JP2006214601A - Air volume controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To rotate a blower by setting to the number of revolutions for outputting target air volume according to flow resistance of a duct. <P>SOLUTION: A wind volume control module 35 is provided with a means for responding to a desired air volume signal 85 and a speed signal 80 sent from a system controller 40 and supplying a control signal 75 to match the speed signal 80 with the desired air volume signal 85, a means for rotating a motor 25 at predetermined rotational speed A, a means for giving an initial motor torque signal 65A displaying output torque of the motor 25 when the motor 25 rotates at the predetermined rotational speed A, and a means for feeding the control signal 75 corresponding to an expression for expressing relation of air volume and the rotational speed corresponding to the initial motor torque signal 65A, the desired air volume signal 85, and the rotational speed calculated by the expression. The blower 20 is operated at the rotational speed corresponding to desired air volume matching with situation of the duct after obtaining the situation of the duct in advance to adjust air volume to the desired air volume corresponding to the situation of the connected duct and perform stable operation. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an air volume control device that ensures an air flow rate required in a refrigeration cycle corresponding to a state of a duct connected by a blower of an air conditioner connected to a duct.

  Conventionally, this type of air flow control device performs a so-called feedback process in which the amount of air flow is estimated from the number of revolutions and the signal given to the motor, and the control signal to the motor is corrected by comparing with the desired air flow rate. (For example, refer to Patent Document 1).

FIG. 3 is a flowchart of the conventional air volume control device described in Patent Document 1. As shown in FIG. 3, step 135 for recognizing the desired air volume, step 140 for estimating the air flow using the PWM signal 160 and the rotational speed currently sent to the motor, and a step for comparing the desired air volume with the estimation result. 145, 150, steps 155, 165 for changing the PWM value based on the comparison result, and step 160 for sending the changed PWM value, and the process returns to step 135 to repeat the above steps.
JP 7-301450 A

  However, in the above-described conventional configuration, the air flow does not flow and there is always pulsation, and the desired air volume and the estimated air volume can hardly coincide with each other. Therefore, the PWM value is changed and the rotational speed fluctuates. However, there was a problem of amplifying the pulsation depending on the situation without being operated stably.

  The present invention solves the above-described conventional problems, and provides an air volume control device that performs a stable rotation operation while ensuring a desired air volume corresponding to the state of a duct from an operation frequency of a variable capacity compressor. Objective.

  In order to solve the conventional problems, an air volume control device according to the present invention includes, in a control device, means for determining an operating frequency of a variable capacity compressor, means for rotating a motor at a predetermined speed, and motor at a predetermined speed. Timing determination means for determining when to rotate, means for providing an initial motor torque signal indicating the motor torque when the motor is rotating at a predetermined rotation speed, and the relationship between the air volume and the rotation speed corresponding to the motor torque signal And a means for determining the desired air volume, and a means for rotating the motor at the rotational speed calculated by the desired air volume and the equation.

  As a result, the condition of the duct is grasped by measuring the motor torque by rotating the motor at a predetermined rotation speed from the operating frequency of the variable capacity compressor, and the relational expression between the air volume and the rotation speed previously created from the characteristics of the blower From this, a relational expression suitable for the duct state is selected, and the number of revolutions to obtain the desired air volume is calculated by the selected relational expression, and the motor is controlled to rotate at the calculated number of revolutions.

  In the air volume control device of the present invention, the timing determining means for determining when to rotate the motor at a predetermined rotational speed is set when the variable capacity compressor starts operation at a predetermined frequency.

  As a result, when the air conditioner is installed, it is not necessary to separately grasp the state of the duct and is automatically grasped when the operation is started.

  In the air volume control device of the present invention, the timing determining means for determining when to rotate the motor at a predetermined rotational speed is such that the motor is rotated at the predetermined rotational speed when the operating frequency of the variable capacity compressor changes. It is.

  As a result, when the indoor temperature is equal to or lower than the set temperature of the air conditioner, the operating frequency of the variable capacity compressor is lowered by reducing the load, or when the indoor temperature is increased, the load is increased. By increasing the operating frequency of the variable capacity compressor, the situation can be grasped even when the operating frequency of the variable capacity compressor changes.

