JP6533196B2 - Gas compressor - Google Patents

Description

  The present invention relates to a gas compressor, and more particularly to a gas compressor having an exhaust heat recovery heat exchanger.

Of the energy consumed by the entire factory, the total energy consumed by gas compressors such as air compressors is said to correspond to 20 to 25%, and the effect of recovering the exhaust heat from the gas compressor is large. In particular, it is expected that the use of exhaust heat from the gas compressor will be emphasized more in the future, even for the purpose of achieving the reduction target of CO ₂ emission starting from the global warming problem.

  The gas compressor includes a compressor body that compresses a gas such as air, a cooling system that absorbs heat generated by compression, a motor that is a driving force source of the compressor, and the like. Further, in the gas compressor, assuming that the motor input power is 100%, the amount of heat absorbed in the cooling system corresponds to 90% or more of that, and the amount of heat is usually released to the outside air, Energy is emitted to the atmosphere. In order to reduce the amount of waste heat, high efficiency is being promoted for the compressor body and the motor, but the effect is limited to several percent, and effective use of the exhaust heat from the gas compressor is required.

  Regarding effective utilization of exhaust heat from gas compressors, there are cases such as utilization for heating, utilization of hot water, and utilization for water supply preheating of boilers.

  In addition, as a prior art of this kind, there are those described in Japanese Patent No. 4329875 (Patent Document 1) and Japanese Patent Application Laid-Open No. 2012-67743 (Patent Document 2).

The above Patent Document 1 uses steam to drive the compressor and uses the heat generated by the compressor for preheating water supplied to the boiler (water supply) to reduce energy consumption in the boiler. It is something like that.
The thing of the said patent document 2 equips the oil-cooling-type gas compressor with the exhaust heat recovery heat exchanger, cools a compressor, and enables exhaust heat recovery from the oil etc. which were heated.

Patent No. 4329875 JP, 2012-77743, A

  In the thing of the above-mentioned patent documents 1, heat generated with an air compressor is used as feed water preheating of a boiler, it has one water cooling cooling system as a cooling system of an air compressor, and is generated with an air compressor Heat is absorbed by the water of the water-cooled cooling system, whereby the temperature-increased water is mixed with the feed water to the boiler to raise the temperature of the boiler feed water and reduce the energy consumption in the boiler .

  In the case of this patent document 1, although the temperature of the replenishing water to the feed tank can be raised by the heat generated by the air compressor, the temperature of the replenishing water is also air compression even under the condition that the water amount is reduced to the limit. The temperature is several tens of degrees lower than the discharge temperature of the machine. In addition, as the load factor of the compressor is lower, the temperature of the makeup water is lower.

  Therefore, the exhaust heat recovery system as described in Patent Document 1 can be used for a system where it is sufficient to simply raise the temperature of water such as makeup water using compressor exhaust heat, but for hot water to be supplied There is a problem that hot water of the required temperature can not be supplied when there is a required lower limit temperature or when the lower limit of the required temperature is only a few degrees lower than the compressor discharge temperature. In addition, there is also a problem that when the amount of water is reduced in order to raise the temperature of makeup water, the heat exchange rate becomes worse.

  In the above-mentioned Patent Document 2, the exhaust heat recovery heat exchanger performs heat exchange between the high temperature oil flowing through the oil pipe and the high temperature compressed air flowing through the gas pipe, and the cooling water from the exhaust heat recovery device, and is cooled. Although water is heated, consideration is given to heat radiation from the exhaust heat recovery heat exchanger in unloading operation (no-load operation) of the oil-cooled gas compressor and in the case of stopping. Not. For this reason, when the cooling water (hot water) temperature of the exhaust heat recovery device is high, heat release from the exhaust heat recovery device occurs at the time of unloading operation or stop of the oil-cooled gas compressor, and the exhaust heat recovery rate There is a problem of getting worse.

  The object of the present invention is to supply warm water having a required temperature even when the compressor load factor is low, and to suppress the heat radiation from the waste heat recovery equipment side to improve the waste heat recovery rate. It is about obtaining a gas compressor.

In order to solve the above-mentioned problems, the present invention comprises a compressor body, a gas pipe for sending compressed gas discharged from the compressor body to a demand end, and an exhaust for recovering heat from the compressed gas flowing through the gas pipe. A heat recovery heat exchanger, and a heat medium is transferred to the exhaust heat recovery heat exchanger in order to transfer the heat received by the exhaust heat recovery heat exchanger to the outside of the gas compressor; A circulating circuit for circulating the gas to the outside of the gas compressor, and a temperature of the compressed gas heat-exchanged by the exhaust heat recovery heat exchanger exchanges heat with the heat medium or the heat medium when the hot water temperature below or even more than a predetermined temperature lower being provided with a control to the control device so as to reduce its rotational speed or stops the circulation pump.

  According to the present invention, even when the compressor load factor is low, it is possible to supply hot water of the required temperature, and it is possible to improve the exhaust heat recovery rate by suppressing the heat radiation from the exhaust heat recovery equipment side. A gas compressor can be obtained.

It is a systematic diagram showing Example 1 of an exhaust heat recovery system using a gas compressor of the present invention. In the system shown in FIG. 1, when the compressed gas temperature discharged from the compressor main body is 100 ° C., and the cooling water is passed through the exhaust heat recovery heat exchanger only once, the amount of cooling water and the cooling water passed through It is a graph which shows a relation with exhaust heat recovery heat exchanger outlet side temperature. In the system shown in FIG. 1, when the compressed gas temperature discharged from the compressor main body is 100 ° C., and the cooling water is passed through the exhaust heat recovery heat exchanger only once, the amount of cooling water and the cooling water passed through It is a graph which shows a relation with exhaust heat recovery rate by. It is a systematic diagram showing Example 2 of an exhaust heat recovery system using a gas compressor of the present invention.

