attached drawings.

FIG. 1 is a schematic diagram showing a pump and controller of a coolant control module according to an embodiment of the present invention, and FIG. 2 is a flowchart showing resonance avoidance control logic performed in the sub-controller of FIG. 1.

Referring to the attached FIG. 1, the coolant control module according to an embodiment of the present invention includes a reservoir tank (not shown) that stores coolant, a heat exchanger (not shown) that exchanges heat with the outside air or refrigerant, and a coolant. It includes n pumps (P_1 to P_n) that flow through the reservoir tank (not shown) and the heat exchanger (not shown) and a controller that controls the n pumps (P_1 to P_n), The controller may include a main controller that transmits a command for the number of revolutions per minute for each of the n pumps (P_1 to P_n) and a sub-controller (SC) that receives the command transmitted from the main controller.

There are n main controllers, and the n main controllers (MC_1 to MC_n) may be matched one-to-one to the n pumps (P_1 to P_n). That is, if any pump among the n pumps (P_1 to P_n) is called pump_a (P_a), and any other pump among the n pumps (P_1 to P_n) is called pump_b (P_b), Main controller_a (MC_a), one of the n main controllers (MC_1 to MC_n), transmits a command for the number of revolutions per minute of the pump_a (P_a), and one of the n main controllers (MC_1 to MC_n) The other main controller_b (MC_b) can transmit a command for the number of revolutions per minute of the pump_b (P_b).

The sub-controller (SC) is provided as one to collect commands transmitted by the n main controllers (MC_1 to MC_n), and one sub-controller (SC) is configured to avoid resonance in FIG. 2, which implements the pump control method of the present invention. It can be configured to operate according to control logic.

Specifically, the resonance avoidance control logic is such that the sub-controller (SC) receives a command for the number of revolutions per minute of each of the n pumps (P_1 to P_n) transmitted by the n main controllers (MC_1 to MC_n). It may include a first command step (S1).

In addition, the resonance avoidance control logic determines the possibility of resonance while the sub-controller (SC) transmits the command received from the n main controllers (MC_1 to MC_n) to the n pumps (P_1 to P_n). In this case, a second command step (S2) of transmitting after adjusting the number of revolutions per minute to prevent resonance may be further included.

Here, the number of rotations per minute of the pump_a (P_a) in the command that the sub-controller (SC) receives from the main controller_a (MC_a) is RPM_a, and the sub-controller (SC) is set to the pump_a ( Let the number of revolutions per minute of the pump_a (P_a) of the command transmitted to P_a) be RPM_a', and the number of revolutions per minute of the command that the sub-controller (SC) receives from the main controller_b (MC_b) of the pump_b (P_b) )'s number of revolutions per minute is RPM_b, and the number of revolutions per minute of the pump_b (P_b) in the command sent from the sub-controller (SC) to the pump_b (P_b) is called RPM_b', and resonance is not generated. If RPM_DB is the RPM difference band, the second command step (S2) may include a first decision step (S21) that compares the difference between RPM_a and RPM_b with the RPM_DB. there is.

And, in the second command step (S2), if it is determined in the first decision step (S21) that the difference between the RPM_a and the RPM_b is smaller than the RPM_DB, a second decision step (S211) of comparing the RPM_a and the RPM_b. It may further include.

And, in the second command step (S2), if the RPM_a is determined to be greater than or equal to the RPM_b in the second judgment step (S211), Max RPM_a is the maximum executable revolutions per minute of the pump_a (P_a). It may further include a third decision step (S2111) of comparing with the sum of the RPM_b and the RPM_DB.

And, in the second command step (S2), if it is determined in the third judgment step (S2111) that the Max RPM_a is greater than or equal to the sum of the RPM_b and the RPM_DB, the RPM_b is determined to be the RPM_b', It may further include a first decision step (S21111) in which the sum of the RPM_b and the RPM_DB is determined as the RPM_a'.

And, in the second command step (S2), if it is determined in the third judgment step (S2111) that the Max RPM_a is less than the sum of the RPM_b and the RPM_DB, the Max RPM_a is determined to be the RPM_a', and It may further include a second decision step (S21112) in which the RPM_b' is determined by subtracting the RPM_DB from Max RPM_a.

And, in the second command step (S2), if it is determined in the second judgment step (S211) that the RPM_a is smaller than the RPM_b, Max RPM_b, which is the maximum feasible rotation per minute of the pump_b (P_b), is set to It may further include a fourth decision step (S2112) of comparing RPM_a and the RPM_DB combined value.

