KR890001727B1 - Turbine high pressure bypass temperature control system and method - Google Patents

Abstract

Steam turbine bypass system inclined where the temp. of the steam bypassed around the high pressure tubine is controlled by measuring the inlet and outlet temps. of the boiler reheatey and generating an adaptive set point. The set point value is used to govern operation of a spray valve which admits cooling water to the bypass steam path. The bypass system also includes a throttle pressure control wherein the outlet throttle pressure of the boiler is controlled by controlling admission of steam into the bypass path by means of bypass valve independently of steam flow during turbing start-up.

Description

Bypass unit for steam turbines

1 is a simplified block diagram of a steam turbine power plant including a bypass system.

FIG. 2 is a partial view of FIG. 1 for illustrating a conventional exemplary bypass control device. FIG.

3 is a block diagram illustrating an embodiment of the invention.

4 is a more detailed block diagram of the apparatus of FIG.

4 (a) is a block diagram showing the alternating tracking arrangement shown in FIG.

5 is a block diagram of a typical control circuit of FIG.

6 is a detailed block diagram of a method of initiating bypass operation.

FIG. 7 is a diagram showing a curve of a boiler load throttling pressure characteristic for sliding pressure operation. FIG.

8 is a block diagram showing the generation of a pressure setpoint by a draw as a function of load.

FIG. 9 is a block diagram showing the sympathetic bias arrangement shown in FIG.

FIG. 10 is the same as the curve of FIG. 7 showing the bias arrangement of FIG.

11 is a block diagram of another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: steam turbine 18: generator

22: boiler 24: heater

50: pump 60: boiler control unit

62 turbine control unit 64 master control circuit

78: low pressure bypass valve 84: high pressure spray valve

86: low pressure spray valve 90: high pressure valve control circuit

92 low pressure valve control circuit 106 operation circuit

114: high pressure valve operation circuit 120: control circuit

124: temperature converter 140: spray valve control circuit

144: target setpoint circuit 164: addition circuit

170: memory 180: differential circuit

184: selection circuit 200-1: control circuit

The present invention relates generally to steam turbine bypass devices, and more particularly to a control device for regulating temperature and / or pressure in the high pressure section of the device.

In operation of a steam turbine power plant, the boiler generates steam provided to the high pressure turbine via a number of steam inlet valves. The steam passing through the high-pressure hollow section is reheated and then fed to the low-pressure turbine section before being fed to the booster turbine in a conventional reheater, where it is directed to a condenser which is converted as well as the vapor discharged therefrom and then complete It is fed to the boiler for circulation.

Conventional fossil fuel steam generators or boilers could not be instantaneously operated. If a load rejection inevitably causes a turbine trip while the turbine is running, steam will normally be generated in the boiler to the extent that the pressure increase will normally cause the various safety valves to operate. Can be.

In this system, the steam is treated to maintain steam purity in the range of about 1 billion parts, meaning that the discharge of treated steam represents a large waste.

Another economic consideration in the operation of steam turbines is fuel costs.

Due to the high fuel costs, some turbines are intentionally shut down, for example during periods of low late night electricity demand, so that the turbine remains relatively hot in the morning while the steam supplied to the boiler is relatively low. High temperature restart problems are encountered. If steam at a relatively low temperature enters the turbine, the turbine is subject to thermal shock, which can shorten the useful life of the turbine. To remove this thermal shock, the steam must enter the turbine very slowly, whereby the turbine cools to the steam temperature and is then gradually loaded. This process is not only long but expensive.

By addressing load exclusion and high temperature restart problems, a bypass device is provided to enhance on-line availity, get fast restarts, and reduce turbine reverse circulation consumption. Basically, the steam box and valves going to the turbine in bypass operation can be closed while steam is generated by the boiler. The high pressure bypass valve opens to divert the steam around the high pressure turbine and provides the pressure of the reheater. The low pressure bypass valve allows steam from the reheater to be diverted to the medium and low pressure sections and provided directly to the condenser.

Normally, the turbine extracts heat from the steam and converts it into mechanical energy. During the bypass operation, the turbine does not extract heat from the bypassed device. As the increased temperature of the steam can damage the reheater and condenser, relatively cold water is injected into the high and low pressure bypass steam passages to prevent overheating of the reheater and condenser. The amount of sprayed water injected into the high pressure bypass steam passage is controlled by a temperature controller. In a conventional temperature control device, the controller tests the temperature at the input of the reheater, compares it with a constant reference value or target set point, and makes a decision that requires a lot of effort and time. Various test runs must be made in the boiler system and the set points determined from these tests are coarse and not optimal for all operating conditions.

The outlet throttling pressure of the steam generator can be controlled by the control of the bypass device under various operating conditions. Conventional controls are subject to steam flow and cannot be operated in various pressure modes useful for boilers.

It is an object of the present invention to provide an improved bypass unit for steam turbines to control temperature and / or pressure and thus to minimize thermal stress on turbines and boilers.

The apparatus of the present invention relates to a bypass device for a steam turbine having a steam generator, comprising a steam generator, a high pressure turbine, a reheater in the steam flow passage between at least one low pressure turbine and a high pressure and low pressure turbine, and a steam bypass passage. The high pressure bypass valve in this bypass passage is a device for flowing into the bypass passage of steam.

