JP7225867B2 - steam system - Google Patents

Description

The present invention relates to steam systems using steam.

BACKGROUND ART Conventionally, steam systems using steam such as steam expanders and steam compressors are known. Patent document 1 and patent document 2 disclose this type of technology.

In Patent Document 1, a motor that uses steam to generate power, a driven machine that is driven by the motor and discharges or sucks in fluid, and a point where steam after use is supplied to the motor are connected via the motor. Based on the steam load at the location where the steam from the prime mover and the steam from the bypass are supplied, and the fluid load in the space where the fluid is discharged or taken in by the driven machine, the prime mover A steam system is described comprising a controller for controlling the supply of steam to a

Patent Document 2 discloses a prime mover that generates power using steam from a boiler, a driven machine that is driven by the prime mover and discharges or sucks fluid, and a prime mover that supplies steam after use to the prime mover. a bypass that supplies steam without passing through a bypass, a bypass valve that is provided in the bypass, a steam load at a location where the steam from the prime mover and the steam from the bypass are supplied, and a fluid that is discharged by the driven machine. Or, based on the fluid load in the sucked space, a controller that controls the steam supply to the prime mover, the water supply to the boiler is stored, the steam or drain leaking from the shaft seal of the prime mover, the drain generated in the prime mover, Alternatively, a steam system characterized by comprising a water supply tank in which stored water or make-up water is heated using heat generated by the driven machine.

Japanese Patent No. 4240155 Japanese Patent No. 4329875

In the steam system, when the supply of steam to the steam machine is stopped and the facility becomes cold, the steam condenses within the facility to generate drain. Condensate that flows into the main body when the steam machine is started carries foreign substances such as rust from the pipes into the main body, and causes damage to the shaft seal of the rotating body due to volumetric expansion during vaporization. In a conventional steam system, a steam separator (steam separator) is placed in the steam supply path. There was a risk of getting in. Therefore, the conventional steam system has room for improvement in terms of preventing the inflow of condensate into the main body during start-up.

SUMMARY OF THE INVENTION An object of the present invention is to provide a steam system capable of effectively suppressing the inflow of drain into a steam machine main body at startup.

The present invention provides a steam machine having a main body into which steam flows and a rotating body pivotally supported inside the main body , a steam feed pipe through which the steam introduced into the steam machine flows, and a steam feed pipe arranged in the steam feed pipe. a steam supply valve, a first drain pipe connected to the steam supply pipe on the upstream side of the steam supply valve, a first steam trap arranged in the first drain pipe, and a connection of the first drain pipe. a first temperature detector for detecting the temperature of steam flowing into the main body in the steam supply pipe upstream of the position ; a control unit that permits the start-up of the machine, opens the steam supply valve, and shifts to control to start supplying steam to the main body, wherein the predetermined temperature is such that the drain generated in the cold state is the first steam It relates to a steam system which is at a temperature which is discharged from a trap and which is indicative of a steam-filled condition of said steam feed line .

Further, the present invention includes a steam machine having a main body into which steam flows and a rotating body pivotally supported inside the main body, a steam supply pipe through which the steam introduced into the steam machine flows, and the steam supply pipe. a steam separator arranged upstream of the steam supply pipe; a drain pipe connected to the steam separator; a steam trap arranged in the drain pipe; a temperature detection unit in the drain pipe upstream of the steam trap for detecting the temperature of the steam flowing into the main body; and a control unit that opens the steam supply valve and shifts to control to start supplying steam to the main body, and the predetermined temperature is reached when the drain generated in the cold state is discharged from the steam trap, It relates to a steam system, wherein the temperature is indicative of the steam-filled state of the steam separator .

After opening the steam supply valve, the control unit performs control to close the steam supply valve and stop the rotation of the rotating body when the detected temperature of the steam flowing into the main body becomes lower than the predetermined temperature. is preferred.

The predetermined temperature is preferably set to the saturated steam temperature.

The steam machine may be a steam expander that expands steam .

The steam machine is a steam compressor that compresses steam, and has a motor that rotates the rotating body, and the control unit starts driving the motor when the steam temperature reaches or exceeds the predetermined temperature. is preferred.

According to the steam system of the present invention, it is possible to effectively suppress the inflow of drain into the steam machine main body at startup.

1 schematically shows a steam system according to an embodiment of the invention; FIG. It is a figure which shows typically the state which the drain detection part with which the steam system of this embodiment has does not detect the predetermined water level. It is a figure which shows typically the state which the drain detection part with which the steam system of this embodiment has detected the predetermined water level. It is a flow which shows the control from the start of operation of the steam system of this embodiment to normal operation. 4 is a flow showing detection control of drain exceeding the permissible value of the steam system of the present embodiment. It is a figure which shows the steam system of a modification typically.