And, in the second command step (S2), if the Max RPM_b is determined to be greater than or equal to the sum of the RPM_a and the RPM_DB in the fourth decision step (S2112), the RPM_a is determined to be the RPM_a', It may further include a third decision step (S21121) of determining the sum of the RPM_a and the RPM_DB as the RPM_b'.

And, in the second command step (S2), if it is determined in the fourth decision step (S2112) that the Max RPM_b is less than the sum of the RPM_a and the RPM_DB, the Max RPM_b is determined to be the RPM_b', and It may further include a fourth decision step (S21122) in which the RPM_a' is determined by subtracting the RPM_DB from Max RPM_b.

And, in the second command step (S2), if the difference between the RPM_a and the RPM_b is determined to be greater than or equal to the RPM_DB in the first decision step (S21), the RPM_a is determined to be the RPM_a', and the RPM_b is determined. It may further include a fifth decision step (S212) of determining the RPM_b'.

Hereinafter, the effects of the coolant control module and the pump control method for the same according to this embodiment will be described.

That is, the coolant control module and the pump control method for the same according to this embodiment have the sub-controller (SC) transmit commands received from the n main controllers (MC_1 to MC_n) to the n pumps (P_1 to P_n). Instead of simply transmitting, the commands received from the n main controllers (MC_1 to MC_n) are transmitted to the n pumps (P_1 to P_n), and the possibility of resonance is determined to prevent resonance from occurring if there is a possibility of resonance. By adjusting the number of revolutions per minute and then transmitting, noise and vibration worsening due to resonance can be prevented when the n pumps (P_1 to P_n) are driven.

Specifically, the sub-controller (SC) is configured to control the It can be operated at the number of revolutions per minute commanded by the main controller (MC_1 to MC_n).

That is, through the first decision step (S21) and the fifth decision step (S212), if the difference between the RPM_a and the RPM_b is greater than or equal to the RPM_DB, the sub-controller (SC) transfers the RPM_a to the RPM_a' It can be transmitted to the pump_a (P_a), and the RPM_b can be transmitted to the pump_b (P_b) as the RPM_b'.

In addition, the sub-controller (SC) has a possibility of resonance occurring between the revolutions per minute commanded by the n main controllers (MC_1 to MC_n), and the pump with a larger commanded revolutions per minute among the pumps likely to cause resonance. Even if the number is increased to the number of revolutions per minute commanded by another pump plus the range of revolutions per minute, if it is less than the maximum number of revolutions per minute, the other pump is operated at the number of revolutions per minute commanded by the main controller matching it, and The pump with a large commanded revolutions per minute is operated at an upwardly adjusted revolutions per minute by the sum of the revolutions per minute commanded by the other pump and the revolutions per minute separation range instead of the revolutions per minute commanded by the matching main controller. , resonance can be prevented by sufficiently spacing the revolutions per minute.

That is, the sub-controller (SC) goes through the first decision step (S21), the second decision step (S211), the third decision step (S2111), and the first decision step (S21111), and performs the RPM_a If the difference between and the RPM_b is less than the RPM_DB, the RPM_a is greater than or equal to the RPM_b, and the Max RPM_a is greater than or equal to the sum of the RPM_b and the RPM_DB, the RPM_b is set to the RPM_b' and the pump_b It can be transmitted to (P_b), and the sum of RPM_b and RPM_DB can be set as RPM_a' and transmitted to pump_a (P_a).

In addition, the sub-controller (SC), through the first decision step (S21), the second decision step (S211), the fourth decision step (S2112), and the third decision step (S21121), determines the RPM_a If the difference between RPM_b and the RPM_b is less than the RPM_DB, the RPM_a is less than the RPM_b, and the Max RPM_b is greater than or equal to the sum of the RPM_a and the RPM_DB, the RPM_a is set to the RPM_a' and the pump_a (P_a ), and the sum of the RPM_a and the RPM_DB can be set as the RPM_b' and transmitted to the pump_b (P_b).

In addition, the sub-controller (SC) has a possibility of resonance occurring between the revolutions per minute commanded by the n main controllers (MC_1 to MC_n), and the pump with a larger commanded revolutions per minute among the pumps likely to cause resonance. If the maximum revolutions per minute cannot be increased to the sum of the revolutions per minute commanded by other pumps and the revolutions per minute separation range due to restrictions on the maximum revolutions per minute, the pump with the larger commanded revolutions per minute is operated at the maximum revolutions per minute. , the other pump is operated at a rotation speed per minute lowered to a value obtained by subtracting the rotation speed per minute separation range from the maximum rotation speed per minute of the pump with the larger rotation speed per minute, so that the rotation speeds per minute are sufficiently spaced apart to prevent resonance. It can be prevented.