The apparatus of the present invention comprises a device for controlling the high pressure bypass valve device in response to a predetermined pressure, a device for measuring the temperature of the steam at the pressure and output of the reheat to provide an indication of the respective cold and hot reheat temperature signals; Characterized by having a device for controlling the temperature of the steam passed by the high pressure bypass device as a function of the cold and high reheat temperature signals.

Further improvements in steam temperature and / or pressure control are those that drive to provide fast or poor control under certain conditions and fast control to provide controlled or slow control under other conditions. Is achieved by.

Hereinafter, with reference to the accompanying drawings of the present invention will become more apparent through exemplary embodiments.

1 is a simplified block diagram of a single nuclear fission reheat turbine generator.

In the conventional steam turbine power plant as shown in FIG. 1, the turbine apparatus 10 is configured in the form of a high pressure (HP) turbine 12, a medium pressure (IP) turbine 13, and a low pressure (LP) turbine 14 It has a plurality of turbines. The turbines are connected to the common shaft 16 to drive a generator 18 that supplies power to the load (not shown).

A steam generator such as a conventional drum-type boiler 22 operated by fuel generates steam heated by a heater 24 to an appropriate operating temperature and is supplied to the high-pressure turbine 12 through a throttling header 26. The steam flow is guided and controlled by a set of steam through valves 28. Although not shown, other devices may include, for example, super and subcritical-once-through boilers.

The steam via the high pressure turbine 12 and the steam line 31 is directed to the reheater 32 (heat transfer in relation to the boiler 22) and then the steam is passed through the steam line 34 to the low pressure turbine 14. The steam from the steam turbine is guided to the condenser 40 through the steam line 42 is converted into water. The water is fed back to the boiler 22 via the water line 44, the pump 46, the water line 48, the pump 50, and the water line 52. Although not shown, a water treatment device is generally provided in the return line, to maintain a precise chemical balance and high purity of water.

Normal boiler 22 operation is performed by the boiler control unit 60 and the turbine valve devices 28 and 36, together with the control units 60 and 62 connected to the boiler and its plant master controller 64. It is controlled by the turbine control unit 62. A turbine bypass device is provided to optimize hot restarts and extend the life of the turbine and boiler device to improve on-line usability, and a turbine bypass device is provided to extend to the boiler 22, the boiler 22 The steam from) is actually bypassed but proceeds as if the steam is still being used by the turbine. The bypass passage includes the steam line 70 and influences the initial treatment of the high pressure bypass by the operation of the high pressure bypass valve. The steam passed by the valve 72 is directed to the input of the reheater 32 via the steam line 74 and the stream of steam reheated in the steam line 76 passes the steam via the steam line 80. Controlled by a low pressure bypass valve 78 through which steam going to line 42 passes.

In order to prevent overheating of the reheater 32, in order to compensate for the loss of heat extraction normally provided by the high pressure turbine 12, a pump 50 is provided and relatively coolant in the water line 82 is provided with a high pressure spray valve ( 84 is provided to the steam line 74 under control. Other arrangements may include directing the cooling flow directly to the valve arrangement. In a similar fashion, relatively coolant in the water line 85 from the pump 46 is utilized to cool the steam in the steam line 80 to prevent overheating of the condenser 40 and to the low pressure turbine 14. To compensate for the loss of heat extraction normally provided. A low pressure spray valve 86 is provided to control the flow of such spray water and a control is provided to control the operation of all the valves of the bypass device. Moreover, the high pressure valve control device 90 has a second circuit arrangement for controlling the operation of the high pressure bypass valve 72.

Similarly, low pressure valve control 92 is also provided to control the operation of low pressure bypass 78 and to control the operation of low pressure spray valve 86. An improved low pressure bypass spray valve is described in US Pat. No. 321,160, assigned to the applicant of the present invention and filed on November 13, 1981.

Typically, a conventional high pressure control device is shown in more detail in FIG. 2, similar to the portion of FIG. 1 with a conventional control device.

Initiation of the bypass operation may be performed by comparing the throttling pressure target set value with the actual throttling pressure to operate to generate a control signal for the high pressure bypass valve 72 with the deviation of these two signals. Furthermore, the pressure transducer 100 in the steam passage generates a signal proportional to the actual throttling pressure and provides this signal to the control circuit 102 on line 101. The actual throttling pressure signal on line 101 is provided by associating circuit 106 in comparison with the throttling pressure target set point signal induced in line 104. One input of the computational circuit is a signal on line 108 which is an indication of steam flow as a signal obtained by irradiating pressure from the pressure reducing section 110 in the steam line. The indication of this flow is modified by various components and the maximum and minimum allowable pressure valves are included by the induction of the setpoint valve. These modifying components are provided to the computing circuit as indicated by arrow 112.

In response to a deviation between the two inputs to the control circuit 102, a control signal is provided to the high pressure valve actuation passage 114 for controlling the movement of the high pressure bypass valve 72. In this arrangement, the setpoint pressure target value depends on the steam flow. As the load changes, the steam flow changes as the set point changes. Operation of the bypass or turbine system can change the steam flow. In turn, it affects the throttle pressure target set point and iteratively affects the turbine or bypass system.

With respect to the operation of the high pressure spray valve 84, the control circuit 120 is connected to the high pressure spray valve drive circuit 122 to control the cooling spray operation according to the actual temperature at the input of the reheater 32 as compared to the temperature set point. Provide control signals.

