JP5491586B2 - Performance evaluation system and performance evaluation method for air compressor - Google Patents

Description

  The present invention relates to a performance evaluation system and a performance evaluation method for an air compressor.

Although air compressors are evaluated for performance at the time of shipment from the manufacturer, once the air compressor is installed at a site such as a factory and the air compressor enters an operating state, continuous performance evaluation tests are rarely performed.
However, in recent years, the importance of energy saving has been emphasized, and continuous performance evaluation is desired from the viewpoint of whether or not the performance of the air compressor has deteriorated.
As a performance evaluation method of a conventional air compressor, there is a method shown in the following non-patent literature, which includes a pressure change, a charging time, and air when charging an air tank connected to the air compressor. The temperature change in the tank was measured, the discharge capacity of the air compressor was calculated, and the performance of the air compressor was evaluated.

JIS B8341 positive displacement compressor-test and inspection method Annex JA (normative) Test method for air tank filling compressor and small compressor with shaft power of 11 kW or less JA. 3.1.4 Average amount of discharged air and amount of discharged air by air tank filling test

In the air compressor performance evaluation method disclosed in Non-Patent Document 1, it is necessary to accurately measure the average temperature in the air tank connected to the air compressor.
However, temperature measurement in the air tank is difficult to measure the average temperature accurately due to the response speed to temperature changes and the occurrence of temperature distribution in the air tank. It was unsuitable for measurement.
As another air compressor performance evaluation method, there is a method of installing an air flow meter and measuring the discharge flow rate of the air compressor with the air flow meter. However, in this method, it is necessary to install an air flow meter, and the air flow meter is expensive and poor in durability, so that it is difficult to adopt.

The present invention provides an air compressor performance evaluation system and a performance evaluation method that do not require an air flow meter, do not require temperature measurement in the air tank, and are capable of evaluating the performance of the air compressor at a low cost. In order to achieve at least a part of this purpose, the following measures were taken.
The present invention is a performance evaluation system for obtaining a discharge flow rate of compressed air discharged from an air compressor installed at a use site, and evaluating a deterioration state of the air compressor,
An air tank connected to the air compressor via an inlet side valve and having a known volume filled with compressed air from the air compressor;
Pressure measuring means for measuring the pressure in the air tank;
An outlet side valve provided at the outlet of the air tank and time measuring means for measuring time;
An evaluation means for evaluating the performance of the air compressor;
With
The pre-charging pressure in the air tank in a state where the outlet valve before the air compressor operation measured by the pressure measuring means is closed ;
When the air tank reaches a target pressure due to the operation of the air compressor, the valve on the inlet side is closed to close the air tank, and the temperature in the air tank is changed to the temperature before charging by heat exchange with the outside. After waiting until the pressure drop that occurs while the temperature reaches is converged, the post-charging pressure in the air tank measured by the pressure measuring means ,
A start time at the start of operation of the air compressor measured by the time measurement means, and an end time when the inside of the air tank reaches a target pressure and the inlet valve is closed, which is measured by the time measurement means. , on the basis of,
Without measuring the temperature change in the air tank, the discharge flow rate of the air compressor installed at the site of use is determined according to the pressure change when pressurizing the air tank and the time required to charge the air tank. calculated by the following equation and summarized in that the performance of the air compressor is configured to evaluate at the evaluation unit.
G = (V ₁ + V ₂ ) × (P ₁ −P ₀ ) /0.1013×60/ (t ₁ −t ₀ ) [m ³ / min]
G [m ³ / min]: Average discharge flow rate converted to the suction state
V ₁ [m ³ ]: Volume between the air tank inlet side valve and the air tank outlet side valve
V ₂ [m ³ ]: Volume between the air compressor outlet and the air tank inlet side valve
P ₀ [MPa]: Air tank pressure before charging
P ₁ [MPa]: Air tank pressure after charging
t ₀ [sec]: Charging start time
t ₁ [sec]: Charging end time

