JP3262011B2 - Operating method of screw compressor and screw compressor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a screw compressor operating method and a screw compressor for adjusting the capacity of a compressor by changing the rotation speed of a drive motor using an inverter.

[0002]

2. Description of the Related Art In a conventional screw compressor, as described in Japanese Patent Application Laid-Open No. 7-35079, the compressor has a suction throttle valve at its suction port. It was opened and closed by a solenoid valve that opened and closed according to several signals.

[0003]

In the above prior art, since the suction throttle valve is closed to control the capacity at a low load, the following points have not been sufficiently considered. At low load, the suction throttle valve is fully closed with the compressor speed reduced: Insufficient power reduction. 2. Since the suction pressure is reduced while the discharge pressure of the compressor remains at the specified pressure, the amount of refueling increases as compared with the case of full load. An increase in the amount of lubrication during low-speed rotation causes an increase in driving power and required driving torque, and an inverter driving machine in which the driving torque decreases in the low-speed rotation range may cause a trip of the inverter. 3. Since the work amount of the compressor is reduced in a state where the discharge pressure of the compressor is equal to or higher than the specified pressure, the capacity of the oil cooler is relatively increased, and the temperature of oil supply to the compressor is decreased. Accordingly, the discharge temperature of the compressor decreases, and the possibility of drainage in the oil separator increases.

In order to improve the power at low load, (a) a state in which the suction throttle valve is fully closed to release the pressure in the oil separator, and (b) a state in which the suction throttle valve is fully opened. A method of repeating the two states (a) and (b) has also been proposed. However, in this method,
A pressure margin for shifting to the states (a) and (b) is required, which may cause the pressure to drop below the set pressure. Further, even when the control pressure is secured, the operation frequency of the suction throttle valve and the solenoid valve increases, so that the durability of these valves may be reduced.

An object of the present invention is to reduce the power of the compressor while maintaining and improving the reliability of the compressor, and to reduce the generation of drain in the oil separator.

[0006]

In order to achieve the above object, an electric motor having a pair of male and female rotors rotatably supported by bearings for driving the rotors and an inverter for controlling the electric motors are provided. In a screw compressor provided with a suction throttle valve for adjusting the flow rate on the suction side, a rotation speed control operation for controlling the capacity of the screw compressor by changing the rotation speed of the electric motor by an inverter , and this rotation speed control
The screw pressure is set so that the screw compressor is driven at the minimum rotation speed during operation , the suction throttle valve is closed, and the no-load operation is performed to reduce the discharge pressure of the screw compressor.
Control means for controlling the compressor, the discharge pressure when the compressor is switched to the no-load operation is P1 , and the discharge pressure when the compressor is switched to the load operation, which is the operation for opening the suction throttle valve at the minimum rotation speed, is P2, when the set discharge pressure during the rotation speed control operation is represented by P0, the control means controls the rotation speed when the discharge pressure reaches the discharge pressure defined by P1> P0 or P2 = <P0 at the time of operation switching. When switching to operation or no-load operation and automatically stopping the compressor due to a decrease in load, the compressor is forcibly operated under load until the pressure becomes higher than the set discharge pressure P0, and the pressure is increased. Is to stop. Preferably, when restarting the compressor, the control means controls the compressor to restart when the discharge pressure becomes equal to or higher than the set discharge pressure P0.

[0007]

[0008]

[0009]

[0010]

In the present invention having the above-described configuration, for example, the electric motor is controlled using an inverter in the range of 100% to 30% of the rated discharge air amount of the compressor, and the displacement is changed by changing the rotation speed of the compressor. Control. 30% air usage
When the pressure falls below, the rotation speed of the compressor is fixed to the rotation speed at the time of a 30% load (lower limit rotation speed), the suction throttle valve is closed, and the discharge pressure of the compressor is reduced at the same time. At the same time as the air flow into the compressor is cut off, the pressure on the discharge side of the compressor is reduced, so that the power consumption is significantly reduced. 3
In the load region of 0% or less, the capacity is adjusted by repeatedly performing the no-load operation and the load operation at the lower limit rotation speed.

