JP2518114B2 - Compressor drive - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention mainly relates to a drive unit for a screw compressor, and more particularly to a drive unit in which a steam turbine is connected to the input side of the compressor and the steam turbine drives the compressor.

[0002]

2. Description of the Related Art Conventionally, there has been proposed one in which a steam turbine is connected to an input side of a screw compressor used in a refrigeration system and the compressor is driven by the steam turbine.

[0003]

The screw compressor is generally driven by an electric motor.
In a compressor driven by a motor, a current limiting device is provided to prevent the problem of damage due to excessive stress when excessive torque is applied to the compressor.

That is, the compressor is generally provided with a slide valve capable of controlling its capacity, detects the outlet temperature of water or brine in the evaporator of the refrigerating apparatus used as the compressor, and detects the outlet temperature by the outlet temperature. The slide valve is operated and its capacity is controlled.
When the motor current exceeds 1.05 times the rated current, the slide valve is forcibly closed to prevent excessive torque from being applied to the compressor.

However, when a steam turbine is used as the drive source of the compressor or a steam turbine is added to the motor to drive the compressor, the motor can be dispensed with,
Further, even when used in combination, there is an advantage that the motor power can be reduced. On the other hand, since the steam turbine has many fluctuations in its steam source, the output of the steam turbine may exceed the allowable power of the compressor. There has been a problem that excessive torque is applied to the compressor to cause damage.

The present invention focuses on that the shaft power Kw of the compressor is dominated by the suction pressure and the discharge pressure of the refrigerant, and limits the output of the steam turbine based on the suction pressure and the discharge pressure. Then, an excessive torque is not applied to the compressor, and an object thereof is to prevent an excessive torque from being applied to the compressor while using the steam turbine.

[0007]

The present invention detects a suction side pressure and a discharge side pressure of the compressor 1 in a compressor drive device in which a steam turbine 9 is connected to an input side of the compressor 1. A low pressure detector 18 and a high pressure detector 19 are provided, and shaft power data in the compressor 1 calculated based on the suction side pressure and the discharge side pressure are provided and detected by the respective detectors 18, 19. When the shaft power value obtained by calculating the suction side pressure and the discharge side pressure is within the preset allowable power range of the shaft power, it operates to output the evaporation turbine 9, and when it exceeds the allowable power range, The turbine output control means 20 for stopping the output of the evaporation turbine 9 is provided. Further, the upper limit value of the suction side pressure and the upper limit value of the discharge side pressure are set in advance from the shaft power data of the compressor 1 calculated based on the suction side pressure and the discharge side pressure, and each of the detectors 18, Turbine output that operates when the suction side pressure and the discharge side pressure detected by 19 are equal to or lower than the respective upper limit values to output the steam turbine 9, and stops the output of the steam turbine 9 when exceeding the upper limit values. The control means 20 may be provided.

Further, the steam turbine 9 includes a steam valve 10 for controlling the operation and stop of the steam turbine 9, and the steam valve 10 serves as turbine output control means 20.
Is preferably controlled to open the shaft power of the compressor 1 within the allowable power range to operate the steam turbine 9 and to stop the operation of the steam turbine 9 when the power exceeds the allowable power range.

In the present invention, the steam turbine 9 is used as the drive source of the compressor 1. However, the steam turbine 9 can be used in combination with the motor 7, and even when the motor 7 is used in combination. , When the motor 1 is turned off and the compressor 1 is driven only by operating the steam turbine 9, and when the motor 7 is driven and the motor 7 and the steam turbine 9 are used in combination. In some cases, the compressor 1 may be driven. When used in combination with the motor 7, the turbine output shaft 12 of the steam turbine 9 and the motor 7
It is preferable to connect the drive shaft 13 of FIG.

[0010]

When the compressor 1 is driven by using the steam turbine 9 as a drive source, when the shaft power of the compressor 1 is less than its allowable power (for example, 220 KW), the steam turbine 9 is caused to output and the steam turbine 9 is output. Thus, the compressor 1 is driven, and when the suction side pressure and the discharge side pressure fluctuate and the shaft power exceeds the allowable power range, the output of the steam turbine 9 is stopped.

