JPH05231363A - Vi variable screw type compressor - Google Patents

Abstract

PURPOSE:To promptly and accurately determine the optimum Vi with a simple constitution by driving a Vi variable valve by utilizing a step motor, in a screw type compressor using a volume control valve and the Vi variable valve. CONSTITUTION:A parameter of suction pressure, delivery pressure, etc., is trend- analyzed by a control unit of providing a data recorder and an arithmetic unit. The optimum Vi is estimated, and its signal is input to a step motor 7 to drive a rod 11 rotated, so that a Vi variable valve 6 screwed to this rod 11 is adjusted. A pressure of fluid just before starting delivery is detected to adjust the Vi variable valve 6 by giving the signal to the step motor 7 so as to minimize a difference between this pressure of fluid just before starting delivery and the delivery pressure.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable Vi valve for varying a set volume ratio Vi which is a ratio of a suction volume to a discharge volume of a screw type compressor, and a variable suction volume to vary a suction flow rate. And a Vi variable screw compressor having a capacity control valve for

[0002]

2. Description of the Related Art Conventionally, each of a displacement control valve and a Vi variable valve uses an adjusting device composed of a cylinder and a piston, and hydraulic pressure is applied to the piston so that the piston is operated at a pressure difference from a back side pressure (mainly suction pressure). By moving the capacity control valve and V
The method of moving the i variable valve was taken.

Further, conventionally, the optimum Vi has been determined by detecting the suction pressure and the discharge pressure and calculating the ratio using the representative value of the specific heat ratio of the gas. That is, P ₁ ... Suction pressure P ₂ ... Discharge pressure K ... When specific heat ratio = C _p / C _v P ₁ V ₁ ^K = P ₂ V ₂ ^K P ₂ / P ₁ = [V ₁ / V ₂ ] ^K V ₁ / V ₂ = [P ₂ / P ₁ ] ^{1 / K} to determine the optimum Vi.

[0004]

Conventionally, since the cylinder and the piston are used to move the Vi variable valve, the V
The i variable valve drive mechanism has a structure projecting to the outside of the compressor, which complicates the compressor and diversifies hydraulic piping.

Conventionally, a drive mechanism similar to the one used to move the displacement control valve as described above is also provided in the Vi variable valve, and hydraulic pressure is applied to the piston to generate a differential pressure from the suction pressure (mainly). Since the Vi variable valve was moved by moving the piston, the amount of movement and speed were not constant, and the optimum Vi
It was difficult to set the position of.

According to the present invention, the Vi variable valve is moved back and forth by the rod driven by the step motor, so that the Vi variable valve can be manufactured at low cost and operates reliably and accurately. Another object is to obtain a Vi variable screw compressor whose speed can be freely selected.

Conventionally, the suction pressure and the discharge pressure of the screw type compressor are detected, and the optimum Vi is calculated by calculating the ratio using the representative value of the specific heat ratio of the gas. Since oil is actually injected inside, there is little basis for using the specific heat ratio, and this was just a theoretical value.

The present invention detects the pressure just before the space formed by the rotor and the inner wall of the casing communicates with the discharge space, and gives a signal to the step motor so as to minimize the difference between this pressure and the discharge pressure. The object of the present invention is to obtain a variable screw compressor that is highly accurate and requires little power.

Further, conventionally, since the optimum Vi is obtained from the theoretical value calculated thermodynamically as described above, only macro control is possible. The present invention calculates the optimum value of Vi based on the trend analysis of the system throughout the period in which the screw type compressor is operated,
An object of the present invention is to obtain a Vi variable screw type compressor capable of setting the Vi variable valve to the optimum position throughout the season and the whole usage period throughout the year.

Furthermore, conventionally, the position of the Vi variable valve is determined by detecting the position of the piston for driving the valve, but the accuracy is poor because the rod and the piston are interposed. It is an object of the present invention to obtain a Vi variable screw compressor that has high accuracy and enables more detailed optimum operation by directly detecting the position of the Vi variable valve.

