CS195643B1 - Connection for automatic adjusting optimal parameters of vapour in the initial phase of warming the pressure vessels - Google Patents

Description

The invention relates to a circuit for automatically adjusting optimum parameters in the initial heating phase of pressure vessels, in particular steam turbine boxes.

Steam turbine cabinets, steam pipelines and other thick-walled thermal energy equipment or accessories operating in the region of higher or high temperatures and pressures are brought into operation by a controlled supply of superheated steam. In the initial heating phase, it is practically always heated by superheated steam, which in contact with the inner surface of the pressure vessel walls condenses and heats it intensively. This first phase is particularly delicate because, at low pressures, a small change in pressure corresponds to a large change in the temperature of the steam system, so that high internal stresses easily arise in said thick-walled pressure vessels.

In order to increase the temperature of the walls of the pressure vessel, it is also necessary to increase the parameters of the heating steam in the next heating phase. It is then possible to achieve the operating temperature of the vessel walls by means of a controlled throttling of the inlet steam pressure. The dependence of the controlled superheat steam pressure p on the initial temperature T _{o of the} superheated device, on the permissible time temperature gradient k and on time t is generally given by the function p '= f (T ₀ , k, t,).

For a given device to be put into operation, the initial temperature T 0 is _a variable parameter that uniquely determines the initial pressure p _{0 of the} superheat steam in the initial stage of the superheat. Thus, the dependence given by the function holds

P - g (T ₀ ).

The latter function has the same shape for all heated thermal energy devices and does not depend on the type of pressure vessel being heated. In the next phase of heating there is a gradual increase in the regulated pressure <p of the superheated steam, which is given by the time temperature gradient k and time t. This dependence is different for pressure vessels with different allowable time temperature gradients k depends on temperature conditions in the pressure vessel. heating phase.

In steam turbine casing, which: ^- are rather warm common type of pressure vessels, from the viewpoint of exceeding the permissible temperature differences most critical coupling flange in the area of the regulating step. Sensing sensors are therefore usually located in these locations. Since the temperature difference between the inner and outer parts of the flange must not exceed a fixed value during heating, the temperature of the turbine casing must not rise faster than a certain critical steep rise given the permissible time temperature gradient k. heating in the shortest possible time, it is necessary to keep the linear increase of the cabinet temperature by this permissible time temperature gradient k.

Hitherto known connections for automatically adjusting optimal steam parameters in the initial heating phase of the above function

Po = g / T ₀ / bud cuts. very complicated, or it doesn't solve it exactly. By way of example, the circuit used so far for the automatic regulation of steam turbine superheat, which is an important part of the device for the automatic start-up of back-pressure steam turbines, can be mentioned.

As with the other wiring used, the temperature sensor and the pressure sensor can be mounted in the turbine housing, while the input and evaluation circuits are located in separate electronic baths in the switchboard. On the pointer meter, which is connected to the output of said temperature sensor, there is an adjustable dial for controlling two photoelectric sensors, the outputs of which are connected to the first amplifier. In each of the two output branches of said first amplifier, connected to a first input and a second input of a logic circuit, a mechanical contact relay and an interference input filter are connected in series.

The first input of the counter is connected to the output of the logic circuit; the output from the counter is connected both to a digital-to-analog converter and to a decoder with a multi-channel output embedded in the feedback branch. After the decoder, the feedback branch is divided into three parallel links.

The first link connects the first output of the decoder to the third input of the logic circuit. In the second interconnect connecting the second output of the decoder to the fourth input of the logic circuit, a first flip-flop is inserted.

Similarly, in the third interconnect connecting the third output of the decoder to the fifth input of the logic circuit, a second flip-flop is inserted. The output of the D / A converter is connected to the first input of the inverter, to which the second input is connected a pressure sensor. The control branch is connected to the inverter output with a second amplifier, controller, control circuit and actuator connected in series. The command branch connecting the command circuit to the second input of said controller is also connected to both flip-flops, the sixth input of the logic circuit, and the second input of the counter. A time base is connected to the seventh input of the logic circuit.

The input information from the temperature sensor is converted into a deflection of the target in the hand gauge, which excites the photoelectric sensors in two set positions. The output signals from these photoelectric sensors corresponding to the two temperature states of the turbine housing are, after amplification, fed through the respective output branch to a logical circuit and to other circuits and parts of said wiring.

The described circuit for automatic control of the preheating is able to evaluate the whole initial phase either as a cold state or as a partially warmed state. The two temperature states correspond to the automatic adjustment of two fixed values of the superheat steam pressure at the beginning of the superheat. Thus, the initial steam parameters are fixed for two temperature zones, each for the lowest temperature. In the upper regions of these temperature zones, the initial parameters of the superheat steam are uneconomically low. The actual heating takes place with a time delay which can be up to 50% of the total heating time. In addition, heat losses occur during this inefficient delay.

