Detailed Description
A shell-and-tube heat exchanger, as shown in fig. 1, comprises a shell 20, a heat exchange component 23, a shell-side inlet connecting pipe 24 and a shell-side outlet connecting pipe 25; the heat exchange component 23 is arranged in the shell 20 and fixedly connected to the front tube plate 16 and the rear tube plate 19; the shell side inlet connecting pipe 24 and the shell side outlet connecting pipe 25 are both arranged on the shell 20; fluid enters from the shell side inlet connecting pipe 24, exchanges heat through the heat exchange part and exits from the shell side outlet connecting pipe 25.
Preferably, the heat exchange member 23 extends in a horizontal direction. The heat exchanger is arranged in the horizontal direction.
Fig. 2 shows a top view of a heat exchange part 23, which comprises a central tube 8, a left tube 21, a right tube 22 and tube groups 1, wherein the tube groups 1 comprise a left tube group 11 and a right tube group 12, the left tube group 11 is communicated with the left tube 21 and the central tube 8, the right tube group 12 is communicated with the right tube 22 and the central tube 8, so that the central tube 8, the left tube 21, the right tube 22 and the tube groups 1 form a closed circulation of heating fluid, the central tube 8 is filled with phase change fluid, an electric heater 9 is arranged in the central tube 8, each tube group 1 comprises a plurality of circular arc-shaped annular tubes 7, the ends of the adjacent annular tubes 7 are communicated, so that the plurality of annular tubes 7 form a serial structure, and the ends of the annular tubes 7 form free ends 3-6 of the annular tubes; the central tube comprises a first tube orifice 10 and a second tube orifice 13, the first tube orifice 10 is connected with the inlet of the left tube group 11, the second tube orifice 13 is connected with the inlet of the right tube group 12, the outlet of the left tube group 11 is connected with the left tube 21, and the outlet of the right tube group 12 is connected with the right tube 22; the first orifice 10 and the second orifice 13 are arranged on opposite sides of the central tube 8.
The ends of the two ends of the center tube 8, the left tube 21 and the right tube 22 are disposed in the openings of the front and rear tube plates 16, 19 for fixation.
Preferably, a left return pipe 14 is arranged between the left pipe 21 and the central pipe 8, and a right return pipe 15 is arranged between the right pipe 22 and the central pipe 8. Preferably, the return pipe is arranged at the end of the central pipe. Both ends of the central tube are preferred.
The fluid is heated and evaporated in the central tube 8, flows to the left and right headers 21 and 22 along the annular tube bundle, and is heated to expand in volume, so that steam is formed, and the volume of the steam is far larger than that of water, so that the formed steam can flow in the coil in a rapid impact manner. Because of volume expansion and steam flow, the free end of the annular tube can be induced to vibrate, the vibration is transmitted to the surrounding heat exchange fluid by the free end of the heat exchange tube in the vibration process, and the fluid can also generate disturbance, so that the surrounding heat exchange fluid forms disturbance flow, a boundary layer is damaged, and the purpose of enhancing heat transfer is realized. The fluid is condensed and released heat in the left and right side pipes and then flows back to the central pipe through the return pipe.
According to the invention, the prior art is improved, and the condensation collecting pipe and the pipe groups are respectively arranged into two pipes which are distributed on the left side and the right side, so that the pipe groups distributed on the left side and the right side can perform vibration heat exchange descaling, the heat exchange vibration area is enlarged, the vibration can be more uniform, the heat exchange effect is more uniform, the heat exchange area is increased, and the heat exchange and descaling effects are enhanced.
Preferably, the annular pipes of the left pipe group are distributed by taking the axis of the left pipe as the center of a circle, and the annular pipes of the right pipe group are distributed by taking the axis of the right pipe as the center of a circle. The left side pipe and the right side pipe are arranged as circle centers, so that the distribution of the annular pipes can be better ensured, and the vibration and the heat exchange are uniform.
Preferably, the tube group is plural.
Preferably, the position of the right tube group (including the right tube) is a position of the left tube group (including the left tube) rotated by 180 degrees (angle) along the axis of the center tube. Through such setting, can make the annular pipe distribution of heat transfer reasonable more even, improve the heat transfer effect.
Preferably, the headers 8, 21, 22 are provided along the longitudinal direction.
Preferably, the left tube group 11 and the right tube group 12 are staggered in the longitudinal direction, as shown in fig. 3. Through the staggered distribution, can make to vibrate heat transfer and scale removal on different length for the vibration is more even, strengthens heat transfer and scale removal effect.
Preferably, the tube group 1 is provided in plural (for example, the same side (left side or right side)) along the length direction of the center tube 8, and the tube diameter of the tube group 1 (for example, the same side (left side or right side)) becomes larger along the flow direction of the fluid in the shell side.
Preferably, the pipe diameter of the annular pipe of the pipe group (for example, the same side (left side or right side)) is increased along the flowing direction of the fluid in the shell side.
The pipe diameter range through the heat exchange tube increases, can guarantee that shell side fluid outlet position fully carries out the heat transfer, forms the heat transfer effect like the adverse current, further strengthens the heat transfer effect moreover for whole vibration effect is even, and the heat transfer effect increases, further improves heat transfer effect and scale removal effect. Experiments show that better heat exchange effect and descaling effect can be achieved by adopting the structural design.
Preferably, the tube group on the same side (left side or right side) is provided in plural along the length direction of the center tube 8, and the distance between the adjacent tube groups on the same side (left side or right side) becomes smaller along the flow direction of the fluid in the shell side.