Further, for example, when the no-load operation is continued for 10 minutes, the compressor is automatically stopped. Alternatively, for example, the compressor is automatically stopped in a load region of 10% or less.
Further, when the load decreases, for example, when the amount of air used falls to 30% or less, the rotation speed of the compressor is maintained at a set value (lower limit number of rotations). Continue operation at frequency. Then, the suction throttle valve is closed to reduce the discharge pressure of the compressor. If the compressor enters the capacity control region of the no-load operation and the set pressure in the rotation speed control region is P _0, and the discharge pressure of the compressor reaches the pressure P ₁ where P ₁ > P ₀ , the suction throttle valve , And the discharge pressure of the compressor is reduced to start a no-load operation. The above method is also performed when the compressor has an automatic stop function.

Further, the pressure P ₂ (lower limit pressure) for returning from the no-load operation to the load operation is set to a pressure equal to or higher than the set pressure P ₀ . When air usage from 100% of the rated air delivery of the compressor 30% controls the rotational speed, operating as a constant pressure near the set pressure P _0. On the other hand, when the air usage is 30% or less, P ₁ > P ₂ > =
Between P ₀ become P ₁ and pressure P _2, repeated load operation at no-load operation and the lower limit rotation speed depending on the air amount.

When the condition for automatically stopping the compressor is established by further reducing the amount of air used, a period of load operation at the lower limit rotational speed is provided, and P ₃ is set for the aforementioned set pressure P _0.
> Pressure to P ₃ to be P ₀ stops the compressor from rising. P at which the consumption of air starts and the pressure becomes P ₄ > = P _0
When it drops to _4, restart the compressor.

The above P ₁ ,
The pressures such as P ₂ , P ₃ , and P ₄ may be detected, and each set pressure may be stored in a storage device. Each set pressure P _{1 to} P ₄
May be automatically calculated by the arithmetic unit when the pressure P ₀ is set, and may be set. Further, an input means for manually changing the set value may be provided. Thereby, each set pressure can be appropriately set, and the set value can be easily changed.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The embodiments of the present invention will be described below with reference to the drawings with reference to some embodiments. FIG.
FIG. 1 shows a schematic diagram of a screw compressor device according to an embodiment of the present invention. The air sucked from the suction filter 1 passes through the suction throttle valve 2, is compressed between the rotors 3 of the screw compressor, and is discharged from the discharge port 4. Lubricating oil is injected into the rotor 3 of the screw compressor 12 for cooling the compression heat generated by the compression and for lubrication and sealing. The compressed air discharged together with the lubricating oil from the discharge port 4 flows into the oil separator tank 5, is separated from the lubricating oil by the oil separator element 6, and sequentially passes from the discharge pipe 7 through the check valve 8 and the pressure regulating valve 9. , Aftercooler 10
After being cooled in the aftercooler 10, it is discharged to an external device (not shown).

On the other hand, the lubricating oil is
The oil is separated from the compressed air in the inside and guided to the oil cooler 11 from the bottom of the oil separator tank 5. The lubricating oil cooled by the oil cooler 11 and the uncooled lubricating oil that does not pass through the oil cooler are mixed in the temperature control valve 13 to lubricate the screw compressor 12. The oil cooler 11 and the after cooler 10 are cooled by the cooling air of the cooling fan 14.

The rotor 3 of the screw compressor and the electric motor 1
The six shafts are connected by a belt 15 for rotation. Electric motor 1
6 can be operated at a variable speed by an inverter 17. A pressure sensor 18 is provided downstream of the check valve 8 and detects a pressure discharged from the screw compressor 12. The output signal of the pressure sensor 18 is input to the input / output unit 19. The control unit 20a includes a storage unit and P
It has an ID function. Then, the stored set pressure is compared with the pressure detected by the pressure sensor 18, and a frequency such that the detected pressure becomes the target pressure P ₀ is given to the inverter 17 to change the rotation speed of the electric motor 16. Pressure setting of various stored in the storage means and the control device part 20a is automatically set to a proper value by simply setting the target pressure P _0. Further, the setting value can be changed by using the setting input unit and the display unit 20b connected to the control device unit 20a. Further, display means (LED, liquid crystal element, etc.) is provided in the setting input means and the display unit 20b, and displays the set value of the pressure and the operation frequency.