Another known connection for automatic regulation of heating, whose description is in MS. No. 136,787, the temperature sensor is connected to a servo system. Also the follow-up part of the wiring. No. 136,787, which serves to evaluate the initial temperature θ, is different from the respective evaluation part of the first circuit described, in particular in that it includes an output voltage comparison circuit of said servo system and a voltage programmed value from the second series of step selectors. Wiring according to MS. No. 1 36 787, however, due to the large number of mechanical contacts, it has a relatively low durability and reliability and therefore requires more and more frequent maintenance.

A considerable part of the disadvantages of the known circuits is eliminated by the circuit for automatically adjusting the optimal steam parameters in the initial phase of heating the pressure vessels according to the invention, characterized in that the first indicator for sensing the steam temperature is connected to the first input of the comparator a connection comprising connecting the output of the comparator to the first input of the programming member and connecting the first output of the programming member to the second input of the comparator, wherein the programming member is simultaneously part of a second feedback circuit , coupling the first output of the coincidence member to the second input of the programming member, and coupling the second output of the coincide The third input of the programming member is connected to the fourth input of the programming member with a time base, the fifth input of the programming member is connected to the first output of the command member, the sixth input to the programming member is connected to the second output of the programming member. to the input of the exponential transducer, and wherein the third output of the command member is connected to the second input of the coincidence member, while the second indicator member for sensing the vapor pressure in the pressure vessel is connected to the first input of the power member; the third input is connected to the fourth output of the Command Member.

The first input of the first summation inverter, which is part of the comparing member together with the series-connected level switch, is connected to the output of the first rip-amplifier, which is part of the first indicator member together with the series-connected temperature sensor. an analog converter which is part of a programming element together with a series-connected logic circuit and a counter, wherein the level switch output is coupled to the logic circuit input. _>

The output of the digital-to-analog converter, which, together with the serial logic circuit and the counter of the programming element, is connected to the input of the exponential converter, the output of said exponential converter being connected to the second input of the second summing inverter. a second voltage amplifier, controller, control circuit, and action circuit connected in series.

The connection according to the invention makes it possible to significantly reduce the heating time of the pressure vessel and thus to save fuel. It is also cheaper and more reliable due to comparable existing connections.

The accompanying drawing shows an exemplary embodiment of an arrangement for automatically adjusting optimum steam parameters in the initial heating phase of pressure vessels according to the invention.

In the block diagram shown, this circuitry consists of an evaluation part consisting of two feedback circuits and an output exponential transducer 10, further comprising a control part formed by interconnected command member 17 and control member 22, which command member 17 is simultaneously connected to the evaluation part, and further comprising an input portion consisting of three separate units, a time base 18 connected to the evaluation portion, and a first display member 19 '. also connected to said evaluation part, and a second indicator member 20 connected to the control member 22 of the control part. The first feedback circuit forms a circular link which comprises connecting the output of comparator 21 to the first input 6 of the programming member 23 and connecting the first output 8 of this programming member 23 to the second input b of said comparator 21. Similarly, the second feedback circuit forms a circular link that includes the second output of the programming member 23 with the first input 2 of the coincidence member 24, the first output n of the coincidence member 24 with the second input 2 of the programming member 23, and the second output of the coincidence. a member 24 with a third input program of the programming member 23.

As can be seen from the illustration, the programming member 23 is simultaneously part of both the first feedback circuit and the second feedback circuit. The third output to the programming member 23 is coupled to the input of the exponential converter 10. In the control portion, the first output 6 of the command member 17 is connected to the fifth input 8 of the programming member 23, the second output 6 of the command member 17 is connected to the sixth input h of the programming member 23. The third output 6 of the command member 17 is connected to the second input M of the coincidence member 24 and the fourth output 8 of the command member 17 is connected to the third input x of the power member 22.

The first of the three separate input wiring units is the time base 18, the output of which is connected to the fourth input f of the programming member 23 of the evaluation part. The second discrete unit of the output portion is a first indicator member 22 whose output is coupled to the first input 6 of the comparator member 21 and its third discrete unit is a second indicator member 60 whose output is connected to the first input of the power member 22 of the control portion.

The comparator 21 consists of a first summing inverter 2 serially connected to the level switch 2 ' the programming member 23 ' consists of a serial logic circuit 2, the output of which is connected to the first input of the counter 6, and a digital analog converter 7 The coincidence member 24 consists of a decoder 2 ^{and a} memory circuit 9. The output of the level switch 4 is connected to the first input of the logic circuit 5 and the output of the digital-analog converter 7 is connected to the second input of the first summing inverter 2. »and secondly to the input Exponential álního 'converter 10. on the second input of the logic circuit 2 is connected to the first output of the decoder 2 and the third input of the logic circuit ³ and 2 connected to the output of the storage circuit 9 ..