  Hereinafter, specific examples of the exhaust heat recovery system using the gas compressor of the present invention will be described using the drawings. In each of the drawings, the parts denoted by the same reference numerals indicate the same or corresponding parts.

  A first embodiment of an exhaust heat recovery system using a gas compressor according to the present invention will be described with reference to a system diagram shown in FIG.

  In FIG. 1, reference numeral 3 denotes a compressor body, which is an oil-cooled screw air compressor in this embodiment. When the compressor body 3 is driven by the motor 4, the gas (air) sucked into the compressor unit 20 is sucked into the compressor body 3 through the suction filter 1 and the suction throttle valve 2. After that, it is compressed and discharged, and flows into the oil separator (oil tank) 6. A discharge temperature sensor (compressor main body outlet temperature sensor) (T1) detects the temperature of the compressed gas (compressed air) discharged from the compressor main body 3. After the temperature is detected by the discharge temperature sensor 5, the compressed gas flows into the oil separator 6.

  The compressed gas flowing into the oil separator 6 is mixed with oil (lubricating oil), and in the oil separator 6, the compressed gas and the oil are centrifuged to separate the compressed gas from the oil separator 6. It flows out from the upper gas pipe (air pipe) 8 and flows into the exhaust heat recovery heat exchanger 10 constituted by a water-cooled heat exchanger. The oil accumulated in the lower part of the oil separator 6 flows out from the oil pipe 7 and flows to the exhaust heat recovery heat exchanger 10 side when the oil temperature is high by the temperature control valve 9 and the oil temperature is low. Flows by bypassing to the oil filter 16 side. The oil that has passed through the oil filter 16 is configured to flow into the compressor body 3 again.

  The exhaust heat recovery heat exchanger 10 is connected to a hot water storage tank unit (exhaust heat recovery device) 23. When the hot water storage tank unit 23 is in operation, the heat transfer medium (fluid such as water) is circulated through the circulation piping (the heat medium inlet piping 17 and the heat medium outlet piping 18) to the exhaust heat recovery heat exchanger 10 And the heat medium is made to flow from the heat medium inlet pipe 17 to the exhaust heat recovery heat exchanger 10 and is recovered from the heat medium outlet pipe 18 as a heat medium having an increased temperature, whereby the compressor is The heat storage tank unit 23 recovers the amount of heat of compression heat generated by the main body 3.

  That is, in the exhaust heat recovery heat exchanger 10, the high temperature oil flowing in the oil pipe 7 and the high temperature compressed gas flowing in the gas pipe 8 exchange heat with the heat medium from the hot water storage tank unit 23, The heat medium is heated, and the compressed gas and oil are configured to be cooled.

  The exhaust heat recovery heat exchanger 10 is disposed in the exhaust heat recovery unit 21. Further, the hot water storage tank unit 23 is provided with a hot water storage tank 19 for storing water (including the case where it is hot water), and the hot water storage tank 19 is provided with a water inlet pipe 27 for supplying water and A hot water outlet pipe 28 is connected for sending water (hot water) whose temperature has risen in the hot water storage tank 19 to a hot water supply destination. Further, a water-to-water heat exchanger 24 is installed in the hot water storage tank 19, and heat is exchanged between the heat medium flowing through the circulation pipe and the water (hot water) in the hot water storage tank 19 for storage. The temperature of the water in the hot water tank 19 is increased.

  Further, a circulation pump 22 for circulating the heat medium is provided in the circulation pipe. In the present embodiment, the circulation pump 22 is installed in the heat medium inlet pipe 17 in the hot water storage tank unit 23, but may be installed in the heat medium outlet pipe 18. The heat pump can be circulated many times through the exhaust heat recovery heat exchanger 10 and the hot water storage tank 19 through the circulation pipes 17 and 18 by the circulation pump 22. As a result, the water in the hot water storage tank 19 can be raised to a predetermined temperature. In addition, even when the load factor of the air compressor becomes small, the air compressor basically can maintain the discharge temperature regardless of the load factor, so the required temperature can be obtained regardless of the load factor of the air compressor. Hot water supply is possible. Therefore, even when there is a request for the required hot water temperature lower limit, and even if the required hot water temperature lower limit is only a few degrees lower than the compressor discharge temperature, the hot water for the required temperature does not depend on the load factor of the compressor. It becomes possible to supply

  An air-cooled heat exchanger 13 is provided downstream of the exhaust heat recovery heat exchanger 10, and the compressed gas and oil that has passed through the exhaust heat recovery heat exchanger 10 also pass through the air-cooled heat exchanger 13. It is configured to That is, after the compressed gas and oil are cooled by the circulating heat medium in the exhaust heat recovery heat exchanger 10 or when the circulation pump 22 is stopped, heat exchange with the heat medium is not performed. It flows into the air-cooling heat exchanger 13 in a state. The air-cooled heat exchanger 13 is configured to be able to cool the compressed gas and the oil by the cooling air blown by the cooling fan 14.

  A fan motor 15 drives the cooling fan 14, and has a configuration in which the rotation speed can be controlled by an inverter 29. Therefore, when the temperature of the compressed gas or oil from the exhaust heat recovery heat exchanger 10 is higher than a predetermined temperature, the compressed gas or oil may be controlled by controlling the number of rotations of the cooling fan 14 according to the temperature. It is possible to supply the temperature of the oil within a predetermined range.

  The compressed gas from the air-cooled heat exchanger 13 is supplied to a demand destination outside the compressor unit 20, and the oil merges with the oil bypassed by the temperature control valve 9, if any. The oil is injected into the compressor body 3 through the oil filter 16.

  Next, the control of supplying the temperature of the compressed gas or oil at a desired temperature by controlling the rotational speed of the cooling fan 14 will be described in detail.