The reheater input temperature, commonly known as coolant heating temperature, is the input to the control circuit 120 and the other input on line 126 is the set point temperature derived from, for example, the turbine master control circuit.

Setpoint calculations take a lot of time and effort to show empirically derived compromised values rather than the optimal optimum for all operating conditions. In contrast, the present invention provides an applicable set point derived as a function of certain system parameters for the calculated temperature control, for which purpose the control device shown in FIG. 3 is shown by reference.

In addition to the temperature converter 124 providing a coolant heating temperature signal on line 126, the reheater 32 for providing a temperature signal on line 136 where the apparatus of FIG. 3 additionally has a high reheating temperature indication. It includes a temperature converter 134 located at the output of. The spray valve control circuit 140 responds to the coolant heating temperature signal on the line 126 to control the operation of the spray valve 84 with a control signal on the line 142 to the other valve drive circuit 122 to heat the coolant. Respond to a set point on line 141 for control.

Compared with the prior art, the setpoint signal on line 141 is applicable to system joggers rather than a pre-calculated setpoint and is generated by the application setpoint circuit 144.

The application set point circuit 144 responds to the cold and cold heating temperature signals of lines 126 and 136, respectively, and to external signals on lines 146 and 147, respectively.

The spray valve controller responds to certain pressure conditions and a pressure control circuit 150 is provided for this purpose. Although not limited to the present invention, the pressure control circuit 150 is preferably described with reference to FIG. This operation can be understood with reference to FIG. 4 in more detail.

Target Set Point Circuit (144)

The target set point circuit 144 is a proportional integral (PI) control circuit 160 which receives a signal on the line 162 provided by the addition circuit 164 as a second input and a dead heating temperature signal on the line 136 as one input. ). Since the PI control circuits are also used in the spray valve circuit 140, a brief description of their operation is described in FIG.

The PI controller receives two signals on each of inputs A and B, takes the difference between the two signals, applies a gain K to the difference, derives the signal applied to the integral of the signal, and makes it a control signal at output C. The control circuit of FIG. 5 additionally limits the output signal to a certain maximum value in accordance with the value of the limit signal applied to lead D and for any minimum value according to the value of the low limit signal applied to lead E. It includes a high / low limiting unit 143 for limiting the output signal. Alternatively, high and low limits can be chosen by the internal circuitry for this controller. When the zero voltage signal is placed on the lead D, the output signal will be fixed at zero voltage. A suitable output signal will be provided if lead D is provided with a signal of higher than appropriate value.

When the required signal to be tracked is supplied to the controller at lead F and the traceable signal is applied to lead G, the controller operates the second mode of operation shown at output C. At any moment, the proportional integral operation on the difference between the two signals of inputs A and B is decoupled from the output. The PI controller pursues widespread use in the control area and its operating embodiment is commercially available from Westinghouse Electric Corporation, the same as the G06 type 7300 series controller. If a PI function is required, it can be implemented by a microprocessor or other type of computer.

In FIG. 4, lines 136 and 162 of controller 160 constitute the first and second inputs (A) (B) of FIG. 5 and are lines G and the signal to be followed is fifth. It appears on the line 126 corresponding to the line F of FIG.

Target setpoint circuit 144 additionally includes a storage device such as memory 170 that is operable to store a high reheat temperature when the device is in bypass operation. The stored high reheat temperature value is provided on the line 172 as an input of the addition circuit 164, and a time function circuit 176 for gradually inclining any input signal on the line 178 from the differential circuit 180. To another input on line 174 derived from. The differential circuit 180 is a signal on line 182 that is a stored high reheat temperature from line 172 and a low value signal from line 147 or line 146 selected by low value signal selector 184. Provide an output signal that is the difference between.

The grain boundary circuit device 186 provides a possible signal on the bypass operation in response to the output signal on the line 152 from the pressure control circuit 150 to operate as follows. a) Instructs the memory 170 to maintain the solidus heating temperature value. b) Release the time function circuit 176 for operation. c) enable control circuit 160. The NOT circuit 188 provides a traceable signal on the line 168 when there is no function signal from the threshold circuit 186, and eliminates the followable signal when there is an output signal from the threshold circuit device 186. do.

Operation of the target setpoint circuit 144

For technical purposes, at some point in the operation of the steam turbine, the turbine trip will inevitably cause the steam barrel and valve to close and start the bypass operation. Also, for illustration purposes, the cold ash heating temperature is 900 ° F and the solid ash heating temperature is 1000 ° F due to the heat imparted in the reheater.

At the start of the bypass operation, a signal on line 152 from pressure control circuit 150 causes threshold circuit 186 to provide a possible signal such that memory 170 stores a 1000 DEG F. heating temperature. do.

In the conventional bypass operation, the control circuit 160 follows the cold reheating temperature on the line 126 so that the output signal on the line 141 represents the cold reheating temperature and maintains until the input of the control circuit 160 changes. will be.

Therefore, in this regard, the control circuit 160 serves as a storage device for the cold reheating temperature. In this respect the actual cold heating temperature signal on line 126 and the target set point signals on line 141 are the same and thus no output signal is provided by spray valve control circuit 140 which will be described later herein.

The input signal on line 136 of control circuit 160 is the actual solid heating temperature. The control circuit 160 additionally receives an input signal on the line 162 from the addition circuit 164. The output of the time function circuit 176 does not instantaneously convert on bypass operation. The addition circuit 164 thus provides the same output signal as the input signal on the line 172, i.e. the stored reheat temperature.