Preferred embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram schematically showing a steam system 1 according to one embodiment of the invention. As shown in FIG. 1, the steam system 1 includes a steam expander 10, a steam compressor 15 as a driven machine, a steam supply pipe 20, a steam separator 21, a steam supply valve 22, and a steam exhaust pipe 40. , and a control unit 100 .

The steam expander 10 includes a main body 11 into which steam flows, a screw 12 as a rotating body pivotally supported inside the main body 11, a seal portion 13 as a shaft sealing portion of the screw 12, and a rotational speed of the screw 12. and a rotation detection unit 14 for detecting. The screw 12 is composed of a driving screw that rotates due to steam flow and a driven screw that meshes with the driving screw and rotates, but FIG. 1 shows only the driven screw as a representative.

The steam compressor 15 is mechanically connected to the steam expander 10 and driven by the rotational force of the screw 12 of the steam expander 10 .

Steam introduced into the main body 11 of the steam expander 10 from a steam generator (not shown) such as a boiler flows through the steam supply pipe 20 . A steam separator 21 and a steam supply valve 22 are arranged in the steam supply pipe 20 .

The steam separator 21 separates steam from water. The steam separator 21 includes a drain pipe 25 that discharges the separated drain and a steam trap 26 to which the drain pipe 25 is connected.

A separator-side temperature sensor 27 is arranged in the drain pipe 25 of the present embodiment. The separator-side temperature sensor 27 is composed of, for example, a thermocouple. A detected value of the separator-side temperature sensor 27 is transmitted to the control unit 100 .

The steam supply valve 22 is arranged downstream of the steam separator 21 in the steam supply pipe 20 . When the steam supply valve 22 is opened, steam is supplied to the main body 11 of the steam expander 10, and when the steam supply valve 22 is closed, the supply of steam is stopped. Opening and closing of the steam supply valve 22 is controlled by the controller 100 . The steam supply valve 22 of this embodiment is a capacity control valve with an emergency cutoff function.

A steam supply temperature sensor 51 and a steam supply pressure sensor 52 are arranged upstream of the steam supply valve 22 . A steam supply temperature sensor 61 and a steam supply pressure sensor 62 are arranged downstream of the steam supply valve 22 . Each detection value of the supply steam temperature sensor 51 , the supply steam pressure sensor 52 , the supply steam temperature sensor 61 and the supply steam pressure sensor 62 is transmitted to the control unit 100 .

From the viewpoint of detecting drain exceeding an allowable value, it is preferable that the supplied steam temperature sensor 51 and the supplied steam temperature sensor 61 are arranged at a portion where drain tends to accumulate. For example, when the steam supply valve 22 is installed horizontally, the steam supply temperature sensor 51 or the steam supply temperature sensor 61 is arranged below the steam supply pipe 20 .

The steam expanded by the steam expander 10 and discharged from the main body 11 flows through the steam exhaust pipe 40 . An exhaust steam temperature sensor 41 and an exhaust steam pressure sensor 42 are arranged in the exhaust pipe 40 . The detected values of the exhaust steam temperature sensor 41 and the exhaust steam pressure sensor 42 are transmitted to the control unit 100 .

Next, a configuration for discharging drain generated in the steam supply pipe 20 and the main body 11 of the steam expander 10 will be described. A first drain pipe 81 is connected to the upstream side of the steam supply valve 22 of the steam supply pipe 20 . The main body 11 of the steam expander 10 is connected to a second drain pipe 82 for discharging drainage generated inside the main body 11 . A third drain pipe 83 is connected to the downstream side of the steam supply valve 22 .

A steam trap 101 is arranged in the first drain pipe 81, and a check valve 105 is arranged downstream of the steam trap 101. A steam trap 102 is also arranged in the second drain pipe 82, and the steam trap 102 is arranged. A check valve 106 is arranged downstream of the . A steam trap 103 is also arranged in the third drain pipe 83 , and a check valve 107 is arranged downstream of the steam trap 103 .

The downstream ends of the first drain pipe 81 , the second drain pipe 82 and the third drain pipe 83 are all connected to the collective drain pipe 90 . As a result, the drains flowing through the first drain pipe 81 , the second drain pipe 82 and the third drain pipe 83 are collected into the collective drain pipe 90 . A drain detector 110 for detecting the amount of drain is arranged in the collective drain pipe 90 , and the drain passes through the drain detector 110 and is discharged to the drain pit 91 . A detection value of the drain detection unit 110 is transmitted to the control unit 100 .

