JP6742509B2 - Liquid supply type gas compressor - Google Patents

Description

The present invention relates to a liquid-feed type gas compressor provided with a gas-liquid separator, and more particularly to a liquid-feed type gas compressor suitable for monitoring the liquid level in the gas-liquid separator.

An oil supply type air compressor, which is one of the liquid supply gas compressors, includes a compressor body, an oil separator, and an oil supply system (see, for example, Patent Document 1). The compressor body compresses air (gas) while injecting oil (liquid) into the compression chamber for the purpose of cooling the compression heat, lubricating the compression member such as the rotor and wrap, and sealing the compression chamber. The oil separator (gas-liquid separator) separates and stores oil from the compressed air (compressed gas) discharged from the compressor body. The oil supply system (liquid supply system) supplies the oil stored in the oil separator to the compressor body.

JP, 2009-85045, A

In the oil-filled air compressor described above, if the amount of oil stored in the oil separator is insufficient, that is, if the amount of oil supplied to the compressor body is insufficient, the compression performance and the like are reduced. Therefore, it is necessary to monitor the oil level in the oil separator.

Therefore, if the difference between the air pressure and the oil pressure in the oil separator is large, a method of providing a detector for detecting the pressure at a predetermined height position in the oil separator can be considered. Explaining in detail, in this method, for example, by presetting a threshold value that is intermediate between the pressure of air and the pressure of oil in the oil separator, by determining whether the pressure detected by the detector exceeds the threshold value, It is determined whether the fluid existing at a predetermined height position in the oil separator is air or oil. Thereby, it is detected whether the oil level in the oil separator is lower than the predetermined height position.

Alternatively, if there is a large difference between the temperature of the air in the oil separator and the temperature of the oil, there may be a method of providing a detector for detecting the temperature at a predetermined height position in the oil separator. Explaining in detail, in this method, for example, by presetting a threshold value that is intermediate between the temperature of air and the temperature of oil in the oil separator, by determining whether the temperature detected by the detector exceeds the threshold value, It is determined whether the fluid existing at a predetermined height position in the oil separator is air or oil. Thereby, it is detected whether the oil level in the oil separator is lower than the predetermined height position.

However, in reality, there is almost no difference between the pressure of air and the pressure of oil in the oil separator, and there is almost no difference between the temperature of air and the temperature of oil. Therefore, the detection value of the detector does not change even if the height of the oil surface in the oil separator changes. Therefore, the method described above cannot be adopted.

As still another method, it is conceivable to provide an optical detector for detecting the presence or absence of oil at a predetermined height position in the oil separator. However, in the oil separator, the oil separated from the compressed air flows down. In addition, the oil level in the oil separator may undulate. Therefore, even when the oil level in the oil separator is lower than the predetermined height position, the oil may continuously pass through or adhere to the detector, and the detector may erroneously detect. Therefore, this method cannot be adopted.

The present invention has been made in view of the above matters, and an object thereof is to monitor the liquid level height in a gas-liquid separator.

In order to solve the above-mentioned subject, the composition described in a claim is applied. The present invention includes a plurality of means for solving the above problems. To give an example thereof, a compressor main body that compresses gas while injecting a liquid into a compression chamber, and discharge from the compressor main body. In a liquid-feed type gas compressor including a gas-liquid separator that separates and stores a liquid from a compressed gas, and a liquid supply system that supplies the liquid stored in the gas-liquid separator to the compressor body, An inlet side is connected to a predetermined height position of the gas-liquid separator, a sampling pipe for flowing a fluid from a predetermined height position of the gas-liquid separator by a pressure difference between the inlet side and the outlet side, and the sampling pipe. A detector for detecting the pressure or temperature of the flowing fluid, a determination as to whether the pressure or temperature detected by the detector may exceed a preset first set value, and detection by the detector By performing at least one of the determinations as to whether the pressure or the temperature may fall below the second set value set to be smaller than the first set value in advance, the fluid flowing through the sampling pipe is A control device that determines which of a gas and a liquid is provided, and a notification device that notifies the determination result of the control device.

In addition, as another example, a compressor body that compresses a gas while injecting the liquid into the compression chamber, and a gas-liquid separator that separates and stores the liquid from the compressed gas discharged from the compressor body. In a liquid-feed type gas compressor including a liquid supply system for supplying the liquid stored in the gas-liquid separator to the compressor body, an inlet side is connected to a predetermined height position of the gas-liquid separator. A sampling pipe for flowing a fluid from a predetermined height position of the gas-liquid separator due to a pressure difference between the inlet side and the outlet side, and a downstream system connected to the outlet side of the sampling pipe on the liquid supply system. A detector for detecting the pressure or temperature of the fluid flowing upward, a determination as to whether the pressure or temperature detected by the detector may exceed a preset first set value, and detection by the detector Flow to the sampling pipe by performing at least one of determinations as to whether or not the applied pressure or temperature may fall below a second set value set to be smaller than the first set value in advance. A control device that determines whether the fluid is a gas or a liquid, and a notification device that notifies the determination result of the control device are provided.