Ignoring the operation of circuits 176, 180 and 184 for the time being, the inputs on lines 162 and 136 of control circuit 160 are the same that do not cause a change in the output signal and the target set value is Keep it before the pass action. If the turbine operates again, the temperature will have been prior to the turbine trip and normal operation will continue.

Let high or cold heating temperatures change something because of some circumstances.

For example, the gain of reheater 32 may vary. If the cold heating temperature changes, it no longer matches the previously memorized value on line 141 so the imbalance is peaked by actuating spray valve control circuit 140. If the high reheat temperature changes, the input on line 136 of control circuit 160 is changed to equal the previously stored high reheat temperature on line 162 and therefore the input on line 136 of controller 160 is changed. Since it is not equal to the previously stored high reheat temperature on line 162, controller 160 will therefore change the target set point signal and cause an imbalance in the input signal of spray valve control circuit 140 and subsequent correction action therefrom. The corrective action will change the cold reheat temperature to maintain the high reheat temperature at the previously memorized value.

As an example, it will also be considered that the bypass operation is initiated at one point when the situation is for example a high reheating temperature of 980 ° F but the actual required temperature for good thermal efficiency is 1000 ° F. In such a case, the 1000 ° F. for which a signal value is required may be provided on line 147 and may be supplied by the turbine control unit 62 (FIG. 1) automatically by driver intervention or automatically. In this regard, the signal on line 146 is a signal on line 182, which is also an indication of the required 1000 ° F. temperature, to a maximum value that may be an indication of the 1000 ° F. temperature required for low value signal selection circuit 184 to occur. To rise. In the example under consideration, a solid heating temperature of 980 ° F is stored at the beginning of the bypass operation and provided to the addition circuit 164 and the 980 ° signal on the output line 172 is 20 ° F (1000 ° -980 ° F) differential. A signal indication is provided to differential circuit 180 to provide a time function circuit 176 at an input on line 178. Since this time function circuit is released for operation, it will incrementally provide an increasing output signal on line 174 of adder circuit 164 to which the previously stored 980 [deg.] F. value signal on line 172 has been added. Since thermal stress should be avoided, this signal on line 162 is a very low application set point on line 141 to initiate a corrective action that increases the cold ash heating temperature to a point equal to the solid ash heating temperature, such as the required 1000 ° F value. It is increased at very low values, to change at.

Thus, an example of temperature control has been described. The first example describes the maintenance of the same temperature condition and the second example describes the rise to the new temperature commanded by the temperature set point on line 162 from the turbine control unit 62. Is generated.

In the third situation, the restart that will be described will be considered. Suppose the turbine unit is shut down at night (the turbine will spin very slowly to prevent rotor twisting, but if it is restarted the next morning, then the boiler will cool relatively low in the morning). Because of the large metal structure, the turbine cools, but is relatively higher than the boiler, for example, the solids heating temperature in the morning may be 600 ° F. The metal part temperature of the turbine will be correlated to the steam temperature introduced, for example, at 950 ° F.

In the morning, the bypass operation begins and then the memory 170 returns 600 ° F and the reheat temperature and the turbine control unit is requested by the driver or automatically on line 147 of the low value signal selection circuit 184. The 950 ° F value is applied to the differential circuit 180 resulting in an output difference signal of 350 ° F applied to the time function circuit 176 and raised to the maximum value. This differential signal causes an increase in the adaptive setpoint on line 141, the steam pass valve opens, the turbine rises to rated speed, and then the setpoint signal on line 147 does not require 1000 [deg.] F. of the corrective operating temperature. While increasing to a value, it is gradually raised to a suitable temperature.

Under certain operating conditions, it is desirable or necessary to modify the solids heating temperature in accordance with certain boiler considerations. Thus, the reheat temperature set point can be applied to line 146 of the low value signal selection circuit 184 and radiate from the boiler control unit (FIG. 1). When not in use, this reheat temperature setpoint signal is raised to the maximum value of the signal and maintained to allow the setpoint signal on line 147 to be selected for control purposes as described above. The setpoint signal is maintained at the required temperature indication, and in the previous example, this temperature indication is actual and higher than the reheating temperature, but under various operating conditions the required temperature may be lower than the actual temperature so that the differential circuit 180 is negative. Value output signal. It is to be understood that the time function circuit 176 will provide increasing gradually in the negative direction against the difference from the stored high reheat temperature indication on the line 172.

Accordingly, the target setpoint circuit 144 provides a target setpoint signal on the line 141 during the bypass operation to control the cold ash heating temperature during normal operation or through the operation of the spray valve circuit 140, thereby causing a high value at a predetermined value during startup. Maintain the reheat temperature.

Spray Valve Circuit (140)

The spray valve circuit is a dual proportional integral that is each control circuit 200-1 and control circuit 200-2 of the control circuit that receives the cold ash heating temperature signal on the line 126, such as the target set point signal on the line 141. Control circuits. One of the control circuits 200-1 or 200-2 will be able to control the operation at any one time.

If possible, control circuit 200-1 will provide a suitable output signal on line 202 and when enabled, control circuit 200-2 will provide an output signal on line 203. The control circuits 200-1 and 200-2 are identical to the control circuits described above with reference to FIG. 5.