Next, the configuration of the drain detector 110 will be described with reference to FIGS. 2 and 3. FIG. FIG. 2 is a diagram schematically showing a state in which the drain detector 110 included in the steam system 1 of this embodiment does not detect the predetermined water level L. As shown in FIG. FIG. 3 is a diagram schematically showing a state in which the drain detector 110 included in the steam system of this embodiment detects the predetermined water level L. As shown in FIG.

The drain detection unit 110 of the present embodiment includes a reservoir 111 to which the collective drain pipe 90 is connected, a discharge pipe 112 connected to the reservoir 111 for discharging the drain in the reservoir 111 to the outside, and and an overflow pipe 113 connected above the discharge pipe 112 . The discharge pipe 112 and the overflow pipe 113 are joined at their downstream ends, and the drain that has passed through the discharge pipe 112 or the overflow pipe 113 is finally discharged to the drain pit 91 . An orifice 116 is arranged in the discharge pipe 112 , and the flow rate of the discharge pipe 112 is throttled by the orifice 116 .

A float switch 120 for detecting a predetermined water level L (see FIG. 3) at which drain flows into the overflow pipe 113 is arranged inside the reservoir 111 . The predetermined water level L indicates that the total amount of drain generated from the steam supply pipe 20 and the steam expander 10 in the steam system 1 is an unacceptable amount, that is, an amount not suitable for starting or continuing operation of the steam expander 10. is the water level. A detection value of the float switch 120 is transmitted to the control unit 100 .

The control unit 100 is a computer that performs various controls of the steam system 1 . Next, control of the steam system 1 by the controller 100 will be described. FIG. 4 is a flow showing control from the start of operation of the steam system of this embodiment to normal operation.

When the steam system 1 receives the activation start signal, the control unit 100 executes activation permission determination to determine whether or not activation permission conditions are satisfied (step S101). The activation permission condition of the present embodiment is whether or not the temperature of the steam flowing into the main body 11 of the steam expander 10 is equal to or higher than a predetermined temperature. Since the steam supply valve 22 is closed while the steam expander 10 is stopped, the start permission determination is executed while detecting the steam temperature on the upstream side of the steam supply valve 22 .

In a first example of the start permission determination, the controller 100 monitors the detected value of the supply steam temperature sensor 51, and determines that the start is permitted when the detected value reaches or exceeds a predetermined temperature. The predetermined temperature in the first example is set to the saturated steam temperature, for example. If a large amount of drain is generated upstream of the steam supply valve 22 in a cold state, or if a drainage failure occurs in the steam trap 101, the steam supply pipe 20 is filled with the drain, and the detection value of the supply steam temperature sensor 51 increases. descend. On the other hand, when the drain in the steam supply pipe 20 is properly discharged and no new drain is generated, the steam supply pipe 20 is filled with the steam supplied from the steam generator. is equal to or higher than the saturated steam temperature. If the detected value of the supply steam temperature sensor 51 exceeds the saturated steam temperature, it means that the steam supply pipe 20 is filled with superheated steam.

In a second example of the start permission determination, the control unit 100 monitors the detection value of the separator-side temperature sensor 27, and determines that start is permitted when the detected value reaches or exceeds a predetermined temperature. The predetermined temperature in the second example is set to the saturated steam temperature, for example. If a large amount of drain is generated on the upstream side of the steam separator 21 in a cold state or if the steam trap 26 fails to discharge the drain, the drain accumulates in the steam separator 21 and the detection value of the separator-side temperature sensor 27 decreases. On the other hand, when the drain in the steam separator 21 is properly discharged and no new drain is generated, the steam supplied from the steam generator fills the steam separator 21 and the drain pipe 25, so the separator side temperature The detected value of the sensor 27 becomes equal to or higher than the saturated steam temperature. If the detected value of the separator-side temperature sensor 27 exceeds the saturated steam temperature, it means that the steam separator 21 is filled with superheated steam.

In a third example of the start permission determination, the control unit 100 monitors the detection values of the supply steam temperature sensor 51 and the separator-side temperature sensor 27, and determines that start is permitted when each detection value exceeds a predetermined temperature. The predetermined temperature in the third example is set to the saturated steam temperature, for example.

When it is determined that activation is permitted, the controller 100 opens the steam supply valve 22 and starts warm-up control to start supplying steam to the steam expander 10 (step S102).

When the warm-up control is started in step S102, the control unit 100 supplies steam to the inside of the main body 11 of the steam expander 10 while maintaining the stationary state of the screw 12. The term "stationary state" as used herein means a state in which the screw 12 as a rotating body is stopped and can be regarded as being stopped, and is not limited to a state in which the screw 12 is completely stopped, and the screw 12 is slightly moving. state shall also be included.