  Reference numeral 30 denotes a control device for controlling the number of rotations of the fan motor 15. The control device 30 includes discharge temperature information from the discharge temperature sensor 5 and a temperature sensor (gas) on the downstream side of the exhaust heat recovery heat exchanger 10. Temperature information of compressed air (compressed gas) from temperature sensor (TA) 11 and temperature information of oil from temperature sensor (oil temperature sensor) (TO) 12 are input.

  Based on these pieces of temperature information, the control device 30 sets the inverter 29 so that the temperature difference between the discharge temperature of the compressed air detected by the discharge temperature sensor 5 and the preset target discharge temperature is reduced. The fan motor 15 is controlled to change the rotational speed of the cooling fan 14 to cool the oil injected into the compressor body 3 to an appropriate temperature. The cooled oil is injected into the compressor body 3 through the oil filter 16.

  That is, when the amount of heat exchange in the exhaust heat recovery heat exchanger 10 is small, the amount of heat exchange in the exhaust heat recovery heat exchanger 10 so that the amount of heat exchange in the air-cooled heat exchanger 13 increases. In the case of a large amount of air, the rotational speed of the cooling fan 14 is controlled so that the amount of heat exchange in the air-cooling heat exchanger 13 is reduced.

  The heat exchanger capacities of the exhaust heat recovery heat exchanger 10 and the air-cooled heat exchanger 13 are designed to be capacities that can individually process the total heat generated by the compressor body 3. For this reason, when the maximum heat recovery is performed in the exhaust heat recovery heat exchanger 10, the temperatures of the lubricating oil and the compressed air which are output from the exhaust heat recovery heat exchanger 10 are sufficiently cooled. In the air-cooling heat exchanger 13, the fan motor 15 may be stopped.

  In the case of an oil-cooled screw-type air compressor, the number of circulations of oil contained in the compressor unit 20 (the number of circulations of oil discharged from the compressor body 3 back to the compressor body) is generally 2 to 5 Because the rotation speed of the cooling fan 14 changes, the temperature of the discharge compressed air detected by the discharge temperature sensor 5 also changes relatively sensitively because the rotation speed of the cooling fan 14 changes. Therefore, by performing inverter control to change the rotational speed of the cooling fan 14 in accordance with the temperature of the discharge temperature sensor 5, the temperature of the compressed air discharged from the compressor main body 3 is substantially at the target discharge temperature (discharge of a predetermined range It is possible to control to temperature).

  In the present embodiment, since the temperature sensor (TA) 11 and the temperature sensor (TO) 12 are also provided, the temperature of the compressed air flowing into the air-cooling heat exchanger 13 and the temperature of the oil are known. It is also possible to adjust the rotational speed of the cooling fan 14 in consideration of the temperature information from these temperature sensors 11 and 12, and the temperature of the compressed air discharged from the compressor main body 3 can be more accurately and accurately It is possible to get closer to

  As described above, by controlling the rotational speed of the cooling fan 14, the exhaust heat recovery heat exchanger 10 can be used regardless of the exhaust heat recovery state (operating state) in the hot water storage tank unit 23. The compressor unit 20 can be operated so that the temperature of the discharge temperature sensor 5 becomes constant regardless of the amount of heat exchange.

  In the hot water storage tank unit 23, the heat medium outlet pipe 18 of the circulation pipes 17 and 18 for circulating the heat medium between the exhaust heat recovery heat exchanger 10 and the hot water storage tank 19 flows through the heat medium outlet pipe 18 A temperature sensor (heat medium temperature sensor) (Tw1) 25 for detecting the temperature of the heat medium, a temperature sensor (hot water temperature sensor) (Tw2) 26 for detecting the warm water temperature in the hot water storage tank 19, and a control device 31 are provided. It is done. The temperature information of the temperature sensor 25 and the temperature sensor 26 is input to the control device 31, and the control device 31 is configured to control the circulation pump 22 based on the temperature information. There is. For example, when the temperature detected by the temperature sensor (Tw2) 26 exceeds a predetermined temperature (for example, a required temperature at a hot water supply destination), the circulation pump 22 is stopped or its rotational speed Control to lower the

  Further, when the temperature detected by the temperature sensor (Tw1) 25 is lower or lower by a predetermined temperature or more than the temperature detected by the temperature sensor (Tw2) 26, the warm water temperature in the hot water storage tank 19 In this case as well, the circulation pump 22 may be stopped or its rotational speed may be reduced.

  Further, the control device 31 can have a function as an output terminal for outputting the temperature information and the like input from the temperature sensors 25 and 26 to the outside. That is, based on the temperature information of the temperature sensors 25, 26 output from the control device 31, it can be used for hot water control in the water inlet pipe 27 or the hot water outlet pipe 28. For example, when the temperature detected by the temperature sensor (Tw2) 26 is equal to or higher than a predetermined temperature (the required temperature at the hot water supply destination), a valve (not shown) provided on the hot water outlet pipe 28 It is possible to control so as to supply hot water to the supply destination and simultaneously open a valve (not shown) provided in the water inlet pipe 27 so as to supply water into the hot water storage tank 19.

  Further, temperature information from the temperature sensors 25 and 26 can be output from the control device 31 to an external display device, a control device 32 described later that controls the entire exhaust heat recovery system, and the like.

  A control device 32 controls the entire exhaust heat recovery system in the oil-cooled gas compressor shown in FIG. 1. This control device 32 is provided in the hot water storage tank unit 23 or in the compressor unit 20. There is. Then, information on the oil temperature detected by the temperature sensor (TO) 12 and information on the temperature of the hot water in the hot water storage tank 19 detected by the temperature sensor (Tw2) 26 are input to the control device 32, When the temperature detected by the temperature sensor 12 becomes equal to or lower than the temperature detected by the temperature sensor 26, control is performed to stop the circulation pump 22 or lower its rotational speed.