The present invention, when the liquid is flowed through the sampling pipe, the pulsation (in other words, a large change that repeatedly increases and decreases periodically) does not occur in the pressure or temperature of the liquid, but when the gas is flowed through the sampling pipe, It is based on the knowledge that the pressure or temperature of gas pulsates, and it is possible to determine whether the fluid flowing through the sampling pipe is a gas or a liquid. Thereby, the liquid level height in the gas-liquid separator can be monitored.

Problems, configurations, and effects other than the above will be clarified by the following description.

It is a schematic diagram showing the composition of the oil supply type air compressor in a 1st embodiment of the present invention, and shows the state where the amount of oil storage in the oil separator was sufficient. It is a figure showing the state where the amount of oil storage in the oil separator in a 1st embodiment of the present invention is insufficient. It is a figure showing the time-dependent change of the detection value of the pressure sensor in a 1st embodiment of the present invention, and shows the case where oil flows into a sampling piping. It is a figure showing the time-dependent change of the detection value of the pressure sensor in a 1st embodiment of the present invention, and shows the case where air flows into a sampling piping. It is a schematic diagram showing the composition of the oil supply type air compressor in a 2nd embodiment of the present invention, and shows the state where the amount of oil storage in the oil separator is sufficient. It is a schematic diagram showing the composition of the oil supply type air compressor in a 3rd embodiment of the present invention, and shows the state where the amount of oil storage in the oil separator was sufficient. It is a figure which shows the state in which the amount of oil storage in the oil separator in the 3rd Embodiment of this invention is insufficient. It is a figure showing the time-dependent change of the detected value of the temperature sensor in a 3rd embodiment of the present invention, and shows the case where oil flows into a sampling piping. It is a figure showing the time-dependent change of the detected value of the temperature sensor in a 3rd embodiment of the present invention, and shows the case where air flows into a sampling piping. It is the schematic showing the communication terminal in the modification of this invention.

A first embodiment of the present invention will be described with reference to the drawings, taking a refueling type air compressor as an application target of the present invention.

FIG. 1 is a schematic diagram showing the configuration of the oil supply type air compressor in the present embodiment, and shows a state in which the amount of oil storage in the oil separator is sufficient. FIG. 2 is a diagram showing a state in which the oil storage amount in the oil separator according to the present embodiment is insufficient.

The refueling type air compressor of the present embodiment includes a compressor main body 1, an intake system 2 connected to the intake side of the compressor main body 1, and an oil connected to the discharge side of the compressor main body 1 via a discharge pipe 3. The separator 4 (gas-liquid separator), the compressed air supply system 5 (compressed gas supply system) connected to the upper part of the oil separator 4, and the lower part of the oil separator 4 and the compressor body 1 are connected to each other. The oil supply system 6 (liquid supply system), the control device 7, and the display device 8 are provided. The compressor body 1, the suction system 2, the discharge pipe 3, the oil separator 4, the compressed air supply system 5, the oil supply system 6, the control device 7 and the display device 8 are on the same base (base, pallet or tank). If it is a mount type, it is arranged on an air tank or the like) to form the compressor unit 9. In particular, in the present embodiment, the compressor unit 9 is configured as a casing whose peripheral surface and upper surface are surrounded by panel plates.

Although not shown in detail, the compressor body 1 has a pair of male and female screw rotors that mesh with each other and a casing that houses them, and a plurality of compression chambers are formed in the tooth spaces of the screw rotor. When the screw rotor rotates, the compression chamber moves in the axial direction of the rotor. The compression chamber sucks air (gas) from the suction system 2, compresses the air, and discharges the compressed air (compressed gas) to the discharge pipe 3. The compressor body 1 injects oil (liquid) into the compression chamber at any stage of the compression process, for example, immediately after the start of compression, for the purpose of cooling the compression heat, lubricating the rotor, and sealing the compression chamber. Has become.

The suction system 2 includes a suction filter 10 that removes impurities in the air, and a suction throttle valve 11 that is provided on the downstream side of the suction filter 10 and that can close the suction side of the compressor body 1.