The output signal on the line 202 from the control circuit 200-1 will be supplied to the addition circuit 206 like the signal on the line 203 from the control circuit 200-2. Moreover, the output signal from the control circuit is input to the control circuit as a signal to be followed to reduce the output signal of the other control circuit when each control circuit is in the tracking mode.

Both controllers are identical to the control circuit described in FIG. 5, but they have different time constants. That is, when the control circuit 200-1 is selected to operate, it will apply an output response as a result of the imbalance in the input signals on lines 126 and 141. This output response is faster than the control circuit 200-2 when the control circuit 200-2 is selected to operate. If ten thousand and one control circuits to analog circuits, the integrated circuit of the control circuit 200-1, the control circuit 200-2 may, gatneunde time constant than the time constant can have a TC ₂ TC ₁ TC ₁ TC ₂ is more small.

Rather than having a single control circuit with a single response for all operating conditions, the control circuit of the present invention is selected depending on whether the device is started or not and is wholly operational. Therefore, the fast time constant control circuit 200-1 is selected for the situation where there is no bypass operation and provides a fast response time for the load removal situation, while the controller 200-2 has a slow response time to start up the situation. Can be selected for.

The choice that the control circuit tracks while the other control circuit responds to the input signal can be achieved by the application of the appropriate signal at terminal 210, which is either a manually or automatically initiated signal. The application of the binary signal in the first logic state acts as a followable signal on line 212, and with the presence of circuit 214, the signal on followable line 212 provided above is controlled by the control circuit 200-1. The control circuit 200-2 follows the output signal on the line 202 and outputs on the output line 203 while being reacted to any rapid load removal causing an imbalance in the input signals on 126 and 141. Repeat the signal. Application of the previous signal in the opposite logic state of terminal 210 reverses the role of the control circuits and causes the control circuit 200-1 to follow the output signal on line 203 from control circuit 200-2. The output on (202) is repeated.

The control circuit cannot be operational until it is provided with a possible signal on line 220 which is an indication of the bypass equivalent, where pressure control circuit 150 provides an output signal on line 152. This signal is in turn provided to a high gain circuit 222 which provides a possible signal.

Operation of the Spray Valve Control Circuit 140

Assume that the bypass operation is made to operate the control circuits 200-1 and 200-2. If the bypass operation occurs in the start-up period, the control circuit 200-2 controls and the control circuit 200-1 controls the control circuit 200-1 if the turbine to follow is fully operated. 200-2) follow.

If the cold reheat temperature on line 126 or the application set point signal of line 141 changes, as described above, the control circuit under command will respond to the difference between these two signals and vapor in steam line 74. The cold air heating temperature is controlled through the spray operation, thereby providing an output signal utilized to close or open the high pressure spray valve 84 to ultimately control the high heating temperature.

The addition circuit 206 is of a type that provides an output signal that is half the sum of the input signals of the circuit. If the control circuit 200-1 provides a signal of a value on the output line 202 in response to the input difference of the controller, this signal is a control circuit that provides the same signal on the output line 203 in the tracking mode ( To the addition circuit 206 as applied to 200-2. Therefore, half of the sum of input signals to the addition circuit 206 results in an output signal from that circuit on line 142. With this structure, the control function can be arranged by another controller, which maintains the same output signal on line 142 to allow for conflict-free movement of control.

Alternatively, the same tracking and collision-free movement may be achieved by connecting the output signal from the addition circuit 206 to the tracking inputs of the controllers via line 208 as described in FIG.

If necessary, initiation of the bypass operation can be utilized to open the spray valve 84 up to some predetermined position at the earliest to rapidly inject spray water for temperature control. This predetermined position may not be accurate for the required microfouling control and therefore the position is modified by the output of the spray valve control circuit 140. For this purpose, an addition circuit 224 and a proportional amplifier 226 are provided. In response to any output signal of line 152 from pressure control circuit 150, proportional amplifier 226 sends appropriately calculated signal to adder circuit 224 to begin scaling of spray valve 84. Will provide. The output signal on line 142 is also added to the addition circuit 224 to subtract or add from the signal provided by the amplifier 226 to allow fine adjustment of the spray valve 84 for precise temperature control as described herein. Is provided.

Pressure control circuit (150)

The high pressure control circuit 150, shown in detail in FIG. 6, is a circuit that nominates when the system is bypassed and when the throttling pressure of the boiler should be properly controlled to a predetermined value. Acts independently. The boiler throttling pressure is equal to the pressure applied to the input of the bypass system and to the steam passage valve 28.

The pressure control circuit 150 includes first and second proportional integral control circuits 240-1 and 240-2, each of which outputs an output signal to each line 242 and 243 of the addition circuit 246 shown in FIG. to provide. In addition, as shown in FIG. 4, an output signal generated from each control circuit is supplied to another control circuit to follow the output signal of the other control circuit when each control circuit is in the tracking mode state.

The following control circuit is determined when a suitable signal initiated manually or automatically is applied to terminal 248 by another control circuit.

If the first logic state signal of the binary signal operates as an enabling signal that is followed in line 250, the NOT logic 252 causes the second logic state signal of the binary signal to follow the enabling signal in line 254. Provided.

The control circuit 240-1 has a time constant TC ₃ , and the control circuit 240-2 has a time constant TC ₄ greater than TC ₃ . Therefore, the control circuit 240-2 is selected for control purposes in a situation where a relatively late reaction time is required, such as a start operation, while the controller 240-1 having a relatively fast time constant is used in a fast shed state. It is used in situations where fast response time is required.