  The controller 32 is also configured to be able to input information on the temperature of the compressed gas detected by the temperature sensor (TA) 11 via the controller 30, so the temperature detected by the temperature sensor 11 is However, when the temperature becomes lower than the temperature detected by the temperature sensor 26, the circulation pump 22 may be stopped or controlled to lower its rotational speed.

  Further, the control device 32 functions as an output terminal for outputting temperature information input from the temperature sensor (TA) 11, the temperature sensor (TO) 12, and the temperature sensor (Tw2) 26 to the outside. Can also be

  When the compressor unit 20 is in the stopped state or in the no-load operating state, the exhaust heat recovery heat quantity that can be received by the exhaust heat recovery heat exchanger 10 is small. In the case where the temperature of the oil flowing through the oil pipe in the exhaust heat recovery heat exchanger 10 is lower than the temperature of the hot water in the hot water storage tank 19, the hot water storage tank via the heat medium flowing through the circulation circuit. Since the heat in 19 moves to the waste heat recovery heat exchanger 10, the waste heat recovery rate is deteriorated.

  On the other hand, in the present embodiment, as described above, the temperature detected by the temperature sensor (TO) 12 or the temperature sensor (TA) 11 is lower than the temperature detected by the temperature sensor (Tw2) 26. And control to stop the circulation pump 22, for example. Therefore, according to the present embodiment, it is possible to prevent the deterioration of the exhaust heat recovery rate.

  Moreover, based on the said temperature information output from the said control apparatus 32 outside, it can also be used for control of the said water inlet piping 27 and the warm water outlet piping 28. FIG. That is, when the temperature detected by the temperature sensor (TO) 12 or the temperature sensor (TA) 11 becomes equal to or lower than the temperature detected by the temperature sensor (Tw2) 26, no further temperature rise of the hot water in the hot water storage tank 19 can be expected. Also in this case, the valve provided in the hot water outlet pipe 28 may be opened to utilize hot water, and the valve provided in the water inlet pipe 27 may also be opened to supply water into the hot water storage tank 19. .

  In the embodiment shown in FIG. 1, the hot water in the hot water storage tank is detected by the hot water temperature sensor 26 by the controller 32, the temperature of the oil or compressed gas heat-exchanged in the exhaust heat recovery heat exchanger 10. Although the example has been described in which the circulating pump 22 is controlled to stop or reduce its rotational speed when the temperature is lower than the temperature, the control may be performed as follows.

  That is, when the temperature of the oil or compressed gas heat-exchanged in the exhaust heat recovery heat exchanger 10 by the control device 32 is equal to or lower than the temperature detected by the heat medium temperature sensor 25, the circulation pump 22 is used. It may be controlled to be stopped or to decrease its rotational speed.

  That is, since the hot water temperature sensor 26 detects the temperature above the hot water storage tank 19, the temperature detected by the heat medium temperature sensor 25 is generally substantially the same as the temperature detected by the hot water temperature sensor 26. The temperature is close. Therefore, even when control is performed using the temperature detected by the heat medium temperature sensor 25, substantially the same effect as in the case of control using the hot water temperature sensor 26 can be obtained.

In the case where the compressor body 3 is in the stopped state or in the no-load operating state, the hot water temperature in the hot water storage tank 19 is high while the hot water temperature in the hot water storage tank 19 is high in the middle of boiling. Then it's getting lower. For this reason, since the heat medium also exchanges heat with low temperature water in the water-to-water heat exchanger 24, the temperature of the heat medium flowing through the heat medium inlet pipe 17 is lower than the temperature detected by the hot water temperature sensor 26. In this state, the temperature of the oil or compressed gas in the exhaust heat recovery heat exchanger 10 may be lower than the temperature detected by the hot water temperature sensor 26. However, even in such a state, if the temperature detected by the heat medium temperature sensor 25 is lower than the temperature detected by the oil temperature sensor 12 or the gas temperature sensor 11, exhaust heat is recovered. It is better to continue driving the circulation pump 22.

  On the other hand, when the temperature detected by the oil temperature sensor 12 or the gas temperature sensor 11 is lower than the temperature detected by the heat medium temperature sensor 25, heat is transferred from the heat medium side to the oil or compressed gas side. In this case, the circulation pump 22 is stopped. By controlling in this manner, the exhaust heat recovery rate can be improved.

  In the present embodiment, the control device 32 compares the detected temperature of the temperature sensor (TO) 12 or the temperature sensor (TA) 11 with the detected temperature of the temperature sensor (Tw2) 26 or the temperature sensor (Tw1) 25. An example of controlling is described. However, since the temperature information detected by the discharge temperature sensor (T1) 5 is also input to the control device 32 via the control device 30, the temperature sensor (TO) 12 or the temperature sensor Instead of the (TA) 11, the control can be performed using the temperature detected by the discharge temperature sensor (T 1) 5, and even in this case, substantially the same effect can be obtained. Furthermore, if control is performed using all the detected temperatures of the temperature sensors 5, 11 and 12, more accurate control becomes possible.

  In the present embodiment, only one hot water temperature sensor (Tw2) 26 is installed at the upper part of the hot water storage tank 19, but the installation position of the hot water temperature sensor 26 is not limited to the upper part. It may be installed in the vicinity. Preferably, it is installed above the water-to-water heat exchanger 24. Further, an exhaust heat recovery system capable of further improving the exhaust heat recovery rate by setting a plurality of the hot water temperature sensors 26 in the vertical direction in the hot water storage tank 19 and controlling using the plurality of temperature sensors It will also be possible.