The oil separator 4 separates oil from the compressed air discharged from the compressor body 1 using, for example, specific gravity separation and collision separation, and stores the separated oil in the lower part. The compressed air separated by the oil separator 4 is supplied to the destination outside the unit via the compressed air supply system 5. The compressed air supply system 5 is arranged at a pressure regulating valve (check valve) 12, a downstream side of the pressure regulating valve 12 to cool compressed air, and a downstream side of the pressure regulating valve 12 to compress the compressed air. The control pressure sensor 14 detects the pressure of air (that is, the pressure that varies depending on the amount of compressed air used). The control pressure sensor 14 outputs the detected pressure to the control device 7.

The oil stored in the oil separator 4 is supplied to the compression chamber via the oil supply system 6 due to the pressure difference between the oil separator 4 and the compression chamber of the compressor body 1. The oil supply system 6 includes an oil cooler 15 that cools oil, a bypass pipe 16 that bypasses the oil cooler 15, a temperature control valve (three-way valve) 17 provided at an inlet (branch point) of the bypass pipe 16, and a bypass. An oil filter 18 is provided downstream of the outlet (merging point) of the pipe 16 to remove impurities in the oil. The temperature control valve 17 detects the oil temperature and adjusts the ratio of the flow rate on the oil cooler 15 side to the flow rate on the bypass pipe 16 side in accordance with the oil temperature. As a result, the temperature of the oil supplied to the compressor body 1 is adjusted.

The control device 7 has an arithmetic control unit (for example, CPU) that executes arithmetic processing and control processing in cooperation with a program, a storage unit (for example, ROM, RAM) that stores the results of the program and arithmetic processing, and the like. is there. As an operation control function, the control device 7 controls the open/closed state of the suction throttle valve 11 according to the pressure detected by the control pressure sensor 14, thereby switching the operating state of the compressor body 1. The control device 7 may be wholly or partially configured as an analog circuit.

More specifically, when the compressor main body 1 is under load operation (in other words, when the suction throttle valve 11 is in the open state), the control device 7 unloads the pressure detected by the control pressure sensor 14 in advance. It is determined whether or not the pressure has increased to the starting pressure Pu. Then, when the pressure detected by the control pressure sensor 14 becomes the unload start pressure Pu, the suction throttle valve 11 is controlled to the closed state, and the compressor main body 1 is switched to the no-load operation.

When the compressor body 1 is under no-load operation (in other words, when the suction throttle valve 11 is in the closed state), the control device 7 sets the pressure detected by the control pressure sensor 14 to the preset load return pressure Pd( However, it is determined whether or not it has fallen until Pd<Pu). Then, when the pressure detected by the control pressure sensor 14 becomes the load return pressure Pd, the suction throttle valve 11 is controlled to the open state to switch to the load operation of the compressor body 1. By the above operation switching, it is possible to reduce power consumption when the amount of compressed air used decreases.

Here, as one of the features of the present embodiment, the refueling type air compressor has an inlet side at a predetermined height position H of the oil separator 4 (specifically, corresponding to a desired oil storage amount when the compressor is driven, for example). A sampling pipe 19 connected to the oil surface height position) and having an outlet side connected to the upstream side of the oil filter 18 of the oil supply system 6, and a pressure sensor 20 (detector) for detecting the pressure of the fluid flowing through the sampling pipe 19. ) And. In the present embodiment, the sampling pipe 19 has a smaller cross-sectional area than, for example, the pipe of the oil supply system 6 so that the flow rate is smaller than that of the oil supply system 6, but the present invention is not limited to this. The pressure sensor 20 outputs the detected pressure to the control device 7.

The control device 7 has an oil level height detection function when the compressor body 1 is in a load operation (in other words, when the oil level in the oil separator 4 is lower than when the compressor body 1 is in a no-load operation). , Determination as to whether the pressure detected by the pressure sensor 20 may be outside a preset setting range (in other words, determination as to whether the pressure may exceed a preset set value P1 and preset It is determined whether the fluid flowing in the sampling pipe 19 is air (or which is the main) by performing the set value P2 (provided that P2<P1) is not reached. The determination result is output to the display device 8. The display device 8 is configured to notify the determination result of the control device 7.

More specifically, as shown in FIG. 1, when the oil level in the oil separator 4 is higher than a predetermined height position H (in other words, the position where the inlet side of the sampling pipe 19 is connected), the sampling pipe 19 is The oil flows. In this case, as shown in FIG. 3, the oil pressure detected by the pressure sensor 20 is within the set range (in other words, set value P1 or less and set value P2 or more) without pulsation. Therefore, the control device 7 determines that the fluid flowing through the sampling pipe 19 is oil. Thereby, it can be detected that the oil level in the oil separator 4 is higher than the predetermined height position H.