Contrary to the control circuit arrangement of FIG. 4, the control circuit of FIG. 6 does not have the same input. Only one input is common to both control circuits and the input signal is provided on line 101 as the actuation throttling pressure signal provided by pressure transducer 100. The other input of the control circuit 240-2 is provided to the line 260 as an throttling pressure target set point signal provided by the process independent set point generator 262. In order to prevent the high pressure bypass device from opening during normal turbine operation, the fast load removal control circuit 240-1 displays a predetermined throttle pressure setpoint and some bias values at its second input on line 264. Has a signal. To increase this bias value, there must be a bias amplifier 268 that receives a predetermined throttling pressure target setpoint signal on line 260 and adds any preselected bias to that signal.

After the initial ignition, many boiler units operate at a constant throttling pressure independent of the boiler load.

For example. In constant pressure systems operating at 2400 pounds per inch (P.S.I) throttling pressure, if the load changes due to pressure change, some fuel should be replenished to the boiler to maintain a constant pressure as a function of load. Thus, in a constant pressure system, the throttling pressure target set point generator 262 may be any device or circuit that provides a constant output voltage indicative of a desired throttling pressure.

Basically this function can be performed by a simple potentiometer. Boilers other than the ones described above operate in sliding pressure mode instead of operating with throttling pressure, where the throttling pressure varies between minimum and maximum values as a function of load, and this type of boiler has good fuel efficiency and high turbine Results in temperature.

By way of example, a typical sliding pressure curve is shown in FIG.

In FIG. 7, the solid line 280 represents the boiler throttling pressure with respect to the boiler load, with the horizontal axis representing the percentage of boiler load and the vertical axis representing the static throttling pressure expressed in (PSI).

Operation of the boiler maintains the minimum pressure at which the throttling pressure reaches any load La on the break point 282 side. The throttling pressure then linearly increases linearly with the load up to the break point 283, ie load Lb. The throttling pressure is then kept constant at any maximum value. If some constant bias B is added to the boiler throttling pressure, it becomes like curve 286 shown in dashed lines. The boiler characteristic curve is well known as the curve that generates the throttle pressure target setpoint. One method performed in various steam turbine generator power plants is shown in FIG.

Circuit 290 provides on line 29 an output signal indicative of the appropriate set of throttling pressure target values as a function of the input signal on line 294 indicating the indication of the load, the characteristic curve described by way of example in FIG. Provides a setpoint signal according to Suitable load signals are generally provided by the load request computer 295 although other controls such as facility masters may provide the load signals separately.

Rated limiting circuit 296 is provided to mitigate the load factor of the throttle pressure target setpoint during fast load displacement to counteract fast load changes in the process and to maintain pressure changes within an acceptable range.

Accordingly, the throttling pressure target setpoint generator 262 generates a predetermined throttling pressure target setpoint by the sliding pressure type operation according to the curve of FIG. 7, which is a commanded setpoint completely separate from the steam flow. Independent setpoints in the process can be carried out in a constant pressure time displacement mode or in an effective valve position mode where the constant pressure changes with time in other boilers, where the throttling pressure as a function of the load is clipped to the sawtooth type Depends on.

Operation of the pressure control circuit 150

Assuming that a 30% boiler load is required to match the turbine to the desired temperature at the start of the high temperature restart operation, one way to perform this operation is to apply a predetermined throttle to apply the characteristic curve of FIG. 7 for a given boiler load condition. The pressure target set point must be selected. Initially, the bypass valve 72 and the turbine steam cylinder and valve are in a closed state, and the throttling pressure increases accordingly as measured by the pressure transducer 100 when the boiler is ignited. When the operating throttling pressure signal on the line 101 approaches a predetermined throttling pressure signal on the line 101, the control circuit 240-2 selected by the control action by the appropriate signal applied to the terminal 248 is predetermined. The bypass valve 72 is sent to an open position where the actuation frame pressure is in equilibrium to provide an output signal for 30% of the boiler steam capacity to pass through the bypass unit.

When the throttling pressure target set point is changed for some reason, the control circuit 240-2 further opens or closes the bypass valve 72 so that the working throttling pressure changes. Although the control circuit 240-1 and the control circuit 240-2 are similar to the control circuit described above, there are slight differences in operation with respect to the limit value imposed as an output signal. Specifically, the control circuit 240-2. Input lines 101 and 260 of have positive (+) and negative (-) signals, respectively. If the input signal on the positive line is greater than the signal on the negative line, control circuit 240-2 provides a positive output limited to some predetermined positive voltage. If the signal of the negative input line is greater than the signal of the positive input line, the output signal of the control circuit 240-2 is reduced to the low limit value of 0 volts, but the output of the control circuit 240-2 is It is not negative. This operation is also the same in the control circuit 240-1.

Therefore, when the predetermined throttling pressure target setpoint signal decreases, the control circuit 240-2 provides an output signal for opening the bypass valve 72 to reduce the operating throttling pressure and, when the setpoint signal increases, the control circuit. The output of 240-2 is reduced to close the bypass valve (zero volts) to increase the actuation pressure.