The piston plate 2a of the suction throttle valve 2 provided on the upstream side of the screw compressor 12
When receiving pressure from one side, it operates in the closing direction. That is, when the solenoid valve 21 is opened, the high pressure in the oil separator 5 is guided to the suction throttle valve 2, and pressure is applied to the piston 2b. Further, a part of the air in the oil separator 5 is discharged to the suction side of the suction throttle valve 2 via the discharge pipe 22 at the same time when the solenoid valve 21 is opened. At this time, the flow rate is adjusted by the orifice 23. Instead of the pipe 22, a configuration in which air is directly discharged to the atmosphere may be used. In addition,
The solenoid valve 21 compares the set pressure automatically or manually set in the storage unit and the control unit 20a with the pressure signal from the input / output unit 19 input to the storage unit and the control unit 20a. It is opened and closed based on.

The operation of the screw compressor configured as described above will be described below. If the oil-cooled screw compressor is driven by an electric motor using an inverter, the rotation speed of the compressor 12 can be reduced with a decrease in the amount of used air. A reduction effect is obtained. Although this is well known in the art, the following disadvantages are brought about when the rotation speed is controlled in the entire region of the discharge air amount.

That is, at a low rotation speed or a small air volume range,
It is necessary to use capacity control using a suction throttle valve or the like, and (1) when the number of rotations becomes low, the motor 1
The rotation speed of the cooling fan 16a integrally provided with the motor 6 also decreases at the same time, the motor cannot be cooled, and the motor coil temperature exceeds a predetermined temperature range. (2) Oil supply to the compressor 12 is performed by the oil separator 5 and the screw. Since the operation is performed by utilizing the differential pressure inside the compressor 12, even if the rotation speed becomes low and the amount of air discharged from the screw compressor is greatly reduced, the amount of refueling does not decrease. There is a problem that the liquid is compressed and an overload occurs.

In order to avoid these problems, there are various methods such as providing a fan driven by a dedicated motor to cool the electric motor, and providing a valve for adjusting the amount of lubrication in a low rotational speed range. It is possible, but the structure is complicated and not practical.

Therefore, in the apparatus described in Japanese Patent Application Laid-Open No. Hei 7-35079, in the small air volume range, the displacement control is not performed, and the suction throttle valve 2 is closed at the same time as the set lower limit speed is reached. In no-load operation. However, this method can be expected to save energy compared to the conventional method, but it is still insufficient. Thus, in the present invention, the equipment is configured as shown in FIG. 1 to control the capacity of the screw compressor. The detailed flow is shown in FIG.

Approximately 30% to 10% of the specified discharge air amount
In the operation range of the air amount of 0%, the drive frequency of the electric motor 16 is changed by the inverter to control the rotation speed. On the other hand, when the discharge air amount falls within the operating range of 30% or less of the specification discharge air amount, the discharge pressure of the compressor detected by the pressure sensor 18 reaches the set pressure P ₁ stored in the storage means and the control output unit. If so, the rotation speed of the screw compressor is held at the lower limit rotation speed set in the rotation speed control. Then, the solenoid valve 21 is opened, and the suction throttle valve 2 is closed. Further, the discharge pressure of the compressor 3 is reduced to switch to the capacity control of the no-load operation. As a result, the pressure at the discharge port 4 of the compressor 12 decreases, and it is possible to greatly reduce power consumption as compared with the related art.

FIG. 2 shows the ratio of the power consumption to the discharge air amount ratio in this case. In FIG. 2, line A represents power consumption characteristics according to the conventional method, and line B represents power consumption characteristics according to an embodiment of the present invention. When the discharge air amount ratio is near 0%, the power consumption is reduced to about half as compared with the conventional case.

Since the discharge pressure has been reduced, the compressor rotor 3
The amount of oil supplied to the portion can also be reduced, and there is no possibility that the torque generated when the lubricating oil is liquid-compressed will abnormally increase. In addition, when the screw compressor is operated at a low load, the oil supply temperature is reduced and drain is easily generated in the oil separator 5, but when the screw compressor is not operated, the pressure in the oil separator 5 is also reduced, so that the drain can be generated. Less likely.