Therefore, when the shaft power is below the allowable range, the steam turbine 9 can be output to drive the compressor 1, but when it exceeds the allowable range, the output of the steam turbine 9 is stopped. Therefore, it is possible to prevent an excessive torque from being applied to the compressor 1.

Moreover, the low pressure detector 18 and the high pressure detector 19 are used to detect the suction side pressure and the discharge side pressure and control the output from the steam turbine 9 so that an excessive torque is not applied. Therefore, it is possible to control the shaft power applied to the compressor 1 close to the measured value.
Since the pressure detectors 18 and 19 that are widely used in refrigeration systems as highly reliable ones can be used as they are, the steam detectors can be highly accurate, inexpensive, and highly reliable. Since the turbine 9 can be controlled, it is possible to effectively prevent damage to the compressor due to excessive torque.

Further, the upper limit value of the suction side pressure and the upper limit value of the discharge side pressure are set in advance from the shaft power data of the compressor 1 calculated based on the suction side pressure and the discharge side pressure, and each of the above detections is performed. When the suction side pressure and the discharge side pressure detected by the devices 18 and 19 are equal to or lower than the respective upper limit values, the steam turbine 9 is output, and when the upper limit values are exceeded, the output of the steam turbine 9 is stopped. By providing the turbine output control means 20 for controlling the shaft power, the shaft power is calculated based on the suction side pressure and the discharge side pressure detected by the detectors 18 and 19, and whether the shaft power is within a preset allowable power range. Since it is not necessary to determine whether or not it is, that is, it is only necessary to determine whether the suction side pressure and the discharge side pressure are equal to or less than a preset upper limit value or exceed the upper limit value, the control system is simple. Can be Kill.

The steam turbine 9 is opened and closed by opening and closing the steam valve 10.
When the output of the compressor is controlled, the operation can be stopped when the shaft power of the compressor 1 exceeds the allowable power range, so that unnecessary operation of the steam turbine 9 can be eliminated and the durability of the entire device can be improved. Of.

Also, when the steam turbine 9 and the electric motor 7 are connected to the input side of the compressor 1, when the shaft power of the compressor 1 exceeds the permissible range, the steam turbine 9 of the steam turbine 9 is also in the same manner as described above. Since the output can be stopped, the motor power by the steam turbine 9 can be reduced, and damage to the compressor 1 due to excessive torque can be prevented.

Even when the steam turbine 9 and the motor 7 are used together as described above, the power of the motor 7 can be turned off and the compressor 1 can be driven only by the steam turbine 9. In this case, the drive of the compressor 1 is also stopped by stopping the output of the steam turbine 9. In this case, the power of the motor 7 is turned on and the drive of the motor 7 is switched to the compression of the compressor. It is preferable to continue driving the machine 1.

When the compressor 1 is driven by using the motor 7 and the steam turbine 9 together, the output of the steam turbine 9 is stopped and the compressor 1 is operated only by the motor 7. Driven.

In any case, when the shaft power exceeds the allowable power, the output of the steam turbine 9 is stopped, so that it is possible to prevent excessive torque from being applied to the compressor 1.

When used in combination with the motor 7, a clutch 8 is provided between the steam turbine 9 and the motor 7 instead of opening and closing the steam valve 10 to control the operation of the steam turbine. It is also possible to control the output from the steam turbine 9 by turning the clutch 8 on and off, and in this case, the output control from the steam turbine 9 can be performed with high responsiveness. Therefore, the compressor 1 The damage can be prevented more reliably.

[0020]

EXAMPLE The example shown in FIG. 1 is a screw compressor 1
Is a screw refrigerating apparatus using the above, wherein an oil separator 2 and a condenser 3 are connected to the discharge side of the compressor 1,
An evaporator 5 is connected to the outlet side of the condenser 3 via an expansion valve 4, the outlet side of the evaporator 5 is connected to the suction side of the compressor 1, and refrigerant is circulated as indicated by a solid arrow. Forming a cycle.

In FIG. 1, 6 is an oil cooler.

Therefore, in the embodiment of FIG. 1, the compressor 1
The input side of the screw rotor (not shown) of the
The steam turbine 9 is connected to the steam turbine 9 via a clutch 7 and the steam turbine 9 is in operation during operation of the steam turbine 9.
The power generated by the motor is added to the power generated by the motor 7 to drive the screw rotor.