If at any point the steam treatment process is initiated, steam is introduced into the turbine and eventually increased to synchronous speed. One method of performing this operation is to initially convert the steam to an intermediate pressure turbine by the control of a valve arrangement 36 such as Bao disclosed in U.S. Patent Application No. 397,260, filed on July 12, 1982 and assigned to the applicant of the present invention. 13). When the turbine reaches the predetermined speed, control is passed to the steam barrel and valve autonomous 28. As the steam barrel and valve open slowly, depending on the speed of the turbine, the pressure to the actuator is reduced. However, the control circuit 240-2 provides an output signal that closes the bypass valve so as to reduce the imbalance and keep the bypass valve 72 at a predetermined setpoint. This process continues until the bypass valve 72 closes and steam from all boilers is provided to the turbine with more steam entering the bin and less steam entering the bypass unit. When the bypass valve 72 is closed, it is detected by a limit switch (not shown), and the throttling pressure control value is moved to the boiler or the turbine control device accordingly, and the control circuit 240-1 performs the control operation primarily. The control circuit 240-2 applies an appropriate signal to terminal 248 to be in tracking mode.

The control circuit 240-1 having a fast time constant serves to open the bypass valve 72 quickly when any overpressure exceeding a predetermined constant bias B, which is the normal pressure. Do not open the bypass valve early during the change.

Investigating the pressure on the control circuit 240-1 shows that the signal on line 101 at equilibrium at a particular load corresponds to the throttling pressure indicated by a particular point on solid line 280 in FIG. 7, but line 264. The signal of the image corresponds to a specific point on the dotted line curve 286. The signal on the line 264 is larger than the signal on the line 101 by a certain amount B, but the bypass valve 72 is closed because the output 240-1 of the control circuit is fixed at zero volts. The bypass valve closes if the top of the actuation pressure does not exceed bias B. Conversely, if the pressure bias due to the load removal exceeds a certain bias, the control circuit 240-1 will quickly provide an output signal in response to an imbalance, thereby opening the bypass valve 72 to bypass the boiler steam. Allow it to pass through the pass device, where the throttling pressure is maintained at any set value plus the bias value until normal operation is restored. After a certain time delay, control is switched back to the control circuit 240-2, whereby the throttling pressure is adjusted from the value of the high throttling pressure target setpoint to the biased target setpoint. In the control movement, since the control circuit 240-2 follows the output of the control circuit 240-1 and provides the same output signal immediately before this challenge, there is no impulse. After correcting the problem and moving all the steam to the turbine, the control circuit 240-1 is again enabled to function as an overpressure adjustment.

9 shows another apparatus for applying a bias to a predetermined throttling pressure setpoint signal. In contrast to having a constant bias applied to the amplifier 268, the arrangement of FIG. 9 includes a multiplication circuit 297 for converting a signal value on the line 260 into a specific percentage of the signal value and applying it to the amplifier 268. . For example, the corresponding predetermined bias value requires a multiplication circuit 297 that multiplies the signal on line 260 by 0.05. The survivas curve for sliding pressure automata may be the one described by the dashed curve 298 shown in dashed lines in FIG.

The breakpoint 282 and the first vias B ₁ are shown in FIG. 10 and the breakpoints 283, the second and high vias B ₂ are shown. The bias value for the slope portion of the curve between break points 282 and 283 gradually increases from the minimum value B ₁ to the maximum value B ₂ .

Single Control Circuit Operation

In the apparatus described so far, the pressure control circuit 150 and the spray valve control circuit 140 each comprise a dual control circuit arrangement in which one control circuit is used for a slow response time situation and the other control circuit has a fast response. Used for time.

11 illustrates a single control circuit arrangement that may be used.

For the pressure control circuit 150, a single proportional integral control circuit 240 is provided which has a relatively slow response time similar to the control circuit 240-2 of FIG. The control circuit 240 has two input signals, one of which is a signal provided on the line 101 indicating the operating cross-pressure indication, and the other is the line 264 as a function of the operating state of the turbine. Is a signal provided on.

Specifically, the selection circuit 300 may apply a bias (or percentage bias as in FIG. 9) signal B on line 302 or zero applied on line 303 depending on the selection signal applied on line 304. It is provided to pass a bias signal. Thus, for example, during a start-up operation, a zero bias signal on line 303 causes amplifier 268 to pass a predetermined trol from generator 262 through a pressure setting signal to control circuit 240 on line 264. It is chosen to configure different inputs for.

On the contrary, when the turbine is not fully operated to perform the bypass operation, the vias on the line 302 provide a path to the control circuit 240 in which the amplifier 268 adds the bias signal to the set value. 150 is selected to function as an overpressure control of the control circuit as described above. During this period of operation, events such as turbine trips may occur that may require the rapid opening of the bypass device. Therefore, in order to cope with a situation in which a sudden reaction is required, a selection priority circuit 310 should be provided, and if a signal impulsively applied on the line 312 appears, in which case the selection circuit 310 is a valve actuating circuit ( The output signal is normally passed on the line 243 from the control circuit 240 except for providing a signal to command 114 to rapidly open the bypass valve 72 to a predetermined maximum position. If the operating load is at a certain maximum of force, then the signal applied to line 312 is dependent on, for example, the turbine trip or the generator circuit breaker opening.

The signal for actuating the valve is traced to the control circuit 240 as a signal to be followed in line 314. When the high speed valve operation is started, an appropriate signal is applied to the pressure line 316 such that the control circuit 240 is in a tracking mode according to the valve operation signal. Once the valve is completely open and the signal on the throttling line 312 is removed, the following enabling signal on the line 316 is controlled by the control circuit 240 which controls the opening of the bypass valve 72 according to the throttling pressure condition. It is removed to provide a crash-free move.