  Further, the air volume control device of the present invention has a timing determining means for determining when to rotate the motor at a predetermined rotational speed, and rotates the motor at a predetermined rotational speed every predetermined time when the operating frequency of the variable capacity compressor does not change for a predetermined time. It is time.

Thus, even when the air conditioner is stably operated, the situation can be grasped.
Further, in the air volume control device of the present invention, the timing determining means for determining when to rotate the motor at a predetermined number of rotations is such that the state of the flow path of the processing air is changed by opening / closing of the damper, etc. This is when the motor is rotated at a predetermined rotational speed when the operating frequency changes.

  Accordingly, even when the connecting duct is branched and a damper is attached thereto, the situation can be grasped.

  The air volume control device of the present invention can adjust the air volume to a desired air volume according to a change in the operating frequency of the variable capacity compressor or the state of a connected duct, and can perform stable operation.

  1st invention is equipped with the air blower, the motor which drives the fan of an air blower, the means which determines the operating frequency of a variable capacity compressor, and the control apparatus which controls rotation of a motor, and a control apparatus is predetermined rotation speed. Means for rotating the motor, timing determining means for determining when to rotate the motor at a predetermined number of revolutions, means for providing an initial motor torque signal representing the torque of the motor when the motor is rotating at the prescribed number of revolutions, By having a calculation formula expressing the relationship between the air volume and the rotation speed corresponding to the motor torque signal, a means for determining the desired air volume, and a means for rotating the motor at the desired air volume and the rotation speed calculated by the calculation formula, Measure the motor torque by rotating the motor at a predetermined number of revolutions to grasp the state of the duct, and change the duct state from the relational expression between the air volume and the number of revolutions created in advance from the characteristics of the blower Select the appropriate relational expression, calculate the number of revolutions that will produce the desired air flow based on the selected relational expression, and control the motor to rotate at the calculated number of revolutions, depending on the status of the connected ducts. By adjusting the air volume to the desired air volume, stable operation can be performed.

  In the second aspect of the invention, the timing determining means of the first aspect of the invention is particularly set when the variable capacity compressor starts operation at a predetermined frequency, whereby the status of the duct is separately grasped when the air conditioner is installed. There is no need to do so, and it can be automatically grasped when driving is started.

  In the third aspect of the invention, the timing determining means of the first aspect of the invention is such that the motor is rotated at a predetermined rotational speed when the operating frequency of the variable capacity compressor changes. Thereby, when the room temperature is equal to or lower than the set temperature of the air conditioner, the operating frequency of the variable capacity compressor is lowered by reducing the load. In addition, when the indoor temperature rises, the operating frequency of the variable capacity compressor increases as the load increases, so that the situation can be grasped even when the operating frequency of the variable capacity compressor changes. .

  In the fourth aspect of the invention, the timing determining means of the first aspect of the invention is set at regular intervals when the operation frequency of the variable capacity compressor does not vary for a certain period of time, and dust is thereby collected on the air filter of the air conditioner. The situation can be grasped even when resistance increases in the flow of the accumulated wind.

  In the fifth aspect of the invention, the timing determining means of the first aspect of the invention is particularly set when the operating frequency of the variable capacity compressor is changed by changing the state of the flow path of the processing air by opening / closing the damper or the like. Yes, this makes it possible to grasp the situation even when the connecting duct is branched and a damper is attached thereto.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a block diagram of an air treatment system including an air volume control device according to a first embodiment of the present invention.

  In FIG. 1, the main elements of the air processing system include a duct system 15, a blower 20, a motor 25, a variable speed motor control device 30, an air volume control module 35, and a system control device 40.

  Duct system 15 is a conduit used to distribute air to a predetermined area to be regulated. The duct system 15 is provided in a building, for example, and supplies conditioned air to a desired room. The static air pressure in the system depends on the shape and length of the duct, the damper 45, the filter 50 and the heat exchanger 55 housed in the duct system 15.

  The blower 20 is a blower device that allows air to flow through the duct system 15, and a sirocco fan is used in this embodiment. The motor 25 is for supplying mechanical force necessary to drive the blower 20, and a DC motor is used in this embodiment. The motor 25 is connected to the blower 20 by a shaft 70.