A steam pipe 11 having a steam valve 10 is connected to the input side of the steam turbine 9 and the steam valve 10 is connected to the steam pipe 10.
When the motor is open, the motor 7 driven by steam supplied from a steam source (not shown) and the power taken out from the output side of the turbine 9 is connected to the turbine drive shaft 12 via the clutch 8. Is added to the drive shaft 13 to drive the screw rotor in total, and the output from the steam turbine 9 is stopped by disengaging the clutch 8 or closing the steam valve 10. The screw rotor is driven only by the rotor 7.

The compressor 1 is provided with a slide valve (not shown) for controlling the capacity of the compressor 1 and a capacity control device 14 for controlling the slide valve. A water or brine outlet pipe 15 to be connected is provided with a temperature detector 16 for detecting the outlet temperature, and the capacity control device 1 is controlled by the outlet temperature by the temperature detector 16.
4 is operated to control the capacity of the compressor 1, and the motor 7 is provided with a current controller 17 for controlling the capacity of the motor.
When the current of data 7 exceeds 1.05 times the rated current,
The slide valve is forcibly closed.

On the other hand, on the suction side and the discharge side of the compressor 1, a low pressure detector 18 for detecting the suction side pressure,
A high pressure detector 19 for detecting the discharge side pressure is provided, and when the shaft power of the compressor 1 is within an allowable power range, the steam valve 10 is opened to operate the steam turbine 9, and the shaft power is also set. The turbine output control means 20 is provided to close the steam valve 10 and stop the operation of the steam turbine 9 when the power exceeds the allowable power range.

The shaft power of the compressor 1 is governed by the suction side pressure and the discharge side pressure.
In the case of 0 kW, as shown in FIG. 2, the discharge side pressure is 15.
Allowable power of 330 when the pressure is ² kg / cm ² (saturation pressure equivalent to 41 ° C) and the suction side pressure is 4 kg / cm ² (saturation pressure equivalent to 0 ° C)
When the pressure becomes KW, and these pressures exceed the respective values, the allowable power is exceeded, and excessive torque is applied to the compressor 1.

That is, in FIG. 2, the horizontal axis indicates the evaporation temperature Ts.
The vertical axis represents the axial power Kw, and the solid line represents the changes in the axial power when the condensation temperature Tc is 40 ° C, 41 ° C, and 45 ° C.

Thus, the turbine output control means 20
Pays attention to that the shaft power of the compressor 1 is governed by the suction side pressure and the discharge side pressure, and the shaft power is determined by a function of each of these pressures, and is calculated in advance based on these suction side pressure and discharge side pressure. The shaft power data in the compressor 1 is input, the suction side pressure and the discharge side pressure detected by the detectors 18 and 19 are input, and both pressures are calculated to calculate the shaft power, If this shaft power is within the preset allowable power range as shown by the dotted line in FIG. 2, it operates to open the steam valve 10 to operate the steam turbine 9.
When the shaft power exceeds the allowable power range, the steam valve 10 is closed to stop the steam turbine 9.

That is, when the shaft power is 330 KW as shown by the dotted line in FIG. 2, for example, when the condensation temperature Tc is 41 ° C. and the saturation pressure is 15.2 Kg / cm ² , the evaporation temperature Ts is 0 ° C.
If the saturated pressure equivalent to the temperature of 4.0 kgg / cm ² is exceeded, the axial power of 330 KW will be exceeded. Therefore, in this case, the steam valve 10 is closed and the operation of the steam turbine 9 is stopped. The condensation temperature Tc is 41 ° C.
At this time, if the evaporation temperature Ts becomes lower than 0 ° C., the steam valve 10 is opened and the steam turbine 9 is operated.

When the condensation temperature Tc is higher than 41.degree. C. and the evaporation temperature Ts is lower than 0.degree. C. or the evaporation temperature Ts is higher than 0.degree. C., the condensation temperature Tc is 41.
When the temperature is lower than ℃, the shaft power 3 shown by the dotted line in FIG.
When it does not exceed 30 KW, the steam turbine 9 is operated without closing the steam valve 10. However, since the above-mentioned cases are rare in the normal operating state, the intake is performed in consideration of the normal operating state. The upper limits of the side pressure and the discharge side pressure may be set and set in advance.