[0011]

According to the present invention, the design volume ratio V is
Vi having a variable Vi valve for varying i and a capacity control valve for varying the suction volume by varying the suction volume
In the variable screw type compressor, a rod passing through the capacity control valve is provided with a male screw and a Vi variable valve is provided with a female screw to drive the Vi variable valve by rotating the rod, and the rod outside the casing is provided. A step motor is attached to the motor, and the motor can be driven by an external signal to automatically change Vi.

The present invention also provides a Vi variable screw compressor having the above Vi variable valve and capacity control valve,
In order to set Vi that minimizes the required power, a pressure sensor is attached to the casing inner wall side immediately before the space formed by the rotor and the casing inner wall communicates with the discharge space, and the pressure and discharge pressure detected by this pressure sensor The configuration is such that a signal is applied to the step motor so as to minimize the difference between the two.

The present invention also provides a Vi variable screw compressor having the above Vi variable valve and capacity control valve,
The suction pressure of the system in which the screw compressor is operated,
The controller has a data recording device and a control device including a computing device to analyze parameters such as discharge pressure, predict the optimum Vi, and set the Vi variable valve to the value of this Vi.

Further, the present invention provides a Vi variable screw compressor having the above Vi variable valve and capacity control valve, wherein
The i variable valve is provided with a tapered groove, a displacement sensor is attached from the outside of the casing so as to detect a gap with the groove, and the position of the Vi variable valve is specified by the displacement of the gap.

[0015]

By operating the step motor by an external signal and rotating the rod, the Vi variable valve is appropriately moved back and forth to automatically adjust Vi.

A pressure sensor provided on the inner wall of the casing immediately before the space formed by the rotor and the inner wall of the casing communicates with the discharge space, and a step motor is provided to minimize the difference between the detected pressure and the discharge pressure. By providing a signal, the power to drive the screw compressor is minimized.

Further, the tendency of the suction pressure and the discharge pressure of the system in which the screw type compressor is operated is analyzed by a control device having a data recording device and a computing device,
The optimum Vi is predicted, and the value of this Vi is input to the step motor to drive it.

Further, the Vi variable valve is provided with a tapered groove, and the position of the Vi variable valve is accurately specified by detecting the gap between the Vi variable valve and the groove with a displacement gauge provided outside the casing.

[0019]

EXAMPLES The present invention will be described with reference to examples.

In FIG. 1, 1 is a suction hole, 2 is a casing, 3 is a discharge hole, 4 is a discharge port, 5 is a capacity control valve, and 6
Is a Vi variable valve, 7 is a step motor, 11 is a rod which is rotationally driven by the step motor 7, 12 is a male screw formed at the end of the rod 11, 13 is a piston rod for moving the capacity control valve 5 back and forth, and 14 is Hydraulic piston, 15 is a hollow hole formed in the piston rod 13, 16 is a hydraulic cylinder, 17
Is a rod body loosely fitted in the hollow hole 15, 18 is a spiral groove formed on the peripheral surface of the rod body, 21 is a displacement sensor mounting hole, and 22 and 23 are supply and discharge ports of hydraulic oil to the hydraulic cylinder 16. Is. In the drawings, the male and female rotors housed in the cylinder 2 are omitted.

Next, the operation of this embodiment will be described.

The fluid sucked from the suction hole 1 is compressed by the male and female rotor in the casing 2, and then discharged to the discharge hole 3 through the discharge port 4.

When it is necessary to change the design volume ratio Vi which is the ratio between the suction pressure and the discharge pressure, the step motor 7
Works. FIG. 1 shows a state in which the Vi variable valve 6 is at the most advanced position (leftward in the drawing). Now this Vi
When the variable valve 6 needs to be retracted (moved to the right in the drawing), the rod 11 is rotated by the step motor 7 to rotate the rod 11 and the female screw 10 and the rod 11 provided on the Vi variable valve 6 are rotated.
The Vi variable valve 6 is retracted by screwing with the male screw 12 of. At this time, the displacement control valve 5 is retracted by the hydraulic pressure in the hydraulic cylinder 16 as the Vi variable valve 6 is retracted, and when the Vi variable valve 6 is fixed at the newly set position, it is in contact with the variable valve 6. Will be fixed again. As a result, the tip of the capacity control valve 5 retracts to a position corresponding to the changed Vi, and the opening degree of the discharge port 4 is newly defined.