’

The second output of the decoder 2 s ^e connected to the first input memory circuit 2 · inputs of the decoder 2 is connected to the joint output of the counter 6 are input DAC 7 .. The first output of the command member 17 is connected to the control part, a fifth input of the logic circuit 2 »second the output of the command member 17 is connected to the second input of the counter 2 ^{and the} third output of the command member 17 is connected to the second input of the memory circuit 2. is the connection / βη to the first input of the controller 22 »further from the control circuit 15, with its input connected to the output of the controller 14, and further from the action circuit 16,

The first input of the second summation inverter 12 is connected to the output of the second indicator member 20, the second input of the second summation inverter 12 is connected to the output of the exponential converter 10. The second input of the controller 22 is connected to the fourth output of the command member 17.

The input base time circuit 18 is connected to the fourth input of the logic circuit 5 by its output. The first input part indicator 19 consists of a temperature sensor 2, which is connected to the input of the first voltage amplifier 6, and the first voltage amplifier 2 the output is connected to the first input of the summation inverter 2. The second indicator member 20 of this input part consists of a pressure sensor 21 which is connected to the input of a resistive transmitter 25 and its output is connected to the first input of a second summation inverter. 12 ♦

The programming member 23 operates as. time-varying voltage source. At higher initial temperatures T _{of the} heated cabinets, the comparator 21 assesses in the first feedback circuit the difference between the voltage at the first output of the programming member 23 and the voltage provided by the indicator member 19.

At a predetermined value of said voltage difference, the level switch 2 changes the logical level of its output voltage from one of two possible states to another, thereby blocking a further voltage change at all three outputs of the programming member 23.

At lower initial temperatures of £ ₀ is the output voltage at all three outputs of the programming element 23 is blocked coincident member 24 in the second feedback circuit.

In both described cases, in the locked state of the programming member 23, the voltage at its third output carries information about the thermal state of the turbine housing. The voltage at the output of the exponential transducer 10 then corresponds to the optimum superheat steam pressure. The second summation member 12 evaluates the difference between the voltage at the output of the exponential converter 10 and the voltage at the output of the resistive transmitter 25 of the second indicator member 20. The output voltage of the second summation inverter 12 is processed after amplification in the second voltage amplifier 13. 22 »which controls the inlet valve of the superheated steam. The command member 17 is essentially a logic circuit used to block and trigger key wiring parts. The time base 18 allows the programming member 23 to operate over time.

The connection according to the invention makes it possible to significantly reduce the heating time of the pressure vessel and thus to save fuel. It is also cheaper and more reliable due to comparable existing connections.

SUBJECT

Claims (2)

Wiring for automatically adjusting optimum steam parameters in the initial phase of overheating of pressure vessels, comprising indicator members for sensing the wall temperature. containers and steam pressure enclosed therein, in particular in steam turbine boxes, characterized in that the first indicator (19) for sensing the temperature of the steam is connected to the first input (a) of the comparator (21) of the first feedback circuit, formed by a circular link comprising connecting the output of the comparator (21) to the first input (c) of the programming member (23) and connecting the first output (ii) of the programming member (23) to the second input (b) of the comparator (21), the member (23) is also part of a second feedback circuit formed by a ring link comprising a second output (j) of the programming member (23) with a first input (1) of the coincidence member (24), and a first output (n) of the coincidence member (24) / with the second input (d) of the programming member (23), · and then connecting the second output (o) of the coincidence member (24) with the third vs tupem / e / program-. A timing base (18) is connected to the fourth input (f) of the programming member (23), and the first output (p) of the command member (17) is connected to the fifth input (g) of the programming member (23). A second output (r) of the command member (17) is connected to the sixth input (h) of the programming member (23), wherein the third output (k) of the programming member (23) is connected to the input of the exponential converter (10), the third output / s / command members / 17 / is connected to the second input / m / coincidence element / 24 /, while the second indicator member 720 / a snímáV Y _N s climb the steam pressure in the pressure vessel is connected to the first input / u (22), to whose second input (v) is connected the output of the exponential converter (10), and whose third input (x) is connected to the fourth output (t) of the command member (17). Wiring for the automatic adjustment of the optimum steam parameters according to claim 1, characterized in that an output of the first summing inverter (3), which is part of a comparator (21), is connected to the first level summing inverter (4). a first voltage amplifier (2), which, together with a series temperature sensor (1), is part of the first indicator member (19), while the second input of the first summation inverter (3) is connected to a digital analogue output (7) with a serial logic circuit (5) and a counter (6) included in the programming element (23), the output of the level switch (4) being coupled to the input of the logic circuit (5).