That is, in the above example, the upper limit value of the discharge side pressure is set to, for example, 15.2 kg / cm ² , and the upper limit value of the suction side pressure is set to, for example, 4 kg / cm ² , and the discharge side is set. Only when the pressure and the suction side pressure are equal to or lower than the preset predetermined values, that is, when the steam valve 10 is opened and the steam turbine 9 is operated only in the region shown by the diagonal lines in FIG. That is, when the shaft power exceeds the allowable power, the steam valve 10 may be closed and the operation of the steam turbine 9 may be stopped.

In this case, the turbine output means 20
While simplifying the control system, it is possible to prevent the compressor 1 from being applied with an excessive torque exceeding the allowable power.

Further, the turbine output control means 20 is
When the steam valve 10 is used, the steam valve 10 is used as an electromagnetic valve in a series circuit with each switch of the pressure detectors 18 and 19, but the clutch 8 is used as an electromagnetic clutch. On / off control may be performed.

As described above, the shaft power data in the compressor 1 calculated based on the suction side pressure and the discharge side pressure are input in advance, and the suction side pressure detected by the detectors 18 and 19 and When the shaft power obtained by calculating the discharge side pressure is within the preset allowable power range of the shaft power, the steam turbine 9 is output, and when the allowable power range is exceeded, the output is stopped. The steam turbine 9
Is output only within the allowable power range of the compressor 1 to drive the compressor 1. The power of the steam turbine 9 can be used to reduce the power of the motor, Therefore, the problem of breakage due to excessive torque applied to the compressor 1 can be solved.

Moreover, whether or not the output of the steam turbine 9 is taken in is detected by using the pressure detectors 18 and 19 which are widely used in refrigeration systems as highly reliable ones to detect the suction side pressure and the discharge side pressure. However, since the control is performed on the basis of each of these pressures, in other words, the torque is controlled by observing the pressures, it is possible to control the torque close to the actually measured value, and at a low cost, and with high accuracy and reliability. It is possible to achieve high control.

Although the steam turbine 9 and the electric motor 7 are connected to the input side of the compressor 1 in the embodiment described above,
The compressor 1 may be driven by using only the steam turbine 9 as a drive source.

Further, even when the steam turbine 9 and the motor 7 are used together as in the embodiment described above, the power of the motor 7 is turned off and the compressor 1 is operated only by the steam turbine 9. It may be driven.

In this case, when the output of the steam turbine 9 is stopped, the compressor 1 is also stopped. In this case, the power of the motor 1 is turned on and the motor 7 is switched to the drive mode to perform the compression. The drive of the machine 1 may be continued.

[0039]

According to the present invention, in the compressor drive device in which the steam turbine 9 is connected to the input side of the compressor 1, a low pressure detector for detecting the suction side pressure and the discharge side pressure of the compressor 1. 18 and a high pressure detector 19 are provided, and the compressor 1 is calculated based on the suction side pressure and the discharge side pressure.
With the shaft power data in
Operates when the shaft power value obtained by calculating the suction side pressure and the discharge side pressure detected by is within a preset allowable power range of the shaft power, and outputs the evaporation turbine 9 to exceed the allowable power range. By providing the turbine output control means 20 for stopping the output of the evaporation turbine 9 at this time, the compressor 1 can be driven by using the steam turbine 9, but the axial power of the compressor 1 is allowed. When it exceeds the range, the output of the steam turbine 9 can be stopped, so that an excessive torque exceeding the allowable power is not applied to the compressor 1, and the damage of the compressor 1 can be prevented.

Moreover, since the operation of the steam turbine 9 is controlled by using the pressure detectors 18 and 19 by observing the suction side pressure and the discharge side pressure, the accuracy of torque limitation can be improved and safety can be ensured and widened. Since the pressure detector used in the refrigeration system can be used, the entire system can be simplified and the cost can be reduced, and the pressure detectors 18, 19 can be used.
Is widely used in refrigeration systems and has high reliability, so that the reliability of the entire system can be improved.