On the other hand, as shown in FIG. 2, when the oil level in the oil separator 4 is lower than the predetermined height position H, air flows through the sampling pipe 19. In this case, as shown in FIG. 4, the pressure of the air detected by the pressure sensor 20 may pulsate and fall outside the set range (in other words, above the set value P1 or below the set value P2). .. Therefore, the control device 7 determines that the fluid flowing through the sampling pipe 19 is air. Thereby, it can be detected that the oil level in the oil separator 4 is lower than the predetermined height position H.

When the display device 8 inputs a determination result that the fluid flowing through the sampling pipe 19 is air, the display device 8 outputs, for example, “alarm: insufficient lubricating oil” or “alarm: lubricating oil” as notification information based on the determination result. Please replenish” message is displayed. Further, the display device 8 may input a determination result that the fluid flowing through the sampling pipe 19 is oil, and displays information such as “lubrication oil filling” message as information based on the determination result. Good. Note that these notification methods may be sound, vibration, or various modes in which these are combined.

As described above, in the present embodiment, when oil (liquid) flows through the sampling pipe 19, the pressure of the oil hardly pulsates, but when air (gas) flows through the sampling pipe 19, the air This is based on the knowledge that the pressure has pulsation, and it is possible to determine which (or which is the main) of the fluid flowing through the sampling pipe 19 among oil and air. Thereby, the oil level in the oil separator 4 can be accurately monitored.

In the first embodiment, the control device 7 determines whether the pressure detected by the pressure sensor 20 may be outside the set range (in other words, the pressure detected by the pressure sensor 20 is the set value. By performing both the determination as to whether P1 may be exceeded and the determination as to whether it is less than the set value P2), the fluid flowing through the sampling pipe 19 may be either air or oil (or which is the main). However, the present invention is not limited to this, and modifications can be made without departing from the spirit and technical idea of the present invention.

As a first modified example, the control device 7 performs one of the determination as to whether the pressure detected by the pressure sensor 20 may exceed the set value P1 and the determination as to whether it may fall below the set value P2. By performing the above, it may be determined which of the air and the oil (or which is the main) the fluid flowing through the sampling pipe 19. Even in such a modification, the same effect as described above can be obtained.

As a second modified example, the control device 7 determines whether the frequency at which the pressure detected by the pressure sensor 20 exceeds the set value P1 is higher than a predetermined value and the pressure detected by the pressure sensor 20 sets the set value P2. Whether or not the fluid flowing through the sampling pipe 19 is air (or which is the main) is determined by performing one or both of the determinations as to whether or not the lower frequency is greater than a predetermined value. Good. Even in such a modification, the same effect as described above can be obtained.

As a third modification, the control device 7 calculates the rate of change in the pressure detected by the pressure sensor 20 (specifically, for example, the rate of change in pressure obtained at each detection time interval of the pressure sensor 20), and By performing one or both of the determination of whether the rate of change may exceed a preset positive set value and the determination of whether it may fall below a preset negative set value, the sampling piping It may be determined whether the fluid flowing through 19 is air (or which is the main), or oil. Even in such a modification, the same effect as described above can be obtained.

A second embodiment of the present invention will be described with reference to the drawings. In this embodiment, the same parts as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted as appropriate.

FIG. 5 is a schematic diagram showing the configuration of the oil supply type compressor in the present embodiment. The main difference in configuration from the first embodiment is that the sampling pipe 19A in the second embodiment has its outlet side connected to the upstream side of the temperature control valve 17 on the oil supply system 6. Another point is that the pressure sensor 20 is arranged on the oil supply system 6 downstream of the outlet of the sampling pipe 19A (downstream of the outlet of the bypass pipe 16 in the present embodiment). That is, the second embodiment is characterized in that not the pressure pulsation of the sampling pipe 19A but the pressure pulsation generated in the oil supply system 6 by the sampling pipe 19A is detected.

More specifically, for example, when the compressor is under load operation, if the oil level position in the oil separator 4 is lower than the inlet side position of the sampling pipe 19A, the sampling pipe 19A is moved to the same position as in the first embodiment. Air flows to the oil supply system 6 via the. That is, air or oil or a mixed fluid of these flows in the bypass pipe 16 to generate pressure pulsation. Similar to the first embodiment, the pulsation change is detected by the pressure sensor 20, and the control device can detect the height of the oil surface.