For the spray valve control circuit 140, the single proportional integrating circuit control circuit 200 has a relatively slow response time variation, such as the control circuit 200-2 of FIG. The control circuit 200 operates like the control circuit 200-2 during the bypass operation and is the same as the cold heating temperature on the line 126 in the control circuit 200-2 and the adaptive setpoint signal on the line 141. Receive the signal. During non-bypass operation, the spray valve 84 is in a closed state, and a sudden occurrence of bypass operation rapidly opens to any predetermined maximum position, which is applied to the line 312 of the selection priority circuit 310. This is because of the signal.

Therefore, the signal instructing the rapid opening of the bypass valve 72 is applied to the proportional amplifier 226 so that the valve operation circuit 122 causes the rapid opening of the spray valve 84 through the addition circuit 224. All. Therefore, the control circuit 200 provides the necessary control signal for maintaining precise temperature control as described above.

Thus, the pressure control circuit 150 described in FIGS. 6, 9 or 11 operates the high pressure bypass valve so that the throttling pressure is maintained at the set point during the start of the high pressure turbine so that the throttling pressure is maintained at the set point during the turbine start. In addition, it acts as an overpressure regulator during normal turbine operation (non-bypass operation) to quickly open the bypass unit for any abnormal pressure conditions. The predetermined throttling pressure target setpoint is generated independent of the steam flow fixation process, thereby eliminating process feedback that can change the setpoint as needed. In dual capacity thermal (initiated and normal turbine operation) of the pressure control circuit, the pressure control circuit can serve as a pressure mode of operation, for example constant pressure, sliding pressure, deformed sliding pressure, preprogrammed ramping pressure. Can be.

Claims (11)

In the steam turbine bypass apparatus for controlling the outlet throttling pressure of the steam generator in the steam turbine apparatus 10 having a bypass passage 74 for bypassing the steam turbine, (A) a high pressure bypass valve 72 in the bypass passage 74 for controlling steam entering the bypass passage. (B) a throttling pressure target setpoint generator 262 which generates a desired throttling pressure target setpoint signal that varies with load but independent of steam flow; (C) a pressure transducer 100 for measuring the throttling pressure of the generator and providing an actuating throttling pressure signal 101; (D) A bypass unit for a steam turbine, characterized in that it comprises a control circuit 150 which controls the automatic operation of the bypass valve as a function of the actuated throttle pressure signal and a desired throttle pressure target setpoint signal. 2. The control circuit according to claim 1, wherein when the steam turbine is operating without normal bypass, the control circuit is configured to open the bypass valve when the actuation throttling pressure signal is equal to the desired throttling pressure target set point plus a bias value. Bypass device for steam turbine, characterized in that the operation. The bypass apparatus for a steam turbine according to claim 2, wherein the Baas value is a constant value. 4. The bypass unit as set forth in claim 3, wherein said bias value is a function of a desired throttling pressure target setpoint signal. 5. The bypass apparatus for a steam turbine as set forth in claim 4, wherein said Baas value is a desired percent throttling pressure target setpoint signal. 2. The steam turbine according to claim 1, wherein the bypass device for the steam turbine includes a regulating device for controlling the bypassed steam temperature, wherein the control device is operated to initiate operation of the regulating device. Bypass device. In the steam turbine bypass apparatus for controlling the outlet throttling pressure of the steam generator in the steam turbine apparatus 10 having a bypass passage 74 for bypassing the steam turbine, (A) a high pressure bypass 72 in the bypass passage 74 for weighing the steam entering the bypass passage, (B) an alternating pressure target set point generator 262 and a steam generator 262 that generate a desired throttling pressure set point signal that varies with load but independent of steam flow; (C) a pressure transducer 100 for measuring the throttling pressure of the generator and providing an actuating throttling pressure signal 101; (D) a control circuit 150 for controlling the operation of the valve device as a function of the operating throttling pressure signal and the desired throttling pressure target set point signal, wherein the control circuit is operating when the steam turbine is not operating normally. Is activated to open the bypass valve when the actuated throttle pressure signal is equal to the desired throttle pressure target set point plus the bias value. (I) a first control circuit having a first response time and accommodating a bias value added to the actuating pressure pressure signal and a desired axial pressure target setpoint signal; (II) a second control circuit for accommodating the desired throttling pressure target set value without the operating throttling pressure signal and the bias value and having a second response time; (III) A bypass unit for a steam turbine, comprising a selection circuit for selecting one of the control circuits to control operation. The bypass apparatus of claim 7, wherein the first response time is faster than the second response time. 9. The steam turbine according to claim 8, wherein each of the control circuits is operated in a first operation mode to generate an output signal in response to an input signal and in a second operation mode to match the following signal. Bypass device. 10. The bypass apparatus for a steam turbine according to claim 9, comprising an apparatus for providing an output signal of one control circuit to another control circuit as a signal to be followed. 12. The steam turbine bypass apparatus of claim 10, wherein the bypass unit for the steam turbine includes an adding circuit for generating an output signal that is a sum of input signals, and the output signal of the control circuit is applied to the adding circuit as an input signal, The output signal of the bypass unit for steam turbines, characterized in that for controlling the operation of the valve device.

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