During the warm-up control, control is performed to adjust the amount of steam flowing into the main body 11 in order to keep the screw 12 stationary. In the present embodiment, the stationary state of the screw 12 is maintained by performing a first control that repeats opening and closing of the steam supply valve 22 or a second control that maintains the open state of the steam supply valve 22 at an opening degree that allows the stationary state to be maintained for a predetermined period of time. while steam is allowed to flow into the main body 11 .

In the first control, the degree of opening when the steam supply valve 22 is opened is set relatively smaller than the degree of opening during normal operation after completion of the warm-up control. Further, the degree of opening at which the stationary state can be maintained and the predetermined time for maintaining the degree of opening in the second control may be any relationship that allows the screw 12 to be in the stationary state. The degree of opening of the steam supply valve 22 and the time and interval of the open state in the warm-up control are not particularly limited. The warm-up control may be any control that allows steam to flow in while maintaining a stationary state. good too.

In this embodiment, the control unit 100 determines whether the screw 12 is stationary or rotating based on the detection value of the rotation detection unit 14 . The rotation detector 14 is, for example, an inductive proximity sensor. When the detection value of the rotation detection unit 14 indicates that the state is not stationary or indicates that the state will not be stationary, the control unit 100 adjusts the opening degree of the steam supply valve 22 so that the stationary state is maintained. reduce the amount of steam supplied.

After shifting to the warm-up control, the controller 100 determines whether or not the warm-up completion condition is satisfied (step S103). The warm-up completion condition is steam pressure, steam temperature, warm-up control time, or a combination thereof. Each condition will be described below.

A case in which the steam pressure is used as the warm-up completion condition will be described. The control unit 100 monitors the detected value of the exhaust steam pressure sensor 42, and determines that the warm-up is completed when the detected value of the steam discharged from the main body 11 reaches a predetermined pressure. The predetermined pressure in this example may be a set value input to the control unit 100 in advance, or may be a detected value of the steam supply pressure sensor 62 arranged near the inlet of the main body 11 . Since the screw 12 is controlled not to rotate during the warm-up control, when the warm-up is sufficiently performed, the expansion of the steam is suppressed when it flows through the inside of the main body 11, and the energy loss is almost eliminated. Therefore, when the pressure difference between the vicinity of the inlet and the vicinity of the outlet of the main body 11 becomes substantially zero, it can be determined that the warm-up is completed. If an energy loss due to heat radiation is expected in the main body 11, the detection value of the steam supply pressure sensor 62, which is set as the predetermined pressure, may be multiplied by an appropriate loss factor of 1 or less.

A case where the steam temperature is used as the warm-up completion condition will be described. The control unit 100 monitors the detected value of the exhaust steam temperature sensor 41, and determines that the warm-up is complete when the detected value of the steam discharged from the main body 11 reaches a predetermined temperature. The predetermined temperature in this example may be a set value such as the saturated steam temperature input to the control unit 100 in advance, or may be a detected value of the supply steam temperature sensor 61 arranged near the inlet of the main body 11 . Since the screw 12 is controlled not to rotate during the warm-up control, when the warm-up is sufficiently performed, the expansion of the steam is suppressed when it flows through the inside of the main body 11, and the energy loss is almost eliminated. Therefore, when the temperature difference between the vicinity of the inlet and the vicinity of the outlet of the main body 11 becomes substantially zero, it can be determined that the warm-up is completed. If an energy loss due to heat radiation is expected in the main body 11, the detection value of the supply steam temperature sensor 61, which is set as the predetermined temperature, may be multiplied by an appropriate loss factor of 1 or less.

A case in which time is set as the warm-up completion condition will be described. The control unit 100 monitors the elapsed time after it is determined that activation is permitted in step S101, and determines that the warm-up is completed when the elapsed time has passed a predetermined time.

The steam pressure, steam temperature, and time described above may be individually used as warm-up completion conditions, or may be combined as warm-up completion conditions. For example, when the exhaust steam pressure sensor 42 exceeds a predetermined value, it may be determined that the warm-up is completed. It is also possible to determine that the warm-up is complete when a predetermined time has elapsed since the start of the operation. In this embodiment, at least one of steam pressure, steam temperature and time is set as the warm-up completion condition.

After it is determined that the warm-up completion condition is satisfied, the normal operation is started (step S104). In normal operation, the opening of the steam supply valve 22 is controlled so that steam flows at a flow rate necessary for the screw 12 to rotate. For example, the detected value of the exhaust steam pressure sensor 42 is used as a feedback value, and the opening of the steam supply valve 22 is PID controlled so that this feedback value is maintained at the target value.

The flow from permission of activation to transition to normal operation has been described above. Next, a safety function for stopping the steam system 1 when a certain amount of drain or more occurs regardless of the operating state will be described. FIG. 5 is a flow showing detection control of drain exceeding the permissible value of the steam system 1 .