In the performance evaluation system for an air compressor of the present invention, the pre-charging pressure and the post-charging pressure of an air tank with a known volume, and the time of starting and ending charging of the air tank are measured. the pressure changes and the time required for pressurizing, the flow rate of the compressed air discharged from the air compressor is calculated using the above equation, it is possible to evaluate the ejection performance of the air compressor, generally air It is possible to calculate the discharge flow rate of the air compressor using existing equipment such as air tanks, pressure gauges, valves, etc. provided as ancillary equipment in the compressor, and it is necessary to install an expensive air flow meter It is not necessary to measure the temperature in the air tank, and it can be used as a cost-effective performance evaluation system. By comparing the calculated discharge flow rate of the air compressor with the rated value, the status of air compressor deterioration can be grasped. Can be air It is possible to carry out maintenance of the compressor in a proper timing, in which energy saving, saving cost is realized.

The performance evaluation method of the air compressor of the present invention is
(A) For an air tank of known volume that is provided with a valve on each of the inlet side and the outlet side and connected to the air compressor, the pressure in the air tank is measured with the outlet side valve closed,
(B) The air compressor is operated to fill the air tank with compressed air and pressurization of the air tank is started.
(C) When the pressure in the air tank reaches the target pressure, the valve on the inlet side is closed to stop timing, and the air compressor is stopped,
; (D) the air tank in a state of Shimeki', after waiting until the pressure drop that occurs during the temperature inside the air tank by heat exchange with the outside is to charge and generously temperature converges, air tank Measure the pressure of
(E) Pressure change obtained by the pre-charging pressure in the air tank measured in (a) and the post-charging pressure in the air tank measured in (d), and (b) and (c) ), The discharge flow rate of the air compressor is calculated by the following formula without measuring the temperature change in the air tank , based on the time required for charging the air tank obtained by timing The gist is to evaluate the discharge capacity of the air compressor.
G = (V ₁ + V ₂ ) × (P ₁ −P ₀ ) /0.1013×60/ (t ₁ −t ₀ ) [m ³ / min]
G [m ³ / min]: Average discharge flow rate converted to the suction state
V ₁ [m ³ ]: Volume between the air tank inlet side valve and the air tank outlet side valve
V ₂ [m ³ ]: Volume between the air compressor outlet and the air tank inlet side valve
P ₀ [MPa]: Air tank pressure before charging
P ₁ [MPa]: Air tank pressure after charging
t ₀ [sec]: Charging start time
t ₁ [sec]: Charging end time

The air compressor performance evaluation method of the present invention does not require an air flow meter, does not require temperature measurement in the air tank, and uses existing equipment provided as ancillary equipment for the air compressor. , the flow rate of the compressed air discharged from the air compressor, that the pressure change time required to pressurize the air reservoir is calculated using the above equation, to accurately evaluate the discharge capacity of the air compressor Thus, it is possible to grasp the state of deterioration of the air compressor at a low cost and perform maintenance or the like at an appropriate time.

It is a schematic block diagram of the performance evaluation system of an air compressor.

Next, the form for implementing this invention is demonstrated using an Example.
FIG. 1 is a schematic configuration diagram illustrating an example of a performance evaluation system for an air compressor. This system uses an existing incidental facility of an air compressor and is configured to be incorporated into an existing control system as an additional function. Is illustrated.

An air tank 3 is connected to an air compressor 1 installed at a site such as a factory via a valve 2 on the inlet side, and the volume of the air tank 3 is known.
The air tank 3 is provided with a pressure gauge 5 for measuring the pressure in the air tank 3, and an outlet side valve 4 is provided in a pipe communicating from the air tank 3 to a load facility on site. Yes. The air tank 3, the pressure gauge 5, and the valves 2 and 4 are provided on site as incidental facilities for the air compressor 1. In addition, a silencer 12, a dryer 13, and a filter 14 including an air discharge valve 11 are provided in a pipe from the air compressor 1 to the valve 2 on the inlet side.