  When the temperature detected by the discharge temperature sensor 5 is lower than the temperature detected by at least one of the oil temperature sensor 12 or the gas temperature sensor 11, the exhaust heat recovery heat exchanger 10 It is considered that the temperature of the oil or the compressed gas to be heat-exchanged is lower than the temperature of the hot water in the hot water storage tank 19. Therefore, when the temperature detected by the discharge temperature sensor 5 is lower than the temperature detected by at least one of the oil temperature sensor 12 and the gas temperature sensor 11, the controller 32 performs the exhaust heat recovery heat exchanger 10. It is determined that the temperature of the oil or compressed gas to be heat-exchanged is lower than the temperature of the hot water in the hot water storage tank 19, and the circulation pump 22 is stopped or its rotational speed is reduced. good.

  In the exhaust heat recovery system in the oil-cooled gas compressor shown in FIG. 1, FIG. 2 shows that the temperature of the compressed gas discharged from the compressor body 3 is about 100.degree. C. (indicated as "discharge temperature 99.degree. C." in FIG. The amount of cooling water and the temperature at the outlet of the exhaust heat recovery heat exchanger of the passed cooling water when the cooling water is not circulated many times in the exhaust heat recovery heat exchanger 10, but only when it passes water once It is a diagram showing a test result of a relation with rise.

  The effect of the temperature rise in the exhaust heat recovery heat exchanger 10 according to the first embodiment will be described using the test results of FIG. 2. This test result is the result of the test conducted in the waste heat recovery system shown in FIG. 1 in which the hot water storage tank 19 does not exist. The horizontal axis indicates the amount of cooling water to the exhaust heat recovery heat exchanger 10, and the vertical axis indicates the temperature rise of the hot water after passing through the exhaust heat recovery heat exchanger 10. Further, the diagram shows the cooling water obtained by exhaust heat recovery obtained by combining the oil pipe 7 side (oil cooler OC side) and the gas pipe 8 side (air cooler AC side) in the exhaust heat recovery heat exchanger 10. It indicates the temperature (temperature rise).

  As can be seen from FIG. 2, the higher the cooling water volume, the higher the hot water temperature, but if the cooling water volume is 2 L / min or less, even if the cooling water volume is further reduced due to the capacity limit of the exhaust heat recovery heat exchanger 10 The temperature can not be increased, and the temperature rise of the hot water reaches a limit at 80 ° C. That is, when the water flow to the exhaust heat recovery heat exchanger 10 is only one time (that is, in the case of one-pass water flow), an oil-cooled screw compressor in which the compressor body outlet is set to about 100 ° C. In this example, the temperature of hot water obtained by exhaust heat recovery from a 22 kW capacity one is limited to the temperature rise up to 80 ° C.

  On the other hand, in the case of the exhaust heat recovery system in the oil-cooled gas compressor shown in FIG. 1, the water between the stored hot water tank 19 and the exhaust heat recovery heat exchanger 10 is connected via the circulation pipes 17 and 18 In order to circulate the hot water many times (because it is not a one-time water passing but a multi-pass water circulating many times), the temperature in the hot water storage tank 19 is finally set to the compressor discharge temperature. It can be raised to a close temperature, for example about 93 ° C. That is, compared with the case of the one-time water passage (one-pass water passage) under the same conditions, it is possible to obtain hot water of about 93 ° C. at a high temperature of 10 ° C. or more. Moreover, when the water flow to the exhaust heat recovery heat exchanger 10 is one time only, the temperature of the hot water obtained is lowered when the load factor of the compressor is low. However, since the compressor can basically maintain the discharge temperature regardless of the load factor, the configuration of the present embodiment makes it possible to supply hot water of the required temperature regardless of the load factor of the compressor. It becomes possible.

  In the exhaust heat recovery system in the oil-cooled gas compressor shown in FIG. 1, FIG. 3 shows that the temperature of the compressed gas discharged from the compressor body 3 is about 78 ° C., and the exhaust heat recovery heat exchanger 10 It is a diagram showing the test result of the relation between the amount of cooling water and the exhaust heat recovery rate by the flowing cooling water when water is supplied only once, not circulated.

  Similar to FIG. 2, FIG. 3 shows the result of the test performed by the exhaust heat recovery system in which the hot water storage tank 19 does not exist in the exhaust heat recovery system shown in FIG. 1. The horizontal axis indicates the amount of cooling water to the exhaust heat recovery heat exchanger 10, and the vertical axis indicates the exhaust heat recovery rate by the flow of the cooling water to the exhaust heat recovery heat exchanger 10. Moreover, the diagram shows the exhaust heat recovery rate by the exhaust heat recovery which put the oil piping 7 side (oil cooler OC side) and the gas piping 8 side (air cooler AC side) in the exhaust heat recovery heat exchanger 10 together. ing. Here, the exhaust heat recovery rate is a value obtained by dividing the heat amount received by the exhaust heat recovery heat exchanger 10 by the total input of the compressor, and the compressor exhaust heat is effectively utilized as the exhaust heat recovery rate is higher. It will be.

  As can be seen from FIG. 3, as the amount of cooling water is reduced, the exhaust heat recovery rate decreases, and in FIG. 2 described above, with a cooling water amount of 2 L / min that can ensure the highest warm water temperature, as shown in FIG. Is only about 10%, and it can be seen that the efficiency of waste heat recovery is very poor. That is, in the case where warm water is generated only by passing water once and hot water to a certain degree is required, it is necessary to reduce the amount of cooling water, so the exhaust heat recovery rate becomes very low.

  Conversely, if the amount of cooling water is increased, the exhaust heat recovery rate can be raised to nearly 80% above a certain amount of cooling water (10 L / min or more in FIG. 3), and the amount of cooling water is further increased Even if it is increased, the waste heat recovery rate can not be further increased but can be maintained at a high value. That is, if it says in the test result of FIG. 3, the heat exchange with a high exhaust heat recovery can be made to be performed by setting cooling water volume as 10 L / min or more (for example, 20 L / min). Therefore, in the present embodiment shown in FIG. 1, by setting the amount of cooling water (for example, the amount of circulating water of 20 L / min), not only high temperature hot water can be obtained, but also an exhaust heat recovery system having a high exhaust heat recovery rate. can do.