The control unit 100 constantly monitors the detection value of the drain detection unit 110, and determines whether or not the amount of drain has exceeded a preset allowable value (step S201). In the process of step S201, when the permissible value is exceeded, stop control is performed to close the steam supply valve 22 and stop the rotation of the screw 12 (step S202).

After the stop control, the control unit 100 monitors whether or not the allowable value of the drain detection unit 110 is exceeded (step S203). When it is detected in step S203 that the allowable value has been exceeded, the control unit 100 monitors whether or not a certain period of time has elapsed while the allowable value has been exceeded (S204). If a certain period of time has elapsed while the value remains below the allowable value, the state is shifted to a state in which activation of the steam expander 10 is permitted (S205). By making the start permission condition that the state of the drain exceeds the allowable value for a certain period of time, it is possible to reliably prevent the operation of the steam system 1 from being started when the drain exceeds the allowable value. After transitioning to activation permission, the process returns to step S201, and the processes after S202 are performed.

Here, the determination of the presence or absence of drain generation using the drain detector 110 can be replaced by detecting the temperature of steam flowing into the main body 11 . As described in the first example and the second example of start permission determination, when the detected value of the supply steam temperature sensor 51 or the detected value of the separator side temperature sensor 27 decreases and becomes less than the saturated steam temperature, condensation of steam occurs. As a result, drainage occurs. Therefore, in the process of step S201, if any of the detected values becomes less than the saturated steam temperature, the process proceeds to step S202, and stop control is performed to close the steam supply valve 22 and stop the rotation of the screw 12. to do After the stop control, the control unit 100 shifts to the process of step S203 and monitors whether the detection value of the supply steam temperature sensor 51 and/or the detection value of the separator side temperature sensor 27 has reached or exceeded the saturated steam temperature. . In the process of step S204, the control unit 100 monitors whether or not a certain time has passed while the detected temperature value remains equal to or higher than the saturated steam temperature. As described above, if the temperature of the steam pipeline is used to determine the presence or absence of drain, the drain detector 110 can be omitted, which contributes to the simplification of the steam system.

As described above, the steam system 1 of the present embodiment includes a main body 11 into which steam flows, a steam expander 10 having a screw 12 pivotally supported inside the main body 11, and a steam expander 10 which controls the temperature of the steam flowing into the main body 11. When the steam temperature detected by the supply steam temperature sensor 51 or the separator side temperature sensor 27 as a temperature detection unit for detection, and the steam temperature detected by the supply steam temperature sensor 51, the separator side temperature sensor 27, or both of them reaches or exceeds a predetermined temperature, the steam expander 10 and a control unit 100 that permits activation of the As a result, the condition for permitting activation of the steam expander 10 is that the temperature of the steam introduced into the main body 11 is equal to or higher than the predetermined temperature. 11 can be effectively prevented from flowing into the inside of the drain. In addition, it is possible to prevent the occurrence of a situation in which drainage occurs before the inside of the main body 11 is warmed at startup. Therefore, foreign matter (rust, etc.) in the piping enters the main body 11 due to the drain, and the structure (for example, the seal portion 13) around the shaft support portion of the screw (rotating body) 11 flows into the main body 11. It is possible to effectively prevent damage due to expansion.

Further, the steam expander 10 of the present embodiment has a steam supply pipe 20 connected to the main body 11 and a steam supply valve 22 arranged in the steam supply pipe 20. Then, the steam supply valve 22 is opened to shift to control to start supplying steam. As a result, it is possible to effectively prevent drain from flowing into the main body 11 when the steam expander 10 is started.

Further, in the present embodiment, the steam supply temperature sensor 51 is preferably arranged upstream of the steam supply valve 22 in the steam supply pipe 20 . As a result, start-up is permitted after no drain occurs inside the steam supply pipe 20 on the upstream side of the steam supply valve 22, so that more stable start-up of the steam expander 10 can be realized.

In addition, in the present embodiment, the steam system 1 includes a steam separator 21 arranged upstream of the steam supply valve 22 in the steam supply pipe 20, a steam trap 26 connected to the steam separator 21 via a drain pipe, Further prepare. A separator-side temperature sensor 27 is arranged in the steam separator 21 or the drain pipe 25 . In this embodiment, by monitoring the temperature of the steam separator 21 or the drain pipe 25, it is possible to set a condition for start-up as a condition in which there is no large amount of drain or poor discharge, and a more stable start-up of the steam expander 10 can be achieved. realizable.

In addition, the control unit 100 of the present embodiment performs warm-up control to control the steam supply valve 22 so as to allow steam to flow inside the main body 11 while maintaining the stationary state of the screw 12 as a rotating body. After machine control, the steam supply valve 22 is controlled so as to rotate the screw 12 . As a result, since the screw 12 is in a stationary state during the warm-up control, the screw 12 rotates with drain flowing into the main body 11, thereby changing the configuration around the shaft support portion of the screw 12 (for example, the seal portion 13). ) can be prevented from being damaged, and the inside of the main body 11 can be warmed up.