If the pressure sensor 20 is on the downstream side of the outlet side connection portion of the sampling pipe 19A on the oil supply system 6, the connection configuration of the sampling pipe 19A may be the same as that of the first embodiment. ..

Even in such a second embodiment, the same effects as those of the first embodiment and its modification can be obtained. In particular, according to the present embodiment, the size of the sampling pipe 19A becomes small, and it is possible to expect effects such as simplification of the pipe configuration and reduction of member cost.

A third embodiment of the present invention will be described with reference to the drawings. In this embodiment, the same parts as those in the first and second embodiments are designated by the same reference numerals, and the description thereof will be omitted as appropriate.

FIG. 6 is a schematic diagram showing the configuration of the oil supply type air compressor in the present embodiment, and shows a state in which the amount of stored oil in the oil separator 4 is sufficient. FIG. 7: is a figure which shows the state in which the amount of oil storage in the oil separator 4 in this embodiment is insufficient.

The refueling type air compression of the present embodiment includes a temperature sensor 21 (detector) that detects the temperature of the fluid flowing in the sampling pipe 19 instead of the pressure sensor 20. The temperature sensor 21 outputs the detected temperature to the control device 7A.

As a function of detecting the oil level, the control device 7A determines whether or not the temperature detected by the temperature sensor 21 may fall outside the preset range when the compressor main body 1 is under load operation (in other words, in other words. , Sampling is performed by determining whether or not a preset setting value T1 may be exceeded and by determining whether a preset setting value T2 (below T2<T1) may be exceeded. It is configured to determine whether the fluid flowing through the pipe 19 is air or oil, and output the determination result to the display device 8.

More specifically, as shown in FIG. 6, when the oil level in the oil separator 4 is higher than the predetermined height position H, the oil flows through the sampling pipe 19. In this case, as shown in FIG. 8, the temperature of the oil detected by the temperature sensor 21 is within the set range (in other words, set value T1 or less and set value T2 or more) without pulsation. Therefore, the control device 7A determines that the fluid flowing through the sampling pipe 19 is oil. Thereby, it can be detected that the oil level in the oil separator 4 is higher than the predetermined height position H.

On the other hand, as shown in FIG. 7, when the oil level in the oil separator 4 is lower than the predetermined height position H, air flows through the sampling pipe 19. In this case, as shown in FIG. 9, the temperature of the air detected by the temperature sensor 21 pulsates and falls outside the set range (in other words, it exceeds the set value T1 or falls below the set value T2). is there. Therefore, the control device 7A determines that the fluid flowing through the sampling pipe 19 is air. Thereby, it can be detected that the oil level in the oil separator 4 is lower than the predetermined height position H.

When the display device 8 inputs a determination result that the fluid flowing in the sampling pipe 19 is air, the display device 8 provides information based on the determination result, for example, “alarm: lack of lubricating oil” or “alarm: supply of lubricating oil”. Please, please display a message etc. Further, the display device 8 may input a determination result that the fluid flowing through the sampling pipe 19 is oil, and displays information such as “lubrication oil filling” message as information based on the determination result. Good.

As described above, in the present embodiment, when oil (liquid) is flown through the sampling pipe 19, almost no pulsation occurs in the temperature of the oil, but when air (gas) is flowed through the sampling pipe 19, the air This is based on the knowledge that the temperature pulsates, and it is possible to determine which (or which is the main) of the fluid flowing through the sampling pipe 19 among the oil and the air. Thereby, the oil level in the oil separator 4 can be monitored.

In the third embodiment, the control device 7A determines whether or not the temperature detected by the temperature sensor 21 is out of the set range (in other words, the temperature detected by the temperature sensor 21 is the set value. By performing both the determination as to whether T1 may be exceeded and the determination as to whether it is less than the set value T2), the fluid flowing through the sampling pipe 19 is either air or oil (or which is the main). However, the present invention is not limited to this, and modifications can be made without departing from the spirit and technical idea of the present invention.

As a fourth modified example, the control device 7A has one of a determination as to whether the temperature detected by the temperature sensor 21 may exceed the set value T1 and a determination as to whether the temperature may fall below the set value T2. By performing the above, it may be determined which of the air and the oil (or which is the main) the fluid flowing through the sampling pipe 19. Even in such a modification, the same effect as described above can be obtained.

As a fifth modification, the control device 7A determines whether the temperature detected by the temperature sensor 21 exceeds the set value T1 more frequently than a predetermined value and the temperature detected by the temperature sensor 21 sets the set value T2. Whether or not the fluid flowing through the sampling pipe 19 is air (or which is the main) is determined by performing one or both of the determinations as to whether or not the lower frequency is greater than a predetermined value. Good. Even in such a modification, the same effect as described above can be obtained.