Further, the compressor rotation speed is maintained at the set lower limit rotation speed, the suction throttle valve 2 is closed, and as a result of the operation, the discharge pressure of the compressor 3 is reduced, and the time of the no-load operation is set. The rotation speed of the compressor is held at the lower limit rotation speed, and the time of the load operation in which the suction throttle valve 2 is opened and operated is determined by the storage means and the timer means built in the control output unit. When the former ratio is, for example, a load of 10% or less, or, for example, the former operation time continuously exceeds 3 minutes,
Stop the compressor. Furthermore, continue to monitor the pressure in the pressure sensor 18 even during stopping, it is to restart the compressor when the pressure drops to the set pressure P ₄ that is stored in the storage unit and controller unit. If the operation of the compressor is controlled in this way, the power consumption characteristics become as shown by the line C in FIG.
Further, it is possible to reduce power in an operation region where air consumption is small.

In the above embodiment, when the amount of consumed air is reduced and the rotational speed of the compressor reaches the set lower limit rotational speed, the target set pressure P ₀ in the rotational speed control region and the no-load operation (hereinafter referred to as the rotational speed) at the same time the number closes the intake throttle valve 2 with a constant, referred to the operating conditions for reducing the discharge pressure of the compressor 3 and the no-load operation.) is the same upper limit pressure P ₁ to start, control the air amount An unstable ON-OFF command is generated in the solenoid valve 21 when the system switching point is coincident with the system switching point, and the hunting of the suction throttle valve 2 may occur.

In a general constant speed type motor driven screw compressor, when the displacement control for closing only the suction throttle valve is not performed, the specified pressure P ₀ * of the compressor and the set upper limit to enter the no-load operation. The pressure P ₁ * is set to the same pressure. This is because the motor is designed to have the maximum allowable output during the full load operation state at the specified pressure. That is, when the set upper limit pressure P ₁ * for starting the no-load operation is higher than the specified pressure P ₀ *, the motor is overloaded, and on the other hand, the set upper limit pressure P 1 * for starting the no-load operation is set to the specified pressure P _0. If it is lower than *, there is a problem that a no-load operation is started before the specified pressure is reached.

On the other hand, in the present invention, since no-load operation is started at the lower limit rotation speed of the rotation speed control region by the inverter, there is no limitation on the compressor driven by the constant speed motor, and the target in the rotation speed control region is not limited. Even if the no-load operation start pressure P ₁ is set higher than the set pressure P ₀ (that is, the specified pressure in the case of a compressor driven by a constant speed motor), no problem such as overload of the motor occurs. Therefore, in the present invention, P
So that _1> P ₀ to set the P _1. For example, P ₀ is 0.6
In the case of 9Mpa it is, and 0.79Mpa the P _1. By setting in this manner, a time delay can be provided between the rotation speed control region and the constant speed control at the lower limit rotation speed,
There is no fear that the hunting described above occurs.

It should be noted that depending on the set pressure, control conditions suitable for the compressor may be deviated, which may cause inconvenience. Therefore, automatically calculates the appropriate value by entering a target setting pressure P _0, using a method of determining P ₁ to P _4. This P _{1 to} P ₄
An example of a method for determining the above is shown below. Now, the pressure P ₀ becomes P ₀ =
It is assumed that the pressure is 0.69 MPa. If the load becomes low in this state, the maximum pressure is increased by 0.098 MPa, and P ₁
= P ₀ + 0.098 = 0.79 MPa. Here, the blowing pressure of the safety valve is 0.93 MPa.
Therefore, the control upper limit pressure satisfies the condition that it is equal to or lower than the blowing pressure. Next, conditions for stoppable pressure P ₂ is P _2> = P _1. That is, until P1 = P2 is b - de driving, unload Once become P ₁ = P ₂ - from switch to de operation, the unload - a from when switching to de operation until the pressure drops to P ₀ time The calculation is performed, and if this time is equal to or longer than a predetermined time, the controller is stopped, and if the time is within the predetermined time, the control device is operated so as to perform the load operation. B - the pressure P ₃ to return to the de operation is P ₃ = <P _0. Further, the pressure P ₄ for restarting after the operation is stopped is P ₄ =
P ₀ −0.098 MPa = 0.59 MPa.