Next, an application case where the present invention is applied to a hot water cleaning facility will be described. The application example of this cleaning facility is conventionally equipped with two 5 kW heaters, and by energizing this, 300 L of water is raised from 20 ° C. to 80 ° C. or more, and the resulting hot water is used for cleaning It is the equipment that I did. Here, when it is calculated that all the heat quantity of the heater energization is used for the temperature rise of water, the time required for the temperature rise to 80 ° C. or more is about 2 hours. However, in an actual installation, the heat naturally escapes to the atmosphere, so the water is raised to a hot water of the target temperature of 80 ° C. or more by energization for 2.5 hours or more. Furthermore, during the operation for 8 hours a day, the heater of 5 kW was repeatedly turned on and off in order to keep the hot water at 80 ° C. or higher. Thus, conventionally, a total of about 47 kWh of power was consumed.

  An application example of the present invention to the above-described hot water cleaning facility will be described. An oil-cooled screw air compressor unit (air-cooled type) having a capacity of 22 kW has conventionally been installed beside the cleaning facility. Then, the system which manufactures the warm water used with the above-mentioned washing equipment was examined using the exhaust heat of this compressor unit, and the warm water was manufactured as an exhaust heat recovery system as shown in FIG. The circulation amount of water (hot water) from the hot water storage tank 19 shown in FIG. 1 to the exhaust heat recovery heat exchanger 10 was 20 L / min.

As a result, as described in FIG. 3, a heat recovery rate as high as 80% is obtained, and the time required to raise 300 L of water from 20 ° C. to 80 ° C. or more becomes 120 minutes (2 hours). The target temperature could be reached 30 minutes earlier than using the heater. Moreover, even after reaching the target temperature of 80 ° C., the target temperature of 80 ° C. or higher could be kept by the compressor exhaust heat, so the amount of power used when using the conventional heater was 47 kWh per day It was possible to make things 0kWh. Moreover, it became possible to obtain high temperature water of 80 ° C. or higher. This is achieved by the application of the present invention that the hot water in the hot water storage tank is circulated to the exhaust heat recovery heat exchanger many times, and the exhaust heat recovery heat exchanger is only passed through once. It is difficult to reach this temperature for things.

  A second embodiment of the exhaust heat recovery system in the oil-cooled gas compressor of the present invention will be described with reference to a system diagram shown in FIG. In this FIG. 4, the portions given the same reference numerals as those in FIG. 1 are the same or corresponding portions, and therefore, portions different from the embodiment 1 shown in FIG. 1 will be mainly described.

  In the first embodiment, the water-to-water heat exchanger 24 is provided in the hot water storage tank 19, and the heat medium circulating in the circulation circuits 17 and 18 is allowed to pass through the water to water heat exchanger 24, and the hot water storage tank The example which made it heat-exchange with the water (warm water) in 19 was demonstrated.

  On the other hand, in the second embodiment, the heat medium for circulating the circulation circuits 17 and 18 without the water-to-water heat exchanger 24 shown in FIG. It is different that it is made to be the case where it is warm water).

  That is, the water in the hot water storage tank 19 of the hot water storage tank unit 23 is directly led to the heat medium inlet pipe 17 from the lower portion thereof, and the exhaust heat recovery heat exchanger of the exhaust heat recovery unit 21 is Device 10). The water (heat medium) sent to the exhaust heat recovery heat exchanger 10 is compressed at high temperature through high temperature oil and gas piping (air piping) 8 flowing through the oil piping 7 in the exhaust heat recovery heat exchanger. Heat is exchanged with the gas to recover heat from the oil and the compressed gas for heating.

  The oil and compressed gas which have been cooled by heat recovery to water are sent to the air-cooled heat exchanger 13 installed downstream via the oil pipe 7 or the gas pipe 8 so as to be further cooled. It is done. Further, the water (hot water) heated by the exhaust heat recovery heat exchanger 10 and whose temperature has risen is returned to the hot water storage tank 19 via the heat medium outlet pipe 18. Thus, the water in the hot water storage tank 19 is circulated to the exhaust heat recovery heat exchanger 10 many times. Therefore, the temperature of the water in the hot water storage tank 19 can be gradually raised.

  As a result, the water in the hot water storage tank 19 can be raised to a predetermined temperature. In addition, even when the load factor of the air compressor becomes small, it is possible to supply hot water of the required temperature regardless of the load factor, so the required temperature is the compressor discharge temperature even when there is the required lower limit temperature of hot water. Even when the temperature is only a few degrees lower, it is possible to supply hot water of the required temperature.

  Even when configured as in the second embodiment, the same effect as that of the first embodiment can be obtained. In addition, in the second embodiment, since it is not necessary to provide a water-to-water heat exchanger as shown in the first embodiment, the structure is simplified and can be manufactured inexpensively, and the heat by the water-to-water heat exchanger is also possible. Since the replacement is not necessary, the waste heat recovery rate can be improved.

  Further, since the water can be introduced from the lowermost portion in the hot water storage tank 19 and heat exchange can be performed by the exhaust heat recovery heat exchanger 10, the lowest temperature water in the hot water storage tank 19 and the high temperature oil from the compressor Since the heat exchange between the and the compressed gas is performed, the exhaust heat recovery rate can be further improved.

  The other configuration and control are the same as in the first embodiment, and thus the description thereof is omitted.