As a sixth modified example, the control device 7A calculates the rate of change in the temperature detected by the temperature sensor 21 (specifically, for example, the rate of temperature change obtained at each detection time interval of the temperature sensor 21), and By performing one or both of the determination as to whether the rate of change may exceed a preset positive setting value and the determination as to whether it may fall below a preset negative setting value, the sampling piping It may be determined whether the fluid flowing through 19 is air (or which is the main), or oil. Even in such a modification, the same effect as described above can be obtained.

The configuration of the second embodiment (FIG. 5) can naturally be applied to the third embodiment. That is, even if the pressure sensor 20 according to the second embodiment is replaced with the temperature sensor 21 according to the third embodiment, the same effect as that of the third embodiment can be obtained.

In addition, in the first to third embodiments and the modified examples, the notification device that notifies the determination result of the control device 7 or 7A is mounted on the compressor unit 9 and is based on the determination result of the control device 7 or 7A. The case of the display device 8 that displays information has been described as an example, but the present invention is not limited to this, and modifications can be made without departing from the spirit and technical idea of the present invention. As in the seventh modified example shown in FIG. 10, the notification device is, for example, information based on the determination result of the control device 7 or 7A which is separated from the compressor unit 9 and received via the communication line 22 (specifically, For example, the communication terminal 23 may display a message such as "alarm: lack of lubricating oil" or "alarm: supply lubricating oil" message). The communication terminal 23 may be in physical contact with the compressor unit 9 as long as the communication connection is separated from each other. For example, the communication terminal 23 may be placed or suspended at any place of the compressor unit 9 and temporarily fixed so as to be separable.

As another configuration using the communication line shown in FIG. 10, the determination function of the control device 7 or 7A is provided in an external arithmetic device (server or the like) connected via the communication line 22, and the determination result is provided to the outside. The configuration may be such that the arithmetic unit notifies the communication terminal 23 via the communication line 22. Furthermore, the communication terminal 23 may be configured to include the determination function of the control device 7 or 7A.

Although not shown, the alarm device may be, for example, an alarm lamp or an alarm buzzer mounted on the compressor unit 9. Then, the control device 7 or 7A may drive the alarm lamp or the alarm buzzer when it is determined that the fluid flowing through the sampling pipe 19 is air. Also in these modified examples, the same effect as described above can be obtained.

Further, in the first to third embodiments, the case where the outlet side of the sampling pipe 19 (19A) is connected to the upstream side of the oil filter 18 of the oil supply system 6 has been described as an example, but the present invention is not limited to this. Modifications are possible without departing from the spirit and technical idea of the present invention. That is, the sampling pipe is connected to the predetermined height position of the oil separator 4 on the inlet side, and the sampling pipe from the predetermined height position of the oil separator 4 is changed by the pressure difference between the inlet side (high pressure side) and the outlet side (low pressure side). It may be configured so that the fluid flows. Therefore, the portion to which the outlet side of the sampling pipe is connected may be lower than the pressure inside the oil separator 4 by at least the pressure loss of the sampling pipe.

In addition, in the first to third embodiments, the refueling air compressor includes the suction throttle valve 11 that closes the suction side of the compressor body 1 in order to switch the compressor body 1 from the load operation to the no-load operation. Although the case where it is provided has been described as an example, the present invention is not limited to this and can be modified without departing from the spirit and technical idea of the present invention.

In order to switch the compressor body 1 from the load operation to the no-load operation, the refueling type air compressor replaces the suction throttle valve 11 with the discharge side of the compressor body 1 (specifically, the adjustment of the compressed air supply system 5). An exhaust valve 24 (indicated by a dotted line in FIG. 1, FIG. 5, or FIG. 6) that exhausts the pressure valve 12) may be provided. Then, when the pressure detected by the control pressure sensor 14 becomes the unload start pressure Pu, the control device 7 or 7A controls the air discharge valve 24 to the open state so that the compressor main body 1 is not operated under load. Switch to load operation. Further, when the pressure detected by the control pressure sensor 14 becomes the load return pressure Pd, the air discharge valve 24 is controlled to the closed state to switch the compressor body 1 from the no-load operation to the load operation.

Alternatively, the refueling type air compressor may include both the suction throttle valve 11 and the discharge valve 24. Further, the refueling type air compressor may be configured so that the compressor body 1 is not switched from the load operation to the no-load operation. That is, the suction throttle valve 11 or the air release valve 24 may not be provided, and the control device 7 or 7A may not have the operation control function described above. Also in these modified examples, the same effect as described above can be obtained.