In this state, when the load applied to the screw type compressor fluctuates and capacity control is required, the hydraulic piston 14 moves forward based on the control command to move the capacity control valve 5 forward by the required amount. Therefore, the fluid being compressed is bypassed from the gap between the Vi variable valve 6 and the capacity control valve 5 to the suction side.

A pin protruding from the hydraulic piston 14 is engaged with the spiral groove 18 of the rod body 17, and the amount of forward and backward movement of the hydraulic piston 14 can be detected with high accuracy by the magnitude of the rotation angle of the rod body 17. You can do it.

The position detection of the Vi variable valve 6 will be described with reference to FIG. Note that FIG. 2 is drawn so that the positions of the Vi variable valve 6 coincide with those of FIG. 1. The end of the piston rod 13 is fixed to the end of the capacity control valve 5 by a tightening bolt 25. A nut is attached to the end of the rod 11 where the male screw 12 is formed.
26 is fixed by the bolt 27. Reference numeral 8 is a tapered groove formed on the bottom surface of the Vi variable valve 6,
A displacement sensor (not shown) is inserted from the outside through the displacement sensor mounting hole 21 and mounted, and the position of the Vi variable valve 6 is detected by the groove 8 and the displacement sensor. The displacement sensor is attached so as to detect the gap with the groove 8, and the position of the Vi variable valve 6 can be specified by detecting the displacement of this gap.

Next, referring to FIG. 1, a method of driving the step motor 7 will be described. 9 is a pressure sensor mounting portion,
A space formed by the rotor and the inner wall of the casing is provided on the inner wall side of the casing immediately before communicating with the discharge space. This pressure sensor detects the above-mentioned "pressure immediately before communication" P _d1 while detecting the discharge pressure P _d2 in the discharge hole 3 to obtain the difference ΔP between the two pressures, and the step motor so as to minimize the value of this ΔP. Signal to 7. By doing so, a signal immediately corresponding to various operating conditions is transmitted to the step motor 7, the step motor 7 is driven, and the optimum Vi is set quickly.

Another method of driving the step motor 7 will be described. There are various factors that influence the value of the design volume ratio Vi, but as the parameters of the trend analysis, the outside air temperature of the system in which the screw compressor is operated, the cooling water temperature, the date and time, the suction pressure, the discharge pressure, Vi variable valve position, displacement control valve position, ampere (of compressor motor), etc. are selected. As the analysis method, the tendency including the time difference is analyzed by weighting factor analysis and regression analysis, and further the calculation of the tendency by the least square method is adopted. In FIG. 1, the control device 30 has functions such as data storage 31, factor analysis 32, arithmetic expression 33, controlled variable output 34, measured value, controlled variable screen output 35, etc. The optimum Vi is predicted by analysis, the signal of the value of this Vi is input to the step motor 7, the rod 11 is rotationally driven, and the position of the Vi variable valve 6 is set to the optimum position. By doing so, the optimum Vi value is always set during the whole day of use, throughout the season, and throughout the year. Moreover, the number of times the Vi variable valve 6 moves is reduced, and the reliability of the sliding portion can be increased.

3 and 4 show the same embodiment as in the case of FIGS. 1 and 2 described above, but the position of the Vi variable valve 6 is simply different. That is, FIG. 3 shows a state in which the Vi variable valve 6 is in the most retracted position (rightward in the drawing). If it is necessary to change Vi from this state due to a change in operating conditions, the step variable motor 7 advances the Vi variable valve 6. In this case, the Vi variable valve 6 presses the capacity control valve 5 by its end face to move it forward integrally. As described above, the set position of the Vi variable valve 6 is detected by the displacement sensor installed in the displacement sensor mounting hole 21.