That is, the sub-controller (SC) goes through the first decision step (S21), the second decision step (S211), the third decision step (S2111), and the second decision step (S21112) to determine the RPM_a. If the difference between RPM_b and RPM_b is less than RPM_DB, RPM_a is greater than or equal to RPM_b, and Max RPM_a is less than the sum of RPM_b and RPM_DB, then Max RPM_a is set to RPM_a' and pump_a It can be transmitted to (P_a), and the value obtained by subtracting the RPM_DB from the Max RPM_a is set to RPM_b' and transmitted to the pump_b (P_b).

In addition, the sub-controller (SC), through the first decision step (S21), the second decision step (S211), the fourth decision step (S2112), and the fourth decision step (S21122), determines the RPM_a If the difference between RPM_b and the RPM_b is less than the RPM_DB, the RPM_a is less than the RPM_b, and the Max RPM_b is less than the sum of the RPM_a and the RPM_DB, the Max RPM_b is set to the RPM_b' and the pump_b (P_b ), and the value obtained by subtracting the RPM_DB from the Max RPM_b can be set as the RPM_a' and transmitted to the pump_a (P_a).

Meanwhile, although not separately shown, the resonance avoidance control logic reports the number of revolutions per minute of the command sent by the sub-controller (SC) to the n pumps (P_1 to P_n) to the n main controllers (MC_1 to MC_n). It can be formed to do so.

In addition, in the case of this embodiment, the main controller is formed in n pieces, but is not limited thereto. That is, if a command for the number of revolutions per minute of the n pumps (P_1 to P_n) can be transmitted, the number of main controllers can be appropriately adjusted.

Max RPM_a: Maximum number of revolutions per minute that pump_a can run.
Max RPM_b: Maximum feasible revolutions per minute of pump_b
MC_a: Main Controller_a
MC_b: Main Controller_b
P_a: pump_a
P_b: Pump_b
RPM_a: The number of revolutions per minute of pump_a of the command received by the sub-controller.
RPM_a': The number of revolutions per minute of pump_a in the command sent by the sub-controller.
RPM_b: The number of revolutions per minute of pump_b in the command received by the sub-controller.
RPM_b': The number of revolutions per minute of pump_b in the command sent by the sub-controller
RPM_DB: Revolutions per minute separation range
SC: Subcontroller
S1: First command phase
S2: Second command phase
S21: First judgment step
S211: Second judgment step
S212: Fifth decision step
S2111: Third judgment step
S2112: Fourth judgment step
S21111: First decision step
S21112: Second decision step
S21121: Third decision step
S21122: Fourth decision step

Claims (15)