In the above description, the case where the present invention is applied to a refueling type air compressor has been described as an example, but the present invention is not limited to this. For example, a compressor main body that compresses air (gas) while injecting water (liquid) into the compression chamber, and a water separator that separates and stores water from the compressed air (compressed gas) discharged from the compressor main body ( The present invention may be applied to a water supply air compressor that includes a gas-liquid separator) and a water supply system (liquid supply system) that supplies water stored in the water separator to the compressor body. When the present invention is applied to this water supply type air compressor, the water surface height in the water separator can be monitored. Further, the present invention may be applied to a compressor that compresses a gas other than air.

In the above description, the compression mechanism of the so-called twin screw rotor including the male and female screw rotors has been described as an example, but the present invention is not limited to this. For example, various compression mechanisms such as positive displacement type and turbo type can be applied. The positive displacement type includes rotary type and reciprocating type, and the rotary type includes single, twin and multi screw rotors, single and multi scroll laps, vane type and claw type. The reciprocating type includes single and multiple reciprocating type. Further, the compressor main body is not limited to the one-unit configuration, and can be applied to a multi-stage configuration including combinations of the same type or different types.

DESCRIPTION OF SYMBOLS 1... Compressor main body, 4... Oil separator (gas-liquid separator), 6... Oil supply system (liquid supply system), 7, 7A... Control device, 8... Display device (informing device), 9... Compressor unit , 11... Suction throttle valve, 19, 19A... Sampling piping, 20... Pressure sensor (detector), 21... Temperature sensor (detector), 22... Communication line, 23... Communication terminal (informing device), 24... Exhalation valve

Claims (14)