  The variable speed motor control device 30 is constituted by means for controlling the motor speed in response to a control signal 75 generated by the air volume control module 35 and means for supplying a speed signal 80 indicating the motor speed. ing.

  The air volume control module 35 includes a means 95 for outputting a rotational speed signal Fr for rotating the motor 25 at a predetermined rotational speed A, a timing determining means 100 for determining when to rotate the motor at the predetermined rotational speed A, and a predetermined rotational speed A. Means 105 for providing an initial motor torque signal Tra representing the output torque of the motor 25 when the motor 25 is rotating, a calculation formula a representing the relationship between the air volume and the rotational speed corresponding to the initial motor torque signal Tra, and the system Desired air volume signal 85 sent from control device 40, initial motor torque signal Tra, means 110 for outputting rotation speed signal Fr corresponding to the rotation speed calculated by equation a, and desired air volume sent from system control device 40 In response to the speed signal Fr calculated from the signal 85 and the speed signal 80, a control signal 75 is supplied so that the speed signal 80 matches the speed signal Fr. And means 90 that.

  The system control device 40 changes the operating capacity of the variable capacity compressor 115 in accordance with the required air conditioning capacity, and supplies an air volume corresponding to the compressor operating capacity as the desired air volume signal 85.

  The operation and action of the air volume control device configured as described above will be described below.

  In general, in a blower circuit including a fan, the air volume is proportional to the rotational speed when the state of the blower circuit is determined. The inclination of the relationship changes depending on the situation of the blower circuit. If the state of the blower circuit is grasped in some way, the relationship between the air volume and the rotational speed can be determined. Therefore, the state of the blower circuit is to be grasped by a motor torque signal when it is rotated at a predetermined rotation speed.

  FIG. 2 shows a motor torque signal when rotating at a predetermined rotational speed when the blower circuit is changed, and the air volume and rotational speed for each of the blower circuits.

  The operation and action will be described. First, when an instruction is sent by the timing determining means due to a change in the operating frequency of the variable capacity compressor 115, the blower 20 is rotated by rotating the motor 25 at a predetermined rotational speed A. When the rotation is stabilized, the initial motor torque signal 65A is measured. At this time, the initial motor torque signal 65A reflects the state of the duct determined by the static air pressure in the system, the shape and length of the duct, the filter 50, and the heat exchanger 55 housed in the duct system 15. It has become.

  When the condition of the duct is determined, the air volume and the rotational speed are in a proportional relationship, and in our measured example, it is as shown in FIG. The relationship of FIG. 2 is expressed as shown in Equation 1 when the rotational speed is expressed using the initial motor torque signal 65A and the air volume when the predetermined rotational speed is 600 r / m.

  The measured initial motor torque signal 65A is stored, and the operation speed at the desired air volume is calculated from the desired air volume signal 85 sent from the system controller 40 using the equation 1, and the control corresponding to the rotation speed is performed. By sending a signal 75, the desired air volume can be passed through the duct.

  As described above, in the present embodiment, the means 95 for outputting the rotational speed signal Fr for rotating the motor 25 at the predetermined rotational speed A to the air volume control module 35 and the time for rotating the motor at the predetermined rotational speed A are determined. Timing determining means 100, means 105 for providing an initial motor torque signal Tra representing the output torque of the motor 25 when the motor 25 is rotating at a predetermined rotational speed A, and an air volume and a rotational speed corresponding to the initial motor torque signal Tra , A desired rotational speed signal Fr corresponding to the rotational speed calculated by the numerical formula 1 and the desired air volume signal 85 and the initial motor torque signal Tra sent from the system controller 40. In response to the rotational speed signal Fr and the speed signal 80 calculated from the means 110 and the desired air volume signal 85 sent from the system controller 40, the rotational speed signal Fr By providing the means 90 for supplying the control signal 75 so as to match the degree signal 80, the condition of the duct is grasped in advance, and then the blower 20 is operated at the rotational speed corresponding to the desired air volume suitable for the condition. The air volume can be adjusted to the desired air volume according to the state of the connected duct, and stable operation can be performed.

  In the present embodiment, the variable speed motor control device 30, the air volume control module 35, and the system control 40 are divided, but the same effect can be obtained even if they are changed or integrated.