n pumps for transporting coolant;
a main controller that transmits a command for the number of revolutions per minute for each of the n pumps; and
A sub-controller that transmits the command received from the main controller to the n pumps, determines the possibility of resonance, and adjusts the number of revolutions per minute to prevent resonance if there is a possibility of resonance, and then transmits the command. Coolant control module comprising a. According to paragraph 1,
Any pump among the n pumps is called pump_a,
Any other pump among the n pumps is called pump_b,
Let the number of revolutions per minute of the pump_a in the command received by the sub-controller be RPM_a,
Let the number of revolutions per minute of the pump_a in the command transmitted by the sub-controller be RPM_a',
Let the number of revolutions per minute of the pump_b in the command received by the sub-controller be RPM_b,
Let the number of revolutions per minute of the pump_b in the command transmitted from the sub-controller be RPM_b',
If the RPM difference band that prevents resonance from occurring is RPM_DB,
If the difference between the RPM_a and the RPM_b is greater than or equal to the RPM_DB, the sub-controller is configured to transmit the RPM_a as the RPM_a' to the pump_a and to transmit the RPM_b as the RPM_b' to the pump_b. Coolant control module. According to paragraph 2,
If the maximum number of revolutions per minute that pump_a can run is Max RPM_a,
If the difference between the RPM_a and the RPM_b is less than the RPM_DB, the RPM_a is greater than or equal to the RPM_b, and the Max RPM_a is greater than or equal to the sum of the RPM_b and the RPM_DB, the RPM_b is converted to RPM_b'. A coolant control module configured to transmit to the pump_b and transmit the sum of the RPM_b and the RPM_DB to the pump_a as the RPM_a'. According to paragraph 3,
If the difference between RPM_a and RPM_b is less than RPM_DB, RPM_a is greater than or equal to RPM_b, and Max RPM_a is less than the sum of RPM_b and RPM_DB, the Max RPM_a is converted to RPM_a'. A coolant control module configured to transmit to the pump_a and transmit the value obtained by subtracting the RPM_DB from the Max RPM_a as the RPM_b' to the pump_b. According to paragraph 2,
If the maximum number of revolutions per minute that pump_b can perform is Max RPM_b,
If the difference between the RPM_a and the RPM_b is less than the RPM_DB, the RPM_a is less than the RPM_b, and the Max RPM_b is greater than or equal to the sum of the RPM_a and the RPM_DB, the sub-controller sets the RPM_a to the RPM_a'. A coolant control module configured to transmit to pump_a and transmit the sum of RPM_a and RPM_DB to pump_b as RPM_b'. According to clause 5,
If the difference between the RPM_a and the RPM_b is less than the RPM_DB, the RPM_a is less than the RPM_b, and the Max RPM_b is less than the sum of the RPM_a and the RPM_DB, the sub-controller sets the Max RPM_b to the RPM_b'. A coolant control module configured to transmit to pump_b and transmit to pump_a the value obtained by subtracting the RPM_DB from the Max RPM_b as the RPM_a'. According to paragraph 1,
The sub-controller is configured to report commands sent to the n pumps to the main controller. A first command step in which the sub-controller receives a command for the number of revolutions per minute for each of the n pumps transmitted by the main controller; and
A second command step in which the sub-controller transmits the command received from the main controller to the n pumps, determines the possibility of resonance, and adjusts the number of revolutions per minute to prevent resonance if there is a possibility of resonance. Pump control method. According to clause 8,
Any pump among the n pumps is called pump_a,
Any other pump among the n pumps is called pump_b,
Let the number of revolutions per minute of the pump_a in the command received by the sub-controller be RPM_a,
Let the number of revolutions per minute of the pump_a in the command transmitted by the sub-controller be RPM_a',
Let the number of revolutions per minute of the pump_b in the command received by the sub-controller be RPM_b,
Let the number of revolutions per minute of the pump_b in the command transmitted from the sub-controller be RPM_b',
If the RPM difference band that prevents resonance from occurring is RPM_DB,
The second command step includes a first decision step of comparing the difference between the RPM_a and the RPM_b and the RPM_DB. According to clause 9,
The second command step further includes a second decision step of comparing the RPM_a and the RPM_b when it is determined in the first decision step that the difference between the RPM_a and the RPM_b is less than the RPM_DB. According to clause 10,
If the maximum number of revolutions per minute that pump_a can run is Max RPM_a,
The second command step further includes a third decision step of comparing the Max RPM_a with the sum of the RPM_b and the RPM_DB when it is determined in the second decision step that the RPM_a is greater than or equal to the RPM_b. method. According to clause 11,
The second command step is,
In the third determination step, if it is determined that the Max RPM_a is greater than or equal to the sum of the RPM_b and the RPM_DB, the RPM_b is determined as the RPM_b', and the sum of the RPM_b and the RPM_DB is determined as the RPM_a'. first decision step and
If it is determined in the third determination step that the Max RPM_a is less than the sum of the RPM_b and the RPM_DB, the Max RPM_a is determined as the RPM_a', and the value obtained by subtracting the RPM_DB from the Max RPM_a is determined as the RPM_b'. A pump control method further comprising a second determining step. According to clause 10,
If the maximum number of revolutions per minute that pump_b can perform is Max RPM_b,
The second command step further includes a fourth decision step of comparing the Max RPM_b with the sum of the RPM_a and the RPM_DB when it is determined that the RPM_a is less than the RPM_b in the second decision step. According to clause 13,
The second command step is,
In the fourth determination step, if it is determined that the Max RPM_b is greater than or equal to the sum of the RPM_a and the RPM_DB, the RPM_a is determined as the RPM_a', and the sum of the RPM_a and the RPM_DB is determined as the RPM_b'. third decision step and
If it is determined in the fourth determination step that the Max RPM_b is less than the sum of the RPM_a and the RPM_DB, the Max RPM_b is determined as the RPM_b', and the value obtained by subtracting the RPM_DB from the Max RPM_b is determined as the RPM_a'. A pump control method further comprising a fourth decision step. According to clause 9,
In the second command step, if the difference between the RPM_a and the RPM_b is determined to be greater than or equal to the RPM_DB in the first decision step, the fifth command step determines the RPM_a as the RPM_a' and determines the RPM_b as the RPM_b'. A pump control method further comprising a determining step.

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