In addition, a control panel 6 including a control unit 7 for controlling the air compressor 1 is provided. In the control panel 6, a measurement unit 8, an evaluation unit 9, and an additional function of the control system of the air compressor 1 are provided. A display unit 10 is incorporated.
That is, the performance evaluation system of the air compressor 1 is realized by using the existing equipment and incorporating the performance evaluation system as an additional function in the control system of the air compressor 1. In addition, an expensive air flow meter does not need to be installed, and is an economical system.

A method for evaluating the performance of the air compressor using such a performance evaluation system will be described below.
Note that the performance evaluation of the air compressor can be automatically performed after the air compressor 1 is stopped or after a holiday.
When performing the performance evaluation, the valve 4 on the outlet side is closed via the control unit 7 so that air does not flow from the air tank 3 to the load equipment side, and the pressure before charging in the air tank 3 is a pressure gauge. 5 is measured. The pressure detection signal from the pressure gauge 5 is input to the measurement unit 8 of the control panel 6.

Next, the air compressor 1 is operated via the control unit 7, the compressed air is charged from the air compressor 1 into the air tank 3, and pressurization of the air tank 3 is started. At the start of pressurization, time measurement is started by a time measuring means (timer) provided in the measuring unit 8.
When the pressure in the air tank 3 reaches a predetermined target pressure, the valve 2 on the inlet side is closed, the time measurement by the time measuring means (timer) is ended, and the air compressor 1 is stopped.
In this state, it waits until the pressure drop of the air tank 3 converges, and after the pressure change converges, the pressure in the air tank 3 is measured by the pressure gauge 5, and the detection signal from the pressure gauge 5 is the control panel 6 The pressure after the air tank 3 is charged is measured.
As described above, the measurement data measured by the measurement unit 8 is sent to the evaluation unit 9.

The evaluation unit 9 stores in advance the following formula 1 and a performance evaluation program for evaluating the performance of the air compressor 1 based on the measurement data.
G = (V ₁ + V ₂ ) × (P ₁ −P ₀ ) /0.1013×60/ (t ₁ −t ₀ ) [m ³ / min] Equation 1
G [m ³ / min]: Average discharge flow rate converted to the suction state V ₁ [m ³ ]: Volume between the air tank inlet side valve 2 and the air tank outlet side valve 4 V ₂ [m ³ ]: Air compression Volume P ₀ [MPa]: Air tank internal pressure P ₁ [MPa]: Post-charging air tank internal pressure t ₀ [sec]: Start of charging Time t ₁ [sec]: Charging end time Based on Equation 1, the discharge flow rate of the air compressor 1 is calculated in the evaluation unit 9.

When the air tank 3 is filled, the internal temperature rises, and if this is not corrected, an error will occur in the calculation result of the discharge flow rate, and temperature measurement is required to perform temperature correction. In the performance evaluation system, in order to eliminate errors without performing temperature measurement, after the air tank 3 is filled, the valve 2 on the inlet side is closed to close the air tank 3, and heat from the outside After waiting until the temperature inside the air tank 3 becomes equal to the temperature before charging by replacement, an error due to a temperature change is avoided by measuring the pressure in the air tank 3. Here, as a method of grasping the temperature change, the pressure gauge 5 is used without using the thermometer.
Specifically, since the pressure changes while the temperature changes, the pressure in the air tank 3 is measured after the pressure change has converged, and thereby the discharge flow rate of the air compressor 1 is expressed by Equation 1. Calculate from

Note that the piping from the outlet of the air compressor 1 to the inlet of the air tank 3 has a volume, and when ancillary facilities such as a dryer 13 and a filter 14 are provided, the ancillary facilities also have a volume inside. Have. Similarly, the piping from the outlet of the air tank 3 to the valve 4 on the outlet side also has a volume.
Therefore V ₁ the volume between the air tank inlet side of the valve 2 and the air tank outlet side of the valve _4, the equation 1 is satisfied the volume between the air compressor 1 to the valve 2 in the air tank inlet side as V ₂ doing.
Here, since the volume V ₁ needs to be known, the inlet side valve 2 and the outlet side valve 4 of the air tank are installed as close as possible to the air tank 3, and the air tank 3 and the valves 2, 4 are connected to each other. It is desirable that there is no unknown volume in between.