FIG. 5 is a perspective view of the Vi variable valve 6.
Is the through hole of the piston rod 13 and 10 is the male screw of the rod 11.
A female screw to be screwed with 12 and a tapered groove 8 are provided.

[0031]

According to the present invention, the rod passing through the capacity control valve is provided with a male screw, while the Vi variable valve is provided with a female screw so that both are screwed and the rod is rotated by a step motor outside the casing. Therefore, by driving the step motor by an external signal, the Vi variable valve can be moved back and forth, and Vi can be changed automatically and accurately.

Further, in the present invention, since the pressure sensor is provided on the casing inner wall side immediately before the space formed by the rotor and the casing inner wall communicates with the discharge space, the pressure detected by the pressure sensor is compared with the discharge pressure. By giving a signal that minimizes this differential pressure to the step motor, it is possible to accurately and quickly set the value of the optimum Vi that minimizes the required power and operate the Vi variable valve.

According to the present invention, parameters such as suction pressure and discharge pressure of a system in which a screw type compressor is operated are analyzed by a controller having a data recording device and a calculation device to calculate an optimum value of Vi. By,
The Vi variable valve can be set to the optimum position at all times of the day, the season, and the entire use period throughout the year.

Further, according to the present invention, since the Vi variable valve is provided with a taper groove and the position of the valve can be directly detected in cooperation with the displacement gauge provided outside the casing, the position of the Vi variable valve as a parameter in the trend analysis. Can be determined with high accuracy, which is beneficial for optimum driving.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of a device of one embodiment of a Vi variable screw compressor of the present invention taken along a vertical plane including a center position of a capacity control valve and a Vi variable valve.

FIG. 2 is an enlarged detailed view of a Vi variable valve portion of FIG.

FIG. 3 is a sectional view of a device of one embodiment of a Vi variable screw compressor of the present invention cut along a vertical plane including a central position of a volume control valve and a Vi variable valve, and a volume control valve and a Vi variable different from those in FIG. It is sectional drawing which shows a valve position.

FIG. 4 is an enlarged detailed view of a Vi variable valve portion of FIG.

FIG. 5 is a perspective view of a Vi variable valve.

[Explanation of symbols]

 1 Suction hole 3 Discharge hole 4 Discharge port 5 Volume control valve 6 Vi variable valve 7 Step motor 8 Groove 9 Pressure sensor mounting part 10 Female screw 11 Rod 12 Male screw

Claims (4)

[Claims] 1. A Vi for varying a design volume ratio Vi.
In a Vi variable screw type compressor having a variable valve and a displacement control valve for varying a suction volume to vary a suction flow rate, a rod passing through the displacement control valve is provided with a male screw and a Vi variable valve is provided with a female screw. The Vi variable valve is driven by rotating the rod, and a step motor is attached to the rod outside the casing.
A Vi variable screw compressor capable of automatically changing Vi by driving the motor by an external signal. 2. A pressure sensor is mounted on the casing inner wall side immediately before the space formed by the rotor and the casing inner wall communicates with the discharge space in order to set Vi at which the required power is minimum, and this is detected by this pressure sensor. The Vi variable screw compressor according to claim 1, wherein a signal is applied to the step motor so as to minimize the difference between the pressure and the discharge pressure. 3. The optimum Vi is predicted by performing a trend analysis of parameters such as suction pressure and discharge pressure of a system in which a screw type compressor is operated by a control device including a data recording device and a computing device to predict the optimum Vi. The Vi variable screw compressor according to claim 1, wherein the Vi variable valve is set to a value. 4. The Vi variable valve is provided with a tapered groove,
The Vi variable screw compressor according to claim 3, wherein a displacement sensor is attached from the outside of the casing so as to detect a gap with the groove, and the position of the Vi variable valve is specified by the displacement of the gap.