(Embodiment 2)
In the second embodiment of the present invention, in the timing determining means when the variable capacity compressor starts operation at a predetermined frequency, an instruction to rotate at a predetermined rotational speed is issued when the operation switch is turned on. The initial motor torque signal 65A is measured in advance before the compressor is operated so as to grasp the status of the duct, so that it is necessary to separately grasp the status of the duct when the air conditioner is installed. It can be automatically grasped when driving is started.

(Embodiment 3)
According to the third embodiment of the present invention, in the timing determination means based on the change of the operation frequency of the variable capacity compressor, when the room temperature is equal to or lower than the set temperature of the air conditioner, the load is reduced to reduce the capacity. The operating frequency of the variable compressor is lowered. Alternatively, when the room temperature rises, the operating frequency of the variable capacity compressor increases as the load increases. Thus, even when the operating frequency of the variable capacity compressor is changed, the situation can be grasped.

(Embodiment 4)
In the fourth embodiment of the present invention, when the operating frequency of the variable capacity compressor does not change for a certain period of time, the timing determination means at a certain time interval periodically grasps the duct status, for example, at a predetermined number of revolutions at 12:00 every day. The initial motor torque signal 65A is measured and stored until 12 o'clock the next day, which causes dust to accumulate in the air filter of the air conditioner and increase resistance to wind flow. It is possible to grasp in response to changes in the situation.

(Embodiment 5)
In the fifth embodiment of the present invention, a damper 45 is provided downstream of the duct 15 in the timing determining means when the operation frequency of the variable capacity compressor is changed by changing the state of the processing flow path. In this case, when the damper 45 is moved to change the state of the processing air flow path, that is, when the state of the processing air flow path changes, an instruction to turn at a predetermined number of revolutions is issued, and the initial motor torque signal 65A is measured and updated. Accordingly, even when the connecting duct is branched and the damper 45 is attached thereto, it is possible to grasp the changed situation.

  As described above, the air volume control device according to the present invention can ensure the target air volume according to the state of the duct, and can be applied to applications such as a duct type air conditioner.

The block diagram of the air volume control apparatus in Embodiment 1 of this invention The characteristic view showing the relationship between the air volume and the rotation speed in the first embodiment of the present invention The figure which shows the control flow of the conventional air volume control apparatus

Explanation of symbols

65 Motor torque signal 70 Axis 75 Control signal 80 Speed signal 85 Desired air volume signal 90 Means for supplying control signal 75 95 Means for rotating motor 25 at predetermined rotational speed A 100 Timing determining means 105 Means for providing initial motor torque signal Tra 110 Rotational speed calculation means

Claims (5)

A blower, a motor that drives a fan of the blower, and a control device that controls the rotation of the motor are provided, and the control device rotates the motor at a predetermined number of revolutions and means for determining an operating frequency of the compressor. Means for determining when to rotate the motor at the predetermined number of revolutions, means for providing an initial motor torque signal representing the torque of the motor when the motor is rotating at the predetermined number of revolutions, A calculation formula expressing the relationship between the air volume and the rotation speed corresponding to the initial motor torque signal, a means for determining the desired air volume, and a means for rotating the motor at the rotation speed calculated by the desired air volume and the calculation formula. Air volume control device. 2. The air volume control device according to claim 1, wherein the timing determining means for determining when to rotate the motor at a predetermined rotational speed determines to rotate the motor at the predetermined rotational speed when the compressor starts operation at a predetermined frequency. 2. The air volume control device according to claim 1, wherein the timing determining means for determining when to rotate the motor at a predetermined rotational speed determines to rotate the motor at the predetermined rotational speed when the operating frequency of the compressor changes. 2. The air volume according to claim 1, wherein the timing determining means for determining when to rotate the motor at a predetermined rotational speed determines to rotate the motor at a predetermined rotational speed every predetermined time when the operating frequency of the compressor does not change for a predetermined time. Control device. The timing determining means for determining when to rotate the motor at a predetermined rotational speed is such that the motor is operated at the predetermined rotational speed when the operating frequency of the compressor changes by changing the state of the flow path of the processing air by opening or closing the damper. The air volume control device according to claim 1, wherein the air flow control device is determined to rotate.

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