The volume V ₂ can be obtained from the inner diameter and length if only the pipe is used, but the internal volumes of the dryer 13 and the filter 14 are not generally disclosed and are difficult to grasp. is there.
If V ₂ is known, the value may be used, but it is also possible to measure V ₂ by the following procedure.
(1) The air tank 3 with the outlet side valve 4 closed is charged to a set pressure, and the inlet side valve 2 is closed.
(2) The air compressor 1 is stopped.
(3) The air release valve 11 provided between the outlet of the air compressor 1 and the air tank inlet valve 2 is opened, and the pressure in the pipe is set to atmospheric pressure. After the atmospheric pressure is reached, the air release valve 11 is closed.
(4) Wait until the change in pressure in the air tank 3 converges, and measure the pressure (P ₀ ).
(5) Open the air tank inlet side valve 2.
(6) Wait until the change in pressure in the air tank 3 converges and measure the pressure (P ₁ ).
(7) determining the _{V 2} by the following equation.
_{V 2 = V 1 × (P} 0 -P 1) / P 1 [m 3]

Note that when the operation is started when the air compressor 1 is stopped for a long time and the temperature of the air compressor 1 is about the same as the ambient temperature, the discharge flow rate gradually decreases immediately after the operation is started and becomes constant thereafter. That is, due to the structure of the air compressor 1, when the temperature of the compressor portion increases, leakage from the high pressure side to the low pressure side occurs during compression inside the device, and the discharge flow rate decreases.
The following countermeasures can be considered for the change in the discharge flow rate due to the temperature of the air compressor 1.
Countermeasure plan 1: Set a time for the device to sufficiently warm up, and measure the air compressor 1 after operating the time in advance.
Countermeasure 2: Measure the temperature inside the device or the discharge temperature of the air, and start measuring after the temperature change converges.
Countermeasure plan 3: Repeat the measurement operation continuously until the difference between the previous measurement result and the current measurement result falls within a certain range.

After calculating the discharge flow rate of the air compressor 1 according to Equation 1, the performance evaluation program in the evaluation unit 9 is executed to perform a comparative evaluation with the manufacturer's rated value of the air compressor 1, and the performance of the air compressor 1 is Be evaluated. The performance evaluated by the evaluation unit 9 is displayed on the display unit 10 and the measurement data is also displayed. Measurement data and performance evaluation results are recorded in a memory (not shown) of the evaluation unit 9.
By performing the performance evaluation intermittently, it is possible to grasp the deterioration state of the air compressor 1 and to perform maintenance of the air compressor 1 at an appropriate time.

  Thus, in the performance evaluation system of this example, the discharge capacity (discharge flow rate) of the air compressor 1 can be obtained from the pressure change and the required time when the air tank 3 is pressurized, and the state of deterioration can be grasped. .

  In addition, in the Example, although what automated the performance evaluation of the air compressor 1 is illustrated, it is not restricted to this, The air tank 3, the pressure gauge 5, valve 2, 4 as an incidental installation of the air compressor 1 It is also possible to evaluate the state of deterioration of the air compressor 1 by obtaining the discharge flow rate of the air compressor 1 by operating.

  In the embodiment, the performance of one air compressor is evaluated. However, even when a plurality of air compressors 1 are installed in parallel with respect to one air tank 3, one unit at a time. By performing the test, the discharge flow rate can be obtained for any of the air compressors 1 and performance evaluation can be performed.

