The present invention relates to a fluid machine system, particularly to a control method of an operation number control device that controls a plurality of fluid machines.
An industrial machine such as a gas compression device is a device that requires regular maintenance, and meanwhile, it may be difficult to stop the industrial machine for maintenance depending on a customer that introduces the industrial machine or an application.
For this reason, in order to suppress the frequency of stop of production equipment as far as possible, Patent Document 1 and the like disclose a control method performed by an operation number control device such that a plurality of fluid machines installed can undergo maintenance or be replaced at the same time.
Patent Document 1 describes a method for controlling the number of pumps in operation which controls the number of a plurality of the pumps in operation to control the water level or flow rate. The method for controlling the number of pumps in operation is characterized in that the operation time of each of the pumps is accumulated and the order of operations is determined based on accumulated operation time values to level the operation times and the number of starts of all the pumps.
Patent Document 1 is characterized in that when a gas compression device is added due to an increase in usage amount of compressed gas in connection with an increase in production capacity of the equipment or the like, or when the difference of operation time with the device already in use is large and the operation rate is also high, a device having a long operation time frequently repeats operation and stop or a device having a short operation time always continues to operate.
In the gas compression device, for the purpose of preventing the acceleration of wear degradation of a sliding portion caused by a rise in temperature in connection with a continuous operation or the like, when the equipment has spare capacity in its entirety, after a certain time has elapsed, the compression device is rotated to a compression device at stop to be stopped and cooled, so that the life of the component is extended.
In that case, when the operation rate of the equipment in its entirety is high as described above or in operation number control for a plurality of inverter-equipped compression devices, even if a compression device has a long operation time, the compression device is operated for a certain time by rotation, and thus the reduction or leveling of the operation times cannot be realized as expected, the maintenance timings cannot be synchronized, and the like, which are problems.
An object of the present invention is, in light of the above problems, to provide a control method capable of securing the cooling times of all of fluid machines by stop of the operation of the fluid machines while leveling operation times even in operation number control for the fluid machines having different operation times in an operation number control device for the fluid machines.
In order to solve the above problems, the present invention includes a plurality of fluid machines; and an operation number control device capable of individually controlling start and stop of the fluid machines. The operation number control device sets a continuous operation time for each of the fluid machines based on total operation times of the fluid machine and other fluid machines. When among fluid machines in operation, there is a fluid machine for which the continuous operation time set for the fluid machine has elapsed and there is a fluid machine at stop, the operation number control device causes the fluid machine at stop to start and causes the fluid machine to stop.
According to the present invention, it is possible to provide the operation number control device and a method for controlling the fluid machines that can level the operation times while securing the stop time required to cool each of the fluid machines to suppress wear degradation of a sliding component in operation number control for the fluid machines even in the case of a combination of the devices having very much different operation times.
Hereinafter, embodiments of the present invention will be described with reference to the drawings
In the present embodiment, an operation number control device for gas compression devices which compress air will be described as an example.
When the operation switch 4 of the operation number control device 1 is pressed, the operation number control device 1 causes both or one of the compression devices 7A and 7B to operate, causes the pressure sensor 3 to measure the pressure of the compressed gas that is discharged from the compression devices and stored in the tank 9, and causes the control circuit 2 to increase or decrease the number of the compression devices in operation and to select a compression device to be operated according to the pressure.
Next,
First, when the operation switch 4 is pressed to make a request for an operation, the control circuit 2 determines which compression device should be operated before causing the compression device to operate. At this time, since the operation time of the compression device 7C is the shortest and the operation time of the compression device 7A is the longest, the order of start of operation is determined to be 7C, 7B, and 7A. The operation time referred to here represents the total operation time which is the sum of operation times from a predetermined time such as when the compression device 7 is produced or sold to the current time.
Next, the continuous operation time setting means 20 determines the continuous operation time of each of the compressors. At this time, the continuous operation time setting means 20 sets the shortest operation time of the compression device to be longer than a standard operation time Tc set in advance, for example, to Tc×2, and sets the operation time of the compression device having the longest operation time to Tc/2. The continuous operation time referred to here represents the time from the next start of operation of the compression device 7 to the next stop of operation.
Here, in the present embodiment, the case of three compression devices is described as an example; however, two compression devices or four or more compression devices may be provided, and in that case, the shortest and shortest operation times are set to operation times (two times the standard operation time and a half of the standard operation time). However, a predetermined coefficient may be set for each of the numbers of the devices according to the operation time, and only the maximum and minimum operation times may be set to values obtained by multiplying the standard operation time Tc by a specific multiplier or divisor.
