1. Field of the Invention
The present invention relates to a compression apparatus.
2. Description of the Related Art
A compression apparatus which compresses a gas, is configured to store a compressor and incidental devices such as an aftercooler in a package (housing), and includes a fan for cooling the respective devices is widely used. In this compression apparatus, a single fan cools not only the compressor but also an intercooler and the aftercooler (refer to Japanese Patent Nos. 3773443 and 4418321).
In a compression apparatus for cooling multiple devices by using a single fan, a fan having a large capacity is often provided in order to sufficiently cool all the devices even under the worst condition. Moreover, if the fan having a large capacity is operated at the maximum capacity in order to sufficiently cool all the devices, there poses a problem that power consumption increases. Further, the operation of the fan having a large capacity increases noise.
The present invention has been made in view of the above-mentioned problems, and therefore has an object to provide a compression apparatus for cooling multiple devices using a single fan with a small amount of electric power consumed by the fan.
In order to solve the problems, the compression apparatus according to the present invention includes: a compressor, multiple temperature detectors that are provided at different locations, a cooling fan that is capable of changing a rotation speed, and fan control means that determines the rotation speed of the cooling fan based on detected values by the multiple temperature detectors; in which the fan control means sets, in advance, an upper limit temperature and a control gain to each of the multiple temperature detectors, calculates a difference between the detected value and the upper limit temperature for each of the multiple temperature detectors, and determines the rotation speed of the fan based on the smallest value in the differences and the control gain set to the temperature detector having the smallest difference.
According to this configuration, since the rotation speed of the fan is adjusted according to a portion most requiring cooling, a cooling capability of the fan is optimized and electric power consumption can be reduced to the minimum.
The compression apparatus configured as mentioned before may include a suction adjustment valve that is provided in an intake channel for supplying the compressor with a gas, a pressure detector that detects a discharge pressure of a compressed gas, and valve control means that opens/closes the suction adjustment valve according to the detected value by the pressure detector; in which the control gain may include a first gain applied in a case in which the suction adjustment valve is opened, and a second gain applied in a case in which the suction adjustment valve is closed.
According to this configuration, the cooling capability of the fan can further be optimized according to the closing/opening of the suction adjustment valve.
In the compression apparatus configured as mentioned before, each of the control gains may include a plurality of constants.
According to this configuration, for example, feedback control using complex functions such as the PID control can be carried out.
The compression apparatus configured as mentioned before may include a plurality of the compressor, in which the compressors may serially be connected with each other, and at least one of the temperature detectors may be disposed in a channel between the compressors. Further, an intercooler may be provided in the channel between the compressors, at least one of the temperature detectors may be provided on an upstream side of the intercooler, and at least one of the temperature detectors may be provided on a downstream side of the intercooler.
According to this configuration, a cooling capability of a two-stage compressor can be optimized.
In the compression apparatus configured as mentioned before, an aftercooler may be provided on a discharge side of the compressor, at least one of the temperature detectors may be provided on an upstream side of the aftercooler, and at least one of the temperature detectors may be provided on a downstream side of the aftercooler.
This configuration can further increase the cooling capability.
In the accompanying drawing,
A description will now be given of an embodiment of the present invention referring to the drawing.
A suction filter 4 and a suction adjustment valve 5 are provided in an intake channel 3 for supplying the first compressor 1 with air. An intercooler 7, a first temperature detector 8 for detecting a temperature of air discharged by the first compressor 1 in the upstream of the intercooler 7, and a second temperature detector 9 for detecting a temperature of air supplied to the second compressor 2 in the downstream of the intercooler 7 are provided in an intermediate channel 6 connecting the first compressor 1 and the second compressor 2 with each other. In a discharge channel 10 for supplying a destination requiring the compressed air with the compressed air from the second compressor 2, an aftercooler 11, a third temperature detector 12 for detecting a temperature of air discharged by the second compressor in the upstream of the aftercooler 11, a fourth temperature detector 13 for detecting a temperature of air discharged into a channel leading to the destination in the downstream of the aftercooler 11, and a discharge pressure detector 14 for detecting a pressure of air discharged in the downstream of the aftercooler 11 are provided. In other words, multiple temperature detectors (the first to fourth temperature detectors 8, 9, 12, and 13) are provided at different locations.
The compression apparatus according to this embodiment includes a fan 15 for cooling the above-mentioned components, particularly the first compressor 1, the second compressor 2, the intercooler 7, and the aftercooler 11. A rotation speed of a motor 16 for driving the fan 15 is set by an inverter 17.
Moreover, the compression apparatus according to this embodiment further includes: a valve control device 18 (valve control means) which opens/closes the suction adjustment valve 5 based on a detected value Pd of the discharge pressure detector 14; and a fan control device 19 (fan control means) to which detected values by the first to fourth temperature detectors 8, 9, 12, and 13 and an output signal of the valve control device 18 are input, and which sets a frequency of the inverter 17, namely a rotation speed of the fan 15.