DESCRIPTION OF SYMBOLS 1 Air compressor 2 Inlet side valve 3 Air tank 4 Outlet side valve 5 Pressure gauge 6 Control panel 7 Control part 8 Measurement part 9 Evaluation part 10 Display part

Claims (2)

A performance evaluation system that evaluates the state of deterioration of the air compressor by obtaining a discharge flow rate of compressed air discharged from an air compressor installed at a use site,
An air tank connected to the air compressor via an inlet side valve and having a known volume filled with compressed air from the air compressor;
Pressure measuring means for measuring the pressure in the air tank;
An outlet side valve provided at the outlet of the air tank and time measuring means for measuring time;
An evaluation means for evaluating the performance of the air compressor;
With
The pre-charging pressure in the air tank in a state where the outlet valve before the air compressor operation measured by the pressure measuring means is closed ;
When the air tank reaches a target pressure due to the operation of the air compressor, the valve on the inlet side is closed to close the air tank, and the temperature in the air tank is changed to the temperature before charging by heat exchange with the outside. After waiting until the pressure drop that occurs while the temperature reaches is converged, the post-charging pressure in the air tank measured by the pressure measuring means ,
A start time at the start of operation of the air compressor measured by the time measurement means, and an end time when the inside of the air tank reaches a target pressure and the inlet valve is closed, which is measured by the time measurement means. , on the basis of,
Without measuring the temperature change in the air tank, the discharge flow rate of the air compressor installed at the site of use is determined according to the pressure change when pressurizing the air tank and the time required to charge the air tank. performance evaluation system of the air compressor, characterized by being configured to evaluate the following the evaluation means to the performance of the air compressor calculated by formula.
G = (V ₁ + V ₂ ) × (P ₁ −P ₀ ) /0.1013×60/ (t ₁ −t ₀ ) [m ³ / min]
G [m ³ / min]: Average discharge flow rate converted to the suction state
V ₁ [m ³ ]: Volume between the air tank inlet side valve and the air tank outlet side valve
V ₂ [m ³ ]: Volume between the air compressor outlet and the air tank inlet side valve
P ₀ [MPa]: Air tank pressure before charging
P ₁ [MPa]: Air tank pressure after charging
t ₀ [sec]: Charging start time
t ₁ [sec]: Charging end time (A) For an air tank of known volume that is provided with a valve on each of the inlet side and the outlet side and connected to the air compressor, the pressure in the air tank is measured with the outlet side valve closed,
(B) The air compressor is operated to fill the air tank with compressed air and pressurization of the air tank is started.
(C) When the pressure in the air tank reaches the target pressure, the valve on the inlet side is closed to stop timing, and the air compressor is stopped,
; (D) the air tank in a state of Shimeki', after waiting until the pressure drop that occurs during the temperature inside the air tank by heat exchange with the outside is to charge and generously temperature converges, air tank Measure the pressure of
(E) Pressure change obtained by the pre-charging pressure in the air tank measured in (a) and the post-charging pressure in the air tank measured in (d), and (b) and (c) ), The discharge flow rate of the air compressor is calculated by the following formula without measuring the temperature change in the air tank , based on the time required for charging the air tank obtained by timing A method for evaluating the performance of an air compressor, comprising evaluating the discharge capacity of the air compressor.
G = (V ₁ + V ₂ ) × (P ₁ −P ₀ ) /0.1013×60/ (t ₁ −t ₀ ) [m ³ / min]
G [m ³ / min]: Average discharge flow rate converted to the suction state
V ₁ [m ³ ]: Volume between the air tank inlet side valve and the air tank outlet side valve
V ₂ [m ³ ]: Volume between the air compressor outlet and the air tank inlet side valve
P ₀ [MPa]: Air tank pressure before charging
P ₁ [MPa]: Air tank pressure after charging
t ₀ [sec]: Charging start time
t ₁ [sec]: Charging end time

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