Further, the control unit 100 of the present embodiment repeats opening and closing of the steam supply valve 22 during warm-up control. By repeating the opening and closing of the steam supply valve 22 , it is possible to supply the steam necessary for warm-up to the steam expander 10 while maintaining the stationary state of the screw 12 .

In addition, the control unit 100 of the present embodiment maintains the open state of the steam supply valve 22 for a predetermined period of time at an opening degree that allows the screw 12 to remain stationary during the warm-up control. As a result, the drain accumulated in the steam supply valve 22 can be reliably discharged from the steam supply pipe 20 to the outside of the system without rotating the screw 12 .

The steam system 1 of the present embodiment further includes a rotation detector 14 that detects the rotation of the screw 12, and adjusts the opening degree based on the detected value of the rotation detector 14. FIG. As a result, the rotation of the screw 12 during warm-up control can be reliably prevented.

Further, the steam system 1 of the present embodiment further includes an exhaust steam pressure sensor 42 as a pressure detection unit for detecting steam pressure, and the control unit 100 detects when the detected value of the exhaust steam pressure sensor 42 reaches a predetermined pressure. can be used as a trigger to end warm-up control. As a result, it is possible to prevent the deterioration of the sealing performance due to the strain amount of the steam expander 10 that varies depending on the steam pressure. For example, in the case of using the seal portion 13 that is assumed to have a clearance of 0 by contact wear in the initial operation, if aging is performed by rotating the screw (rotating body) 12 in a low pressure state and then in a high pressure state, the amount of distortion of the seal material will increase. The clearance will increase due to the change. In this respect, according to the present configuration, it can be determined that there is no clearance due to strain when the steam pressure reaches a predetermined pressure, and the warm-up control can be terminated.

In addition, the steam system 1 of the present embodiment further includes an exhaust steam temperature sensor 41 as a temperature detector for detecting steam temperature, and the control unit 100 detects when the detected value of the exhaust steam temperature sensor 41 reaches a predetermined pressure. can be used as a trigger to end warm-up control. Thus, by setting the predetermined temperature to the saturated steam temperature, for example, it is possible to determine that no drainage occurs inside the main body 11, and to more appropriately determine the timing of warming up.

In addition, in the present embodiment, the control unit 100 can also terminate the warm-up control using the fact that the warm-up control has elapsed for a predetermined time as a trigger. As a result, it is possible to determine the timing for ending the warm-up control by a simple process of counting the predetermined time.

Further, the steam system 1 of the present embodiment includes a collective drain pipe 90 through which drain discharged from the main body 11 or the steam supply pipe 20 flows, and a drain detector 110 that detects the amount of drain flowing through the collective drain pipe 90. . The control unit 100 performs control to stop the steam expander 10 when the detection value of the drain detection unit 110 exceeds the allowable value. As a result, failure of the steam expander 10 due to rotation of the screw 12 in the presence of a large amount of drain exceeding the allowable value can be prevented.

In addition, in the present embodiment, the drain detector 110 includes a reservoir 111 to which the collective drain pipe 90 is connected, a discharge pipe 112 connected to the reservoir 111 for discharging the drain in the reservoir 111 to the outside, and a reservoir and a float switch 120 as a water level detection unit capable of detecting the water level inside the unit 111 . When the detected value of the float switch 120 indicates that it exceeds the allowable value, the control unit 100 performs control to stop the rotation of the screw 12 . Accordingly, it is possible to accurately determine whether or not the drain has exceeded the allowable value using the reservoir 111 .

In this embodiment, the drain detection unit 110 further includes an overflow pipe 113 connected above the discharge pipe 112 in the reservoir 111, and the float switch 120 detects a predetermined water level L at which the drain flows into the overflow pipe 113. be. As a result, with a simple configuration using the float switch 120, it is possible to realize the drain detection unit 110 that can detect whether or not the drain exceeds the allowable value.

Further, in this embodiment, the control unit 100 permits the rotation of the screw 12 after the lapse of a predetermined time when the detected value of the float switch 120 is below the allowable value. As a result, it is possible to prevent the steam expander 10 from being started while the drain remains.

Also, the drain detector 110 of this embodiment detects the total amount of drain from the first drain pipe 81 , the second drain pipe 82 and the third drain pipe 83 . As a result, one drain detector 110 can detect excess drain at a plurality of locations.