An upper limit pressure PdH and a lower limit pressure PdL are set to the valve control device 18. If the detected value Pd by the discharge pressure detector 14 becomes equal to or more than the upper limit pressure PdH, the valve control device 18 closes the suction adjustment valve 5, and if the detected value Pd by the discharge pressure detector 14 becomes equal to or less than the lower limit pressure PdL, the valve control device 18 opens the suction adjustment valve 5. The fan control device 19 stores in a built-in memory, as shown in Table 1 for example, upper limit temperatures (T1h, T2h, T3h, and T4h) for the respective detected values (T1, T2, T3, and T4) by the first to fourth temperature detectors 8, 9, 12, and 13, and gains (constants) used to feed back the detected values (T1, T2, T3, and T4) by the first to fourth temperature detectors 8, 9, 12, and 13 for controlling the rotation speed of the fan 15. Two types of gains, that is, first gains (G1, G2, G3, and G4) to be applied when the suction adjustment valve 5 is opened, and second gains (g1, g2, g3, and g4) to be applied when the suction adjustment valves 5 are closed are stored for the respective temperature detectors 8, 9, 12, and 13. The “upper limit temperature” can be referred to as so-called “target value” in the feedback described later. Therefore, in practice, the temperatures of the respective locations can temporarily exceed the “upper limit temperature”.
The fan control device 19 checks the detected values (T1, T2, T3, and T4) for the respective first to fourth temperature detectors 8, 9, 12, and 13 every predetermined cycle time, and calculates differences (T1h−T1, T2h−T2, T3h−T3, and T4h−T4) between the upper limit temperatures and the detected values, respectively. Then, if the cycle time is considered as a unit and the present time is denoted by n, the fan control device 19 sets a difference having the smallest value in the multiple differences as a representative difference ΔTr(n) at that time point, and sets the gain set to the temperature detector having the smallest difference as a representative gain Gr(n) at that time point. For example, if the second temperature detector 9 has the smallest difference, the representative gain Gr(n) is G2 if the suction adjustment valve 5 is opened at the time n, and is g2 if the suction adjustment valve 5 is closed.
If a set frequency by the inverter 17 at the time n is denoted by X(n), the fan control device 19 sets a value obtained by subtracting a value obtained by multiplying the representative difference ΔTr(n) at the time n by the representative gain Gr(n) from the set frequency X(n) at the time n as a set frequency X(n+1) at a time n+1.
X(n+1)=X(n)−Gr(n)*ΔTr(n)
In this way, only the temperature of a temperature detector closest to the upper limit temperature in the first to fourth temperature detectors 8, 9, 12, and 13, namely the temperature having the least margin is used as a control input for negative feedback, and thereby the rotation speed of the fan 15 is proportionally controlled, according to this embodiment. As a result, in a state where any one of the detected values by the first to fourth temperature detectors 8, 9, 12, and 13 does not exceed the upper limit value with as much effort as possible, the rotation speed of the fan 15 is suppressed to as low as possible and thereby power consumption and noise are reduced.
It should be noted that the reason why the second gains of the third and fourth temperature detectors 12 and 13 are “0” in Table 1 is that, if the suction adjustment valve 5 is closed, a load on the first compressor 1 increases, a temperature of the intermediate channel 6 increases and thus the differences of the third and fourth temperature detectors 12 and 13 (T3h−T3 and T4h−T 4) will not be smaller than the differences of the first and second temperature detectors 8 and 9 (T1h−T1 and T2h−T2), so that it is not necessary to set constants for the feedback.
Moreover, the fan control device 19 may receive the representative difference ΔTr(n) as a control input and carry out the PID control on the rotation speed of the fan 15. In this case, each of the first gain and the second gain contains three constants, that is, a proportional constant, an integral constant, and a differential constant, as shown in Table 2. For example, for the first gain for the first temperature detector 8, the proportional constant is G1, the integral constant is G1i, and the differential constant is G1d.
Although according to this embodiment, temperatures of the air in the intermediate channel 6 and the discharge channel 10 are detected as control inputs, temperatures of the first compressor 1, the second compressor 2, the intercooler 7, the aftercooler 11, the motor, and the like, or portions tending to generate heat in the device may be detected as control inputs. For example, an oil temperature and the like in an oil cooling device for an oil cooled compressor may be detected as a control input.
Although according to this embodiment, the opening/closing control is provided for the suction adjustment valve 5, and the first gain and the second gain are selectively used according to the opening/closing of the suction valve 5, the same gain may be used regardless of opening/closing of the suction adjustment valve 5. In other words, one gain (or one set of gains) is used for each of the temperature detectors. Alternatively, one gain (or one set of gains) may be used for each of the temperature detectors for a device configuration without the suction adjustment valve 5.
Although according to this embodiment, the valve which is switched between two states, that is, the open state and the closed state is used as the suction adjustment valve 5, a valve which is capable of continuously varying its opening degree may be used as the suction adjustment valve 5. In this case, a gain (first gain) used when the suction adjustment valve 5 is fully opened and a gain (second gain) used when the suction adjustment valve 5 is fully closed may be stored, and for an intermediate opening degree therebetween, a gain obtained by interpolating between the first gain and the second gain according to the opening degree may be used.
Although the difference and the gain only for the temperature detector having the smallest difference from the upper limit are used in calculation for the fan control according to this embodiment, the difference and the gain of the temperature detector having the second smallest difference from the upper limit and the subsequent temperature detectors in an ascending order of the difference from the upper limit may properly be added to the calculation, in addition to that of the temperature detector having the smallest difference from the upper limit.
The present invention can widely be applied to a compression apparatus for producing a compressed air as well as a compression apparatus for compressing a gas other than air.
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2011-251440 | Nov 2011 | JP | national |
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