As described above, according to each embodiment of the present invention, the exhaust heat recovery heat exchanger 10 for recovering heat from at least one of the compressed gas flowing through the gas pipe 8 and the oil flowing through the oil pipe 7 is provided; Further, a heat storage medium for transferring the heat received by the waste heat recovery heat exchanger 10 to the hot water storage tank 19 and a heat storage tank 19 for storing the heat received by the waste heat recovery heat exchanger 10 as hot water and the heat received by the waste heat recovery heat exchanger 10 A circulation circuit (circulation pipes 17 and 18) for circulating (a fluid such as water) between the exhaust heat recovery heat exchanger 10 and the hot water storage tank 19, and a circulation pump 22 provided in the circulation circuit The control is performed to stop the circulation pump or reduce its rotational speed when the temperature of the oil or compressed gas subjected to heat exchange in the exhaust heat recovery heat exchanger is equal to or lower than the warm water temperature in the hot water storage tank Equipped with a control unit There.

  Therefore, it is possible to supply hot water of the required temperature even when the compressor load factor is low, and to suppress the heat radiation from the exhaust heat recovery equipment to improve the exhaust heat recovery rate. Waste heat recovery system can be obtained.

  That is, in this embodiment, as the cooling system of the oil-cooled gas compressor, in addition to the air-cooling heat exchanger 13 which is the main first cooling system, the exhaust heat recovery heat exchanger 10 which is the second cooling system is Further, a heat storage tank unit (exhaust heat recovery device) 23 is juxtaposed in the compressor unit 20 to constitute an exhaust heat recovery system, and a circulation pipe is provided between the hot water storage tank 19 and the exhaust heat recovery heat exchanger 10 A heat transfer medium (water in the above embodiment) is circulated as many times as possible 17 and 18. Therefore, it is possible to raise the hot water in the hot water storage tank 19 to a temperature (a temperature close to the compressor outlet temperature) lower by a few degrees C. than the compressor outlet temperature.

  Since the outlet temperature of the oil-cooled screw compressor is usually as low as 100 ° C. or lower, when producing hot water by the exhaust heat, the temperature is further lowered due to the limit of the heat exchanger, but this embodiment is adopted Thus, it is possible to obtain a hot water temperature extremely close to the compressor outlet temperature.

  Further, does the control device stop the circulation pump 22 when the temperature of the oil or compressed gas subjected to heat exchange in the exhaust heat recovery heat exchanger 10 is equal to or lower than the warm water temperature in the hot water storage tank 19? Since the rotation speed is controlled to be reduced, the heat in the hot water storage tank 19 is transferred to the exhaust heat recovery heat exchanger 10 via the heat medium flowing through the circulation circuit, and the exhaust heat recovery rate is deteriorated. You can also control

  Furthermore, according to the present embodiment, the amount of heat exchange in the exhaust heat recovery heat exchanger 10, that is, regardless of the operating condition of the hot water storage tank unit (exhaust heat recovery device) 23, Since the cooling fan 14 blowing air to the air-cooling heat exchanger 13 is configured to be able to control the number of rotations, it is possible to control so that the outlet temperature of the compressor main body 3 becomes a constant target temperature. Therefore, it is possible to obtain an exhaust heat recovery system in an oil-cooled gas compressor that does not require the operating condition of the hot water storage tank unit (exhaust heat recovery device) 23 and the operating condition of the compressor unit 20 to coincide.

The present invention is not limited to the embodiments described above, but includes various modifications.
For example, in each of the above embodiments, the oil-cooled screw air compressor has been described as an example of the oil-cooled gas compressor, but the invention is not limited thereto. For example, a compressor of another type such as a scroll compressor But the same applies.

  Further, the medium compressed by the oil-cooled gas compressor is not limited to air, and the invention can be applied to a compressor that compresses another gas as well. Furthermore, the drive source may be another drive source other than the motor, such as an engine or a turbine.

In the embodiment described above, the exhaust heat recovery system in the oil-cooled gas compressor is connected by connecting three units of the compressor unit 20, the exhaust heat recovery unit 21 and the hot water storage tank unit 23 in parallel. However, it is also possible to integrate the three units into one unit or a two-unit configuration.
Further, the above-described embodiments are described in detail to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the configurations described.
(Supplementary Note 1)
A compressor body, an oil separator for separating oil from compressed gas discharged from the compressor body, an oil pipe for returning the oil separated by the oil separator to the compressor body, and the oil pipe A waste heat recovery heat exchanger for recovering heat from oil flowing through the
In order to transfer the heat received by the exhaust heat recovery heat exchanger to the outside of the gas compressor, a heat medium is pumped by a circulation pump between the exhaust heat recovery heat exchanger and the outside of the gas compressor. Circulation circuit to circulate,
When the temperature of the oil heat-exchanged by the exhaust heat recovery heat exchanger is equal to or lower than the temperature of warm water distributed to the outside of the gas compressor, the circulation pump may be stopped or its rotational speed may be reduced. And a controller for controlling the gas compressor.
(Supplementary Note 2)
(Additional remark 1) The gas compressor according to
The temperature of the oil heat-exchanged by the exhaust heat recovery heat exchanger is equal to or lower than the warm water temperature input from the warm water temperature sensor that detects the warm water temperature flowing outside the gas compressor In some cases, the gas compressor is one that stops the circulation pump or reduces its rotational speed.
(Supplementary Note 3)
(Additional remark 1) The gas compressor according to
When the temperature of the oil heat-exchanged by the exhaust heat recovery heat exchanger is equal to or lower than the temperature input from a heat medium temperature sensor that detects the heat medium temperature of the circulation circuit, the controller A gas compressor that shuts down the circulation pump or reduces its speed.
(Supplementary Note 4)
The gas compressor according to (Appendix 2) or (Appendix 3), wherein
At least one of a discharge temperature sensor for detecting a discharge side temperature of the compressor body and an oil temperature sensor for detecting the oil temperature at an outlet side of the exhaust heat recovery heat exchanger;
When the temperature detected by the control device is at least one of the discharge temperature sensor and the oil temperature sensor is lower than or lower than the temperature input from either the hot water temperature sensor or the heat medium temperature sensor, A gas compressor which stops the circulating pump or reduces its rotational speed.
(Supplementary Note 5)
(Additional remark 1) The gas compressor according to
A discharge temperature sensor for detecting the discharge side temperature of the compressor body, and an oil temperature sensor for detecting the oil temperature at the outlet side of the exhaust heat recovery heat exchanger,
A gas compressor, wherein the control device shuts down the circulation pump or reduces its rotational speed if the temperature detected by the discharge temperature sensor is lower than the temperature detected by the oil temperature sensor. .
(Supplementary Note 6)
(Additional remark 1) The gas compressor according to
An air-cooled heat exchanger disposed downstream of the exhaust heat recovery heat exchanger for cooling lubricating oil flowing through the oil pipe, and a cooling fan for sending a cooling air to the air-cooled heat exchanger.
The gas compressor, wherein the number of revolutions of the cooling fan is controlled so that the temperature of the compressed gas discharged from the compressor body falls within a predetermined range.