When each of the pressures P _{0 to} P ₄ is set as described above, if P ₀ = 0.83 MPa or more, P ₁ = (P ₀ +
0.098)> 0.93 MPa, which exceeds the blowing pressure of the safety valve. Therefore, P ₁ = P ₀ + (0.07
/ P ₀ ) An empirical formula suitable for each specification represented by MPa is stored in the storage means of the control device of the compressor. That is, in accordance with the pressure setting of the compressors, by storing the arithmetic expression Expression in accordance with the specifications, only the input of the P _0, can automatically determine each set pressure. In this embodiment, the relationship between the set pressures is given by an arithmetic expression, but a discrete value may be used by interpolation. Further, the relational expression is stored in the storage means, but a relational expression stored in an external storage means such as a floppy disk may be used.

Conventionally, when a constant-speed electric motor is used, the occurrence of a pressure difference due to the opening / closing operation of the suction throttle valve and the solenoid valve cannot be avoided. For example, even if the minimum required pressure is 0.59 Mpa, the load operation and the no-load operation were repeated between 0.69 Mpa and 0.59 Mpa. On the other hand, in the rotation speed control method using the inverter, the rotation speed can be changed while the pressure is kept constant by the PID control, and the minimum required pressure is 0.59 Mp.
By setting a to the target set pressure P ₀ in the rotation speed control region, it is not necessary to increase the pressure unnecessarily to a high pressure, and a power saving effect can be obtained. However, during a no-load operation in a low-load region where the rotation speed is not controlled, for example, 0.59 Mpa and 0.49 Mpa
The effect is reduced by half when the pressure falls below 0.59 MPa. That is, when the pressure is 0.59
When drops Mpa or less when a trouble can not reduce the P ₀ after all.

Therefore, the pressure sensor 1 detects that the compressed air is consumed and the discharge pressure decreases after the no-load operation.
8 to detect. Further, the pressure (lower pressure) P ₂ at the time of returning to the load operation, the same as the target setting pressure P ₀ in the speed control region, the more pressure. As a result, even when the air consumption further decreases from the rotation speed control region,
The operation can always be performed at a pressure higher than the target set pressure in the rotation speed control region. Further, even if the control pressure is increased, the increase in operating power can be very small because the load is in the low load range.

Next, a modified example of the present invention will be described. This modification relates to control when the load decreases. When the load decreases, automatic stop and automatic restart are performed by the timer function described above. At this time, when the automatic stop condition of the compressor is satisfied, the load operation is forcibly performed once, and the discharge pressure of the compressor is temporarily set to the target set pressure P in the rotation speed control region.
₀ to raise the pressure to P ₃ which is a P _3> P _0, and then stops the compressor. Moreover, P ₄ the pressure P ₄ with respect to the target set pressure P ₀ in the speed control region to restart the compressor>
= P ₀ is set. As a result, the compressor can be stably controlled even in a low load region where the rotation speed is maintained at a constant speed. That is, according to this modification, the target set pressure in the rotation speed control region can be maintained in all load regions, and therefore, the power saving effect of the rotation speed control by the inverter described above, in which the compressor can be operated at the minimum necessary pressure. Can be used to the fullest.

In the above embodiment, the set value of the control pressure is stored in the storage means 20a, and can be displayed when necessary by using the display and input means 20b. These settings are automatically computed by entering the control pressure P _0, is adapted to be determined, it can be easily be used to display and input means 20b. For example, in an example in which the maximum pressure is limited by the pressure, the above-mentioned five control pressures P ₀ , P ₁ , P ₂ , P ₃ , and P ₄ are calculated as follows: P ₁ = P ₃ = P ₀ + (0.07 / P ₀ ) Mpa is set using the equation of P ₂ = P ₄ = P ₀ and stored in advance in the storage means.
Change only ₀ . In this case, the operating pressure can be easily changed.

It is needless to say that each set pressure can be manually determined. For example, P ₁ = P ₂ = P ₃ =
P ₀ + X, as _{P 4 = P 0 -Y, X} , while watching the value of every moment to be displayed on the display device the value of Y, is input using the input switch or the like provided on the control board. Where 0.0
01> X or Y> 0.098.