Further, in this embodiment, the control unit 100 closes the steam supply valve 22 and stops the rotation of the screw 12 when the detection value of the drain detection unit 110 exceeds the allowable value. As a result, even if the drain caused by the expansion of steam becomes excessive due to a malfunction or the like, this state is detected and the driving of the steam expander 10 is stopped. Failures can be prevented.

Here, regarding the control to close the steam supply valve 22 and stop the rotation of the screw 12, the determination of the allowable value using the drain detection unit 110 is based on the temperature of the steam flowing into the main body 11, for example, the temperature of the steam supply temperature sensor 51 and the separator. It can be substituted by detecting the detected value of the side temperature sensor 27 . As a result, it is possible to prevent troubles caused by drain flowing into the main body with a simple system configuration.

Next, a modified example in which a part of the configuration of the above embodiment is changed will be described. In the following description, the same reference numerals may be assigned to configurations that are common or similar to those of the above-described embodiment, and description thereof may be omitted.

In the above embodiment, the separator-side temperature sensor 27 is arranged in the drain pipe 25, but the configuration is not limited to this. For example, the separator-side temperature sensor 27 may be arranged below the steam separator 21 to determine whether the drain is stagnant inside the steam separator 21 . If a large amount of drain flows into the steam separator 21 in a short period of time, the drain will accumulate and the separation efficiency will be lowered.

Also, instead of providing the steam trap 26 outside the steam separator 21 , the steam trap 26 may be built in the lower portion of the steam separator 21 . In this case, the separator-side temperature sensor 27 may be provided at a position below the steam separator 21 and upstream of the steam trap 26 .

A configuration for detecting an abnormality in the steam trap can be added to the above embodiment. For example, a configuration may be adopted in which abnormality of the steam trap 26 is detected using the detected value of the separator-side temperature sensor 27 . In this configuration, the controller 100 determines that the steam trap 26 is abnormal when the separator-side temperature sensor 27 continuously detects a temperature drop caused by the drain accumulated and stagnated in the drain pipe 25 for a certain period of time. . In this configuration, an annunciator (not shown) that issues an alarm indicating that an abnormality has occurred in the steam trap 26 may be further arranged to quickly detect an abnormality in the steam trap 26 .

Furthermore, temperature detection units are arranged not only in the steam trap 26 but also in the primary piping of the steam traps 101, 102, and 103, and when the control unit 100 detects a temperature drop due to accumulation and retention of drain by the temperature detection units, the steam traps may be configured to determine that an abnormality has occurred.

Moreover, the completion conditions of the warm-up of the steam system 1 of the said embodiment are not limited to the above-mentioned conditions. For example, in addition to the steam temperature, it may be configured to determine whether or not the warm-up is completed based on the ventilation temperature of the steam system 1 (heat radiation temperature to the surroundings).

The configuration of the drain detector 110 of the above embodiment can be changed as appropriate. For example, the drain detector 110 can be replaced with a flow sensor. In this configuration, the control unit 100 determines whether or not the drain amount exceeds the allowable value based on the detected value of the flow sensor.

Although the screw-type steam expander 10 has been described as an example in the above embodiment, the screw-type steam expander 10 is not limited to this. For example, it may be a scroll type steam expander. In this case, the orbiting scroll is pivotally supported inside the main body as a rotating body, and the rotation detector detects the rotation of the scroll.

In the above embodiment, an example in which the steam expander 10 is the driven machine of the steam compressor 15 has been described, but the configuration is not limited to this. For example, a generator can be used as the driven machine driven by the steam expander 10 .

The example of the steam system 1 using the steam expander as the steam machine has been described above. Next, a case where a steam compressor is used as the steam machine will be described with reference to FIG. FIG. 6 is a diagram schematically showing a steam system 201 of a modified example.

The steam compressor 215 is a water addition type compressor provided with a motor 210 that rotates a rotating body (not shown) inside a main body 216 . Note that the steam compressor 215 may also be of a screw type or a scroll type, like the steam expander 10 of the above-described embodiment.

A main body 216 of the steam compressor 215 is supplied with steam from a boiler (not shown) through a steam supply pipe 220 . Also, cooling water is sprayed into the compression space of the main body 216 via a supply water pipe 230 . The steam that has flowed into the main body 216 is compressed by the rotation of the rotating body driven by the motor 210 and discharged from the steam exhaust pipe 240 . A drain separator (not shown) is arranged in the steam exhaust pipe 240, and the drain separated by the drain separator during operation of the steam compressor 215 is reused as cooling water. A steam supply valve 222 , a steam supply temperature sensor 51 and a steam supply pressure sensor 52 are arranged in the steam supply pipe 220 . An exhaust steam pressure sensor 42 is arranged in the exhaust steam pipe 240 . Each detection value of the supply steam temperature sensor 51 , the supply steam pressure sensor 52 and the exhaust steam pressure sensor 42 is transmitted to the control unit 100 .