Further, the upper limit value of the suction side pressure and the upper limit value of the discharge side pressure are set in advance from the shaft power data of the compressor 1 calculated on the basis of the suction side pressure and the discharge side pressure, and each of the above detections is performed. When the suction side pressure and the discharge side pressure detected by the devices 18 and 19 are equal to or lower than the respective upper limit values, the steam turbine 9 is output, and when the upper limit values are exceeded, the output of the steam turbine 9 is stopped. Turbine output control means 20
With the above configuration, the control system of the turbine output control means 20 can be simplified, and it is possible to prevent an excessive torque exceeding the allowable power from being applied to the compressor 1.

Further, if the steam valve 10 is opened / closed as the turbine output control means 20 to control the operation and stop of the steam turbine 9, unnecessary operation of the steam turbine 9 can be eliminated and the apparatus The durability of itself can also be improved.

Further, the electric motor 7 is provided together with the steam turbine 9.
Also in the case of using together, similarly to the above, when the shaft power of the compressor 1 exceeds the allowable range, the output of the steam turbine 9 can be stopped, and the motor power by the steam turbine 9 can be reduced while being excessive. It is possible to prevent the compressor 1 from being damaged by the torque.

Further, when used in combination with the motor 7, a clutch 8 is provided between the steam turbine 9 and the motor 7, and the clutch 8 is turned on / off to allow the steam turbine 9 to move away from the steam turbine 9. When controlling the output of, the output control from the steam turbine 9 can be performed with good responsiveness, and the damage of the compressor 1 can be prevented more reliably.

[Brief description of drawings]

FIG. 1 is a piping system diagram of an entire refrigeration system to which an embodiment of the present invention device is applied.

FIG. 2 is a shaft power characteristic diagram showing the relationship between the suction side pressure and the discharge side pressure and the shaft power of the compressor at a saturation temperature corresponding to the pressure.

[Explanation of symbols]

 1 Compressor 7 Motor 9 Steam Turbine 10 Steam Valve 18 Low Pressure Pressure Detector 19 High Pressure Pressure Detector 20 Turbine Output Control Means

Claims (5)

(57) [Claims] 1. A low-pressure pressure detector 1 for detecting a suction-side pressure and a discharge-side pressure of the compressor 1 in a compressor drive device in which a steam turbine 9 is connected to an input side of the compressor 1.
8 and a high pressure detector 19 are provided, and the shaft power data in the compressor 1 calculated based on the suction side pressure and the discharge side pressure are provided, and the suction side pressure detected by each of the detectors 18 and 19 and When the shaft power value obtained by calculating the discharge side pressure is within the preset allowable power range of the shaft power, it operates to output the evaporation turbine 9, and when it exceeds the allowable power range, the evaporation turbine 9 A drive device for a compressor, which is provided with turbine output control means 20 for stopping output. 2. A low-pressure pressure detector 1 for detecting a suction-side pressure and a discharge-side pressure of the compressor 1 in a compressor drive device in which a steam turbine 9 is connected to an input side of the compressor 1.
8 and a high pressure detector 19, and the upper limit value of the suction side pressure and the upper limit value of the discharge side pressure are calculated from the shaft power data of the compressor 1 calculated based on the suction side pressure and the discharge side pressure. When the suction side pressure and the discharge side pressure which are set in advance and detected by the detectors 18 and 19 are equal to or lower than the upper limit values, the steam turbine 9 is output, and when the upper limit values are exceeded, the steam turbine 9 is output. A drive device for a compressor, which is provided with turbine output control means 20 for stopping the output of the steam turbine 9. 3. The steam turbine 9 comprises a steam valve 10 for controlling the operation and stop of the steam turbine 9, and the turbine output control means 20 controls the steam valve 10 so that the shaft power of the compressor 1 is within an allowable power range. 3. The drive device for a compressor according to claim 1, wherein the steam turbine 9 is opened to operate the steam turbine 9, and the steam turbine 9 is closed to open when the allowable power range is exceeded to stop the operation of the steam turbine 9. 4. The compressor drive device according to claim 1, wherein a steam turbine 9 and an electric motor 7 are connected to the input side of the compressor 1. 5. A drive device for a compressor according to claim 4, wherein the turbine output shaft 12 of the steam turbine 9 and the drive shaft 13 of the motor 7 are connected via a clutch 8.