Further, a timer for starting counting after the automatic restart is provided in the storage means and the control unit 20a so that the compressor is not stopped for a predetermined time t ₁ even if the load decreases,
After this time t ₁ elapses still load condition of the compressor to automatically stop the compressor when it is satisfied the automatic stop condition.
Thus, it is possible to prevent the compressor from stopping before the oil temperature sufficiently rises and causing drainage in the oil separator 5 due to the frequent operation and stoppage of the compressor.

FIG. 3 shows an example of changes in the amount of air used and the pressure when the above-described control method of the screw compressor is used, and FIG. 4 shows an example of a flow of operation control of the screw compressor. In the present invention, rotation speed control using an inverter,
In the screw compressor combined with capacity control and its operation method, there is no operation area of the conventional method of controlling the capacity by closing only the suction throttle valve during the capacity control operation, thereby reducing the power and the generation of drain. .

As described above, according to this embodiment, by inputting the control set pressure, the pressure can be easily set in the capacity control under a low load, and there is no inconvenience of the machine due to the pressure condition. In addition, since a function for changing and confirming the input value is provided, the operating state of the compressor can be always grasped, and the reliability in the compressor operation can be improved.

[0041]

According to the present invention, when the screw compressor is operated with a low load and a reduced rotational speed of the compressor, (1) the power reduction effect is large.

(2) The required driving torque does not increase, and no inverter trip occurs in the inverter driven compressor.

(3) Since the discharge pressure of the compressor also decreases,
There is no danger of drainage in the oil separator.

(4) Even if the load is further reduced and the compressor is stopped, the pressure required for controlling the rotational speed can be secured.
The set pressure for the rotation speed control can be reduced, and the power can be reduced to near ideal.

[Brief description of the drawings]

FIG. 1 is a schematic view of a screw compressor device according to one embodiment of the present invention.

FIG. 2 is a graph showing characteristics of power consumption.

FIG. 3 is a graph showing an example of a change in air usage and pressure.

FIG. 4 is a flowchart of an example of operation control.

[Explanation of symbols]

2 ... suction throttle valve, 5 ... oil separator, 6 ... oil separator element, 8 ... check valve, 9 ... pressure regulating valve, 16 ... electric motor, 17 ... inverter, 18 ... pressure sensor, 19 ... input / output unit, 20a ... storage means and control unit, 20b ... display and setting input means, 2
1 ... Solenoid valve.

Continuation of front page (56) References JP-A-6-10876 (JP, A) JP-A-6-123287 (JP, A) JP-A-5-133342 (JP, A) JP-A-4-159491 (JP) , A) Japanese Patent Publication No. 5-46797 (JP, B2) (58) Fields investigated (Int. Cl. ⁷ , DB name) F04C 18/16 F04C 29/10 311

Claims (2)

(57) [Claims] 1. A suction throttle valve having a pair of male and female rotors rotatably supported by bearings, comprising an electric motor for driving the rotors, and an inverter for controlling the electric motor, and adjusting a flow rate on a suction side. In a screw compressor provided with, a rotation speed control operation of controlling the capacity of the screw compressor by changing the rotation speed of the electric motor by an inverter ,
A no-load operation in which the screw compressor is driven at the minimum rotation speed during the rotation speed control operation, the suction throttle valve is closed, and the discharge pressure of the screw compressor is reduced.
And a control hand to control the screw compressor to perform
It includes a stage, the discharge pressure when switching the compressor into the unloaded operation P1, the rotational speed of the compressor is a lowest rotational speed
Set ejection when the discharge pressure when switching to a driving load operation P2, operated rotational speed control to open the intake throttle valve Te
When the output pressure is represented by P0, the control means sets P1>
P1 and P2 are calculated and set to P0 and P2 = <P0,
To automatically stop the compressor due to a decrease in load,
A screw compressor, wherein the compressor is forcibly operated under load until the pressure becomes higher than the output pressure P0 to increase the pressure, and then the compressor is stopped. 2. The control means restarts the compressor.
When the discharge pressure reaches a pressure equal to or higher than the set discharge pressure P0.
The screw compressor according to claim 1, wherein the screw compressor is controlled so as to be restarted when it comes .