Next, the operation of the compression device 7C is started first, and when the pressure measured by the pressure sensor 3 does not reach pressure set in advance, the operation time of the compression device 7B having the next shortest operation time is set to the continuous operation time Tc, and the compression device 7B is started.
Next, when the compressed gas generated and the compressed gas consumed in this state are in balance, the current operation is continued, and when the continuous operation time Tc of the compression device 7B set in advance has elapsed, a process of determining the switching of the compression device is performed. At this time, since the compression device 7A is in a standby state, the control circuit 2 determines that rotation can be performed, and again, the control circuit 2 causes the continuous operation time 20 to recalculate and set the continuous operation time of each of the compression devices from the operation time of each of the compression devices.
Since the compression device 7A has the longest operation time among the three compression devices, the operation of the compression device 7B is stopped at the same time the continuous operation time of the compression device 7A is set to Tc/2 and the compression device 7A is started.
Hereinafter, when the continuous operation time of each of the compression devices 7A, 7B, and 7C has elapsed, the compression device to be started next is controlled according to the pressure and presence or non-presence of the compression device at rest, so that while the leveling of the operation times of the compression devices is realized, the cooling of all the compression devices including also the compression device having a short operation time can be realized with appropriate stop periods, and a premature wear degradation of the compression devices can be prevented. Therefore, the extended life can be expected.
In a case where rotation or operation number control is performed in the control of the compression devices, when two compression devices have reached a predetermined operation time substantially at the same time, there is a case where as shown in
The second embodiment will be described with reference to
In the next step 14, the total operation times of all the compression devices connected to the operation number control device 1 are calculated, and the process proceeds to step 15.
In step 15, a compression device having the shortest operation time is selected as a rotation device from the compression devices at stop, and the process proceeds to step 16.
In step 16, it is determined whether or not the operation time of the rotation device selected is the shortest among the compression devices. In the case of YES, the process proceeds to the next step 17, the continuous operation time of the rotation device is set to Tc×2, and the process proceeds to step 18. In the case of No, the process proceeds to the next step 26.
In step 26, it is determined whether or not the operation time of the rotation device is the longest among the compression devices. In the case of YES, the process proceeds to step 27, the continuous operation time of the rotation device is set to Tc/2, and the process proceeds to step 18. In the case of No, the continuous operation time is set to Tc and the process proceeds to step 18.
In the next step 18, a compression device of which the continuous operation time has elapsed is stopped, and the process proceeds to the next step 19. In step 19, the operation of the rotation device is started, the clocking of the continuous operation time determined in the determination process of step 16, 26, or 36 is started, the process proceeds to the next step 99, and return is performed.
Therefore, the operation number control device 1 determines the continuous operation times of the compression devices 7A, 7B, and 7C according to the total operation times to cause the compression devices 7A, 7B, and 7C to operate, and suppresses restart of the operation for the stop time Th during stop, so that while the leveling of the operation times is realized, an appropriate cooling period can be secured.
In the related art or in the first and second embodiments, the continuous operation time of the compression device is obtained by multiplying the standard operation time by the coefficient set in advance; however, when the total operation times are very much different from each other, it is also considered a case where the leveling of the operation times of the compression devices is not completed until a compression device having the longest total operation time reaches maintenance time. Therefore, in a third embodiment, remaining times Tremain from the total operation times to maintenance of the compression devices each are calculated, an average remaining time Tremain_ave is calculated, and the operation times of the compression devices each are determined from a ratio between the remaining times Tremain and the average remaining time, and thus control can be performed such that the leveling of the total operation times of the compression devices is completed before the compression device having the longest total operation time reaches the maintenance time.
Specifically, first, Equation (1) is computed to calculate the remaining time Tremain to maintenance of each of the compression devices.
[Equation 1]
T
remain
=T
mnt
−T
ope (1)
Here, Tmnt is maintenance time and Tope is the operation time of the compression device.
Next, the average remaining time Tremain_ave of the entirety of the compression device system is obtained from the remaining times Tremain of the compression devices. Namely, Equation (2) is computed.
[Equation 2]
T
remain_ave
=T
remain_7A
+T
remain_7B
+T
remain_7C)/3 (2)
Here, Tremain_7A is the remaining time of the compression device 7A, Tremain_7B is the remaining time of the compression device 7B, and Tremain_7C is the remaining time of the compression device 7C.