A compressor body that compresses gas while injecting liquid into the compression chamber, a gas-liquid separator that separates and stores the liquid from the compressed gas discharged from the compressor body, and a gas-liquid separator In a liquid supply type gas compressor having a liquid supply system for supplying a liquid to the compressor body,
An inlet side is connected to a predetermined height position of the gas-liquid separator, a sampling pipe for flowing a fluid from a predetermined height position of the gas-liquid separator by a pressure difference between the inlet side and the outlet side,
A detector for detecting the pressure or temperature of the fluid flowing in the sampling pipe,
It is determined whether the pressure or temperature detected by the detector may exceed a preset first set value, and the pressure or temperature detected by the detector is smaller than the first set value in advance. It is determined whether the fluid flowing through the sampling pipe is a gas or a liquid by performing at least one of the determinations as to whether or not it may fall below a second set value that is set to A control device,
A liquid supply type gas compressor, comprising: an informing device that informs a determination result of the control device. The liquid feed type gas compressor according to claim 1,
The controller determines whether the pressure or temperature detected by the detector may exceed a preset first set value, and the pressure or temperature detected by the detector is preset by the first controller. It is determined whether the fluid flowing through the sampling pipe is a gas or a liquid by both determining whether or not it may fall below a second set value set to be smaller than the set value. A liquid feed type gas compressor that does. The liquid feed type gas compressor according to claim 1,
At least one of a suction throttle valve that closes the suction side of the compressor body and an air discharge valve that discharges the discharge side of the compressor body in order to switch from the load operation of the compressor body to the no-load operation. Prepare,
The control device determines whether the pressure or temperature detected by the detector may exceed a preset first set value during load operation of the compressor body, and the control device detects the detector. By performing at least one of the determinations as to whether the pressure or the temperature may fall below the second set value set to be smaller than the first set value in advance, the fluid flowing through the sampling pipe is A liquid feed type gas compressor for determining whether it is a gas or a liquid. The liquid feed type gas compressor according to claim 1,
A liquid supply type gas compressor in which an outlet side of the sampling pipe is connected to the liquid supply system. The liquid feed type gas compressor according to claim 1,
The compressor body, the gas-liquid separator and the liquid supply system constitute a compressor unit arranged on the same base,
A liquid feed type gas compressor, wherein the notification device is a display device mounted on the compressor unit and displaying information based on a determination result of the control device. The liquid feed type gas compressor according to claim 1,
The compressor body, the gas-liquid separator and the liquid supply system constitute a compressor unit arranged on the same base,
A liquid supply type gas compressor which is a communication terminal in which the notification device is separated from the compressor unit and displays information based on a determination result of the control device received through a communication line. A compressor body that compresses gas while injecting liquid into the compression chamber, a gas-liquid separator that separates and stores the liquid from the compressed gas discharged from the compressor body, and a gas-liquid separator In a liquid supply type gas compressor having a liquid supply system for supplying a liquid to the compressor body,
An inlet side is connected to a predetermined height position of the gas-liquid separator, a sampling pipe for flowing a fluid from a predetermined height position of the gas-liquid separator by a pressure difference between the inlet side and the outlet side,
On the liquid supply system, a detector for detecting the pressure or temperature of the fluid flowing on the downstream system connected to the outlet side of the sampling pipe,
It is determined whether the pressure or temperature detected by the detector may exceed a preset first set value, and the pressure or temperature detected by the detector is smaller than the first set value in advance. It is determined whether the fluid flowing through the sampling pipe is a gas or a liquid by performing at least one of the determinations as to whether or not it may fall below a second set value that is set to A control device,
A liquid supply type gas compressor, comprising: an informing device that informs a determination result of the control device. The liquid feed type gas compressor according to claim 7,
The controller determines whether the pressure or temperature detected by the detector may exceed a preset first set value, and the pressure or temperature detected by the detector is preset by the first controller. It is determined whether the fluid flowing through the sampling pipe is a gas or a liquid by both determining whether or not it may fall below a second set value set to be smaller than the set value. A liquid feed type gas compressor that does. The liquid feed type gas compressor according to claim 7,
At least one of a suction throttle valve that closes the suction side of the compressor body and an air discharge valve that discharges the discharge side of the compressor body in order to switch from the load operation of the compressor body to the no-load operation. Prepare,
The control device determines whether the pressure or temperature detected by the detector may exceed a preset first set value during load operation of the compressor body, and the control device detects the detector. By performing at least one of the determinations as to whether the pressure or the temperature may fall below the second set value set to be smaller than the first set value in advance, the fluid flowing through the sampling pipe is A liquid feed type gas compressor for determining whether it is a gas or a liquid. The liquid feed type gas compressor according to claim 7,
A liquid supply type gas compressor in which an outlet side of the sampling pipe is connected to the liquid supply system. The liquid feed type gas compressor according to claim 7,
The compressor body, the gas-liquid separator and the liquid supply system constitute a compressor unit arranged on the same base,
A liquid feed type gas compressor, wherein the notification device is a display device mounted on the compressor unit and displaying information based on a determination result of the control device. The liquid feed type gas compressor according to claim 7,
The compressor body, the gas-liquid separator and the liquid supply system constitute a compressor unit arranged on the same base,
A liquid supply type gas compressor which is a communication terminal in which the notification device separates from the compressor unit and notifies information based on a determination result of the control device received via a communication line. A compressor body that compresses gas while injecting liquid into the compression chamber, a gas-liquid separator that separates and stores the liquid from the compressed gas discharged from the compressor body, and a gas-liquid separator In a liquid supply type gas compressor having a liquid supply system for supplying a liquid to the compressor body,
An inlet side is connected to a predetermined height position of the gas-liquid separator, a sampling pipe for flowing a fluid from a predetermined height position of the gas-liquid separator by a pressure difference between the inlet side and the outlet side,
A detector for detecting the pressure or temperature of the fluid flowing in the sampling pipe or flowing in the sampling pipe,
Determining whether the frequency or the pressure detected by the detector exceeds a preset first set value more than a predetermined value, and the pressure or temperature detected by the detector is preset by the first setting. By performing at least one of determining whether the frequency of falling below the second set value set to be smaller than a value is greater than a predetermined value, the fluid flowing through the sampling pipe is either a gas or a liquid. A control device for determining whether
A liquid supply type gas compressor, comprising: an informing device that informs a determination result of the control device. A compressor body that compresses gas while injecting liquid into the compression chamber, a gas-liquid separator that separates and stores the liquid from the compressed gas discharged from the compressor body, and a gas-liquid separator In a liquid supply type gas compressor having a liquid supply system for supplying a liquid to the compressor body,
An inlet side is connected to a predetermined height position of the gas-liquid separator, a sampling pipe for flowing a fluid from a predetermined height position of the gas-liquid separator by a pressure difference between the inlet side and the outlet side,
A detector for detecting the pressure or temperature of the fluid flowing in the sampling pipe or flowing in the sampling pipe,
The change rate in the pressure or temperature detected by the detector is calculated, and it is determined whether the change rate may exceed a preset positive set value and the change rate is a preset negative set value. By performing at least one of the determination of whether or not there is less than, a control device for determining whether the fluid flowing through the sampling pipe is a gas or liquid,
A liquid supply type gas compressor, comprising: an informing device that informs a determination result of the control device.

Images