1: Suction filter, 2: Suction throttle valve, 3: Compressor body, 4: Main motor,
5: Discharge temperature sensor (compressor body outlet temperature sensor),
6: Oil separator (oil tank),
7: Oil piping, 8: Gas piping (air piping),
9: Temperature control valve,
10: Exhaust heat recovery heat exchanger (water-cooled heat exchanger)
11: Temperature sensor (gas temperature sensor) (TA),
12: Temperature sensor (oil temperature sensor) (TO),
13: air-cooled heat exchanger, 14: cooling fan, 15: fan motor,
16: oil filter,
17, 18: Circulation piping (circulation circuit) (17: heat medium inlet piping, 18: heat medium outlet piping),
19: Hot water storage tank,
20: compressor unit, 21: exhaust heat recovery unit,
22: Circulation pump,
23: Hot water storage tank unit (exhaust heat recovery equipment),
24: Water-to-water heat exchanger,
25: Temperature sensor (heat medium temperature sensor) (Tw1),
26: Temperature sensor (hot water temperature sensor) (Tw2),
27: water inlet piping, 28: hot water outlet piping,
29: Inverter,
30-32: Control device.

Claims (7)

Gas compression comprising a compressor body, a gas pipe for sending compressed gas discharged from the compressor body to a demand end, and an exhaust heat recovery heat exchanger for recovering heat from the compressed gas flowing through the gas pipe Machine,
In order to transfer the heat received by the exhaust heat recovery heat exchanger to the outside of the gas compressor, a heat medium is pumped by a circulation pump between the exhaust heat recovery heat exchanger and the outside of the gas compressor. Circulation circuit to circulate,
The temperature of the compressed gas is heat-exchanged in the exhaust heat recovery heat exchanger, when the heating medium or the heating medium and the hot water temperature to be heat exchanged following or even more than a predetermined temperature lower, the circulation pump And a control device for controlling to stop or reduce its rotational speed. The gas compressor according to claim 1, wherein
The control device is configured such that the temperature of the compressed gas subjected to heat exchange in the exhaust heat recovery heat exchanger is equal to or lower than the temperature of hot water inputted from a hot water temperature sensor that detects the temperature of hot water exchanged with the heat medium The gas compressor which stops the said pump for circulation, or reduces the rotation speed, when lower than predetermined temperature more than it. The gas compressor according to claim 2, wherein
  At least one of a discharge temperature sensor for detecting the temperature on the discharge side of the compressor body and a gas temperature sensor for detecting the temperature of the compressed gas on the outlet side of the exhaust heat recovery heat exchanger,
  When the control device detects that the temperature detected by at least one of the discharge temperature sensor and the gas temperature sensor is lower than the temperature input from the hot water temperature sensor or lower than the predetermined temperature, the pump for circulation A gas compressor that is to stop or reduce its speed. The gas compressor according to claim 1, wherein
Wherein the controller, the temperature of the compressed gas is heat-exchanged in the exhaust heat recovery heat exchanger, the temperature of the heat medium that is input from the heat medium temperature sensor that detects the temperature of the heat medium circulation circuit below or it A gas compressor which stops the circulating pump or reduces its rotational speed when the temperature is lower than a predetermined temperature . The gas compressor according to claim 4 , wherein
At least one of a discharge temperature sensor for detecting the temperature on the discharge side of the compressor body and a gas temperature sensor for detecting the temperature of the compressed gas on the outlet side of the exhaust heat recovery heat exchanger,
When the control device, the discharge temperature sensor and the temperature detected by at least any one of said gas temperature sensor, pre-Symbol heat medium temperature sensor or found the following input temperature or even more than a predetermined temperature lower, A gas compressor which stops the circulating pump or reduces its rotational speed. The gas compressor according to claim 1, wherein
An air-cooled heat exchanger disposed downstream of the exhaust heat recovery heat exchanger for cooling compressed gas flowing through the gas pipe, and a cooling fan for sending cooling air to the air-cooled heat exchanger.
The gas compressor, wherein the number of revolutions of the cooling fan is controlled so that the temperature of the compressed gas passing through the air-cooling heat exchanger falls within a predetermined range. Gas compression comprising a compressor body, a gas pipe for sending compressed gas discharged from the compressor body to a demand end, and an exhaust heat recovery heat exchanger for recovering heat from the compressed gas flowing through the gas pipe Machine,
In order to transfer the heat received by the exhaust heat recovery heat exchanger to the outside of the gas compressor, a heat medium is pumped by a circulation pump between the exhaust heat recovery heat exchanger and the outside of the gas compressor. Circulation circuit to circulate,
A discharge temperature sensor for detecting the temperature of the discharge side of the compressor body,
And a gas temperature sensor for detecting a temperature of the compressed gas on the outlet side of the exhaust heat recovery heat exchanger,
The discharge temperature the temperature detected by the sensor, when the gas temperature sensor is lower than the detected temperature, the control device, the gas compressor is intended to reduce its rotational speed or stops the circulation pump .

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