Then, a continuous operation time Trun_long is obtained from the remaining time Tremain and the average remaining time Tremain_ave for a compression device having the shortest operation time. Namely, Equation (3) is computed.
[Equation 3]
T
run_long
=T
remain
/T
remain_ave
×k×Tc (3)
Here, Trun_long is the continuous operation time of the compression device having a short operation time, k is an acceleration coefficient, and Tc is the standard continuous operation time.
However, when the result of the computation of Equation (3) exceeds the maximum operation time assumed for the compression device, the operation time is fixed at a predetermined continuous operation time Trun_max.
Next, a continuous operation time Trun_short is obtained from the remaining time Tremain and the average remaining time Tremain_ave for a compression device having the longest operation time. The computational equation at this time is expressed as Equation (4).
[Equation 4]
T
run_short
=T
remain
/T
remain_ave
/k×Tc (4)
However, when the result of the computation of Equation (4) is smaller than the minimum operation time assumed for the compression device, in order to prevent the operation from ending in a very short time, the operation time is fixed at a predetermined continuous operation time Trun_min, so that noise and annoying sound caused by frequent rotation of the compression devices, damage to an electric circuit caused by an inrush current, or contact wear of an electromagnetic contactor is prevented.
Then, continuous operation times Trun are obtained using Equation (5) for the remaining compression devices.
[Equation 5]
T
run
=T
remain
/T
remain_ave
×Tc (5)
Then, Tc×2, Tc/2, and Tc in steps 17, 27, and 37 of
Therefore, according to the present invention, even in the operation number control for a combination of the compression devices having very much different operation times, the compression device having a short operation time can be continuously operated preferentially and for a longer time than the other compression devices, and it is possible to provide the operation number control device and a method for controlling the compression devices that can level the operation times to the maintenance times in the operation number control device for the compression devices.
In the above embodiments, whether the operation number control device 1 and the plurality of compression devices 7 are contained in one package as a product or a system in which products contained in a plurality of packages are combined is not particularly limited. Namely, the control described in the above embodiments is performed on the product including the operation number control device 1 and the plurality of compression devices 7 in one package, so that for example, when one compression device 7 is replaced due to a failure or when the compression device 7 is added to a space that is empty at the time of sale, the compression devices 7 can be operated such that the operation times of the compression devices 7 are leveled. In addition, when the compression device 7 which is a package type is newly added to an environment where one or more compression devices 7 which are a package type are already operated, or the like, the operation number control device 1 which is a package type can be introduced to cause the compression devices 7 to operate such that the operation times of the compression devices 7 are leveled.
Particularly, in the case of a system in which the operation number control device 1 and the plurality of compression devices 7 are all formed as separate products, each of the compression devices 7 includes a control substrate, but is configured to operate as described in the present embodiments according to an operation or stop signal or the like from the control circuit 2 provided in the operation number control device 1. In addition, each of the compression devices 7 may be configured to transmit a current operating status or information regarding operation time via a communication line through which a start or stop signal and the like from the operation number control device 1 are received. The operation number control device 1 may be configured to count the operation time of each of the compression devices 7 based on the premise that a user inputs the operation time of each of the compression devices 7 into the operation number control device 1 during construction of the system and each of the compression devices 1 operates according to a start or stop signal from the operation number control device 1 after the system is constructed.
Incidentally, the present invention can be adopted in a compression device system or in a package of compression devices including a plurality of compression devices such as a twin or single screw type, a reciprocating type, or a turbo type. In addition, the present invention can also be adopted in a compression device that compresses a mixed gas such as air or a compression device that compresses a single gas such as nitrogen gas or oxygen gas, as the compression device. Further, the present invention can be adopted in a system or package including a plurality of fluid machines such as chillers or pumps including the same mechanism, other than the compression device.
Incidentally, the present invention is not limited to the above-described embodiments, and includes various modification examples. For example, the above-described embodiments have been described in detail to describe the present invention in an easy-to-understand manner, and the present invention is not necessarily limited to including all the configurations described. In addition, a part of the configuration of an embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of an embodiment. In addition, other configurations can be added to, removed from, or replaced with a part of the configuration of each of the embodiments.
Number | Date | Country | Kind |
---|---|---|---|
2018-237869 | Dec 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2019/046725 | 11/29/2019 | WO | 00 |