When the operation of the steam system 201 is started, the controller 100 opens the steam supply valve 222 to start steam flowing into the main body 216 of the steam compressor 215, and the steam temperature detected by the steam supply temperature sensor 51 rises. Monitor whether or not the temperature is equal to or higher than a predetermined temperature. When it is detected that the steam temperature has reached a predetermined temperature or higher, the control unit 100 determines that the activation permission condition for permitting rotation of the motor 210 is satisfied, and drives the motor 210 to start rotating the rotating body. Let As a result, it is possible to effectively prevent drain from flowing into the main body when the motor is started.

In this modification, the drain generated in the main body 216 of the steam compressor 215 is discharged to the outside of the main body 216 through the drain pipe 290 . A drain detector 310 configured by a flow sensor is arranged in the drain pipe 290 . The drain pipe 290 may be connected to the drain pipe of the drain separator so as to join the drain discharged from the drain separator.

A detection value of the drain detection unit 310 is transmitted to the control unit 100 . When a large amount of drain flows into the main body 216 through the steam supply pipe 220, the motor 210 is stopped when the detected value of the drain detector 310 exceeds the allowable value. The water addition compressor cools the rotating body by spraying cooling water into the compression space and evaporating the mist adhering to the surface of the rotating body. Therefore, if drain other than cooling water flows into the compression space, a water film is formed on the surface of the rotating body, hindering the mist from evaporating, resulting in poor cooling of the rotating body. In this modified example, even if drainage other than cooling water flows into the main body 216 of the steam compressor 215, this state is detected and the steam compressor is stopped. It is possible to prevent such failures from occurring. Note that the drain detector 310 may have the same configuration as the drain detector 110 described in the embodiment in which the steam machine is the steam expander 10 .

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments and modifications, and can be modified as appropriate.

1,201 steam system 10 steam expander (steam machine)
11 main body 12 screw (rotating body)
20 steam supply pipe (steam pipe)
21 Steam Separator 22 Steam Supply Valve 25 Drain Pipe 26 Steam Trap 27 Separator Side Temperature Sensor (Temperature Detector)
51 supply steam temperature sensor (temperature detection unit)
100 Control Unit 210 Motor 215 Steam Compressor (Steam Machine)
216 main body 220 steam supply pipe (steam pipe)

Claims (6)

a steam machine having a body into which steam flows and a rotating body pivotally supported inside the body;
a steam supply pipe through which steam introduced into the steam machine flows;
a steam supply valve disposed in the steam supply pipe;
a first drain pipe connected to the steam supply pipe on the upstream side of the steam supply valve;
a first steam trap disposed in the first drain pipe;
a first temperature detection unit for detecting the temperature of steam flowing into the main body in the steam supply pipe upstream of the connecting position of the first drain pipe ;
a control unit that, when the steam temperature detected by the first temperature detection unit reaches or exceeds a predetermined temperature, permits the start-up of the steam machine , opens the steam supply valve, and shifts to control to start supplying steam to the main body; , and
The steam system, wherein the predetermined temperature is a temperature indicating a state in which drain generated in a cold state is discharged from the first steam trap and the steam supply pipe is filled with steam. a steam machine having a body into which steam flows and a rotating body pivotally supported inside the body;
a steam supply pipe through which steam introduced into the steam machine flows;
a steam supply valve arranged in the steam supply pipe;
a steam separator arranged upstream of the steam supply pipe;
a drain pipe connected to the steam separator;
a steam trap disposed in the drain pipe;
a temperature detection unit for detecting the temperature of the steam flowing into the main body in the drain pipe upstream of the steam separator or the steam trap ;
a control unit that, when the steam temperature detected by the temperature detection unit reaches or exceeds a predetermined temperature , permits the start-up of the steam machine, opens the steam supply valve, and shifts to control to start supplying steam to the main body; prepared ,
The steam system, wherein the predetermined temperature is a temperature indicating a state in which drain generated in a cold state is discharged from the steam trap and the steam separator is filled with steam. After opening the steam supply valve, the control unit performs control to close the steam supply valve and stop the rotation of the rotating body when the detected temperature of the steam flowing into the main body becomes lower than the predetermined temperature. Steam system according to claim 1 or claim 2 . 4. The steam system according to any one of claims 1 to 3, wherein said predetermined temperature is set to a saturated steam temperature. The steam system according to any one of claims 1 to 4, wherein the steam machine is a steam expander that expands steam. The steam machine is a steam compressor that compresses steam, and has a motor that rotates the rotating body,
3. The steam system according to claim 1 , wherein the controller starts driving the motor when the steam temperature reaches or exceeds the predetermined temperature.

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