Preferably, the spacing between the tube banks on the same side (left or right) in the direction of fluid flow in the shell side is increased by a decreasing amount.
The interval amplitude through the heat exchange tube increases, can guarantee that shell side fluid outlet position fully carries out the heat transfer, forms the heat transfer effect like the adverse current, further strengthens the heat transfer effect moreover for the whole vibration effect is even, and the heat transfer effect increases, further improves heat transfer effect and scale removal effect. Experiments show that better heat exchange effect and descaling effect can be achieved by adopting the structural design.
It has been found in research and practice that the heat exchange of the heat exchange components with continuous power stability results in fluid formation stability of the internal heat exchange components, i.e. no fluid flow or little fluid flow, or stable flow, which results in greatly reduced vibration performance of the tube bank 1, thereby affecting the descaling of the tube bank 1 and the efficiency of heat exchange. Therefore, the following improvements are required for the heat exchange member.
In the prior application, the heat exchange of a single heat exchange part is researched, but the problem of uneven overall heat exchange exists, for example, the heat exchange power is different along with the time.
Preferably, the heat exchange power adopts a batch heat exchange mode.
The heat exchange components are divided into two groups, and the two groups of heat exchange components exchange heat alternately to realize periodic frequent vibration of the elastic coil.
In a period T, the heat exchange power P of each heat exchange component in the first group changes according to the following rule:
in a half period of 0-T/2, P is equal to n, wherein n is a constant value and has the unit of watt (W), namely the heat exchange power is kept constant;
p =0 in half period of T/2-T. I.e. the heat exchange part does not exchange heat.
The heat exchange power P of the second group of single heat exchange components is changed according to the following rule:
p =0 in the half period of 0-T/2. I.e. the heat exchange part does not exchange heat.
In a half period of T/2-T, P is equal to n, wherein n is a constant value and has the unit of watt (W), namely the heat exchange power is kept constant;
preferably, T is 50-80 minutes, wherein 1000W < n < 5000W.
Through the heat exchange with the time variability, the fluid can be frequently evaporated, expanded and contracted in the elastic tube bundle, so that the vibration of the elastic tube bundle is continuously driven, and the heat exchange efficiency and the descaling operation can be further realized.
By dividing the heat exchange components into two groups, the heat exchange efficiency of the heat exchange components can be improved as a whole.
Preferably, the number of heat exchange members in each group is the same.
Further preferably, the heat exchange components are divided into n groups, each group does not exchange heat alternately, in one period T, n-1 groups exchange heat, and 1 group does not exchange heat.
Namely, in a period T, the change rule of the heat exchange power P of each heat exchange component of 1 group is as follows:
in a half period of 0-T/2, P is equal to n, wherein n is a constant value and has the unit of watt (W), namely the heat exchange power is kept constant;
p =0 in half period of T/2-T. I.e. the heat exchange part does not exchange heat.
The change rule of the heat exchange power P of the other n-1 groups of heat exchange components is as follows:
p =0 in the half period of 0-T/2. I.e. the heat exchange part does not exchange heat.
In a half period of T/2-T, P is equal to n, wherein n is a constant value and has the unit of watt (W), namely the heat exchange power is kept constant;
preferably, the heat exchange power of the single heat exchange component is 1000W < n <5000W
Preferably, the number of heat exchange parts in each group is the same.
Preferably, the heat exchange components are arranged into 2 groups, each heat exchange component is provided with a plurality of heat exchange components, each heat exchange component is independently controlled, and the starting number of the first group of heat exchange components and the second group of heat exchange components is periodically changed along with the change of time.
Preferably, when the operation is started, the first group of heat exchange components are all closed, the second group of heat exchange components are all started, and each group of heat exchange components is n, so that in a period T, one heat exchange component is started in the first group of heat exchange components at intervals of T/2n until the heat exchange device is all started at the T/2 time, and then one heat exchange component is closed at intervals of T/2n until the heat exchange device is all closed at the T time. In the second group of heat exchange components, one heat exchange component is closed every T/2n until the heat exchange device is completely closed at T/2n, and then one heat exchange component is opened every T/2n until the heat exchange device is completely opened at T.
Preferably, each heat exchange component has the same heat exchange power.
Through the heat exchange with the time variability, the fluid can be frequently evaporated, expanded and contracted in the elastic tube bundle, so that the vibration of the elastic tube bundle is continuously driven, and the heat exchange efficiency and the descaling operation can be further realized.
The total heat exchange power can be ensured to be kept the same through the opening and closing of the two groups of heat exchange components.
Preferably, the number of the heat exchange components is 3, the heat exchange components are respectively a first heat exchange component, a second heat exchange component and a third heat exchange component, and the change rule of the heat exchange power P of the 3 heat exchange components is as follows in a period T:
in the first third period of 0-T/3, the heat exchange power P of the first heat exchange component and the second heat exchange component is equal to n, wherein n is a constant value and the unit is watt (W), namely the heat exchange power of the first heat exchange component and the heat exchange power of the second heat exchange component are kept constant; p of the third heat exchange part is 0;
in the middle third period of T/3-2T/3, the heat exchange power P of the first heat exchange component and the third heat exchange component is n, wherein n is a constant numerical value and the unit is watt (W), namely the heat exchange power of the first heat exchange component and the heat exchange power of the third heat exchange component are kept constant; p of the second heat exchange part is 0;
in the last third period of 2T/3-T, the heat exchange power P of the second heat exchange component and the third heat exchange component is equal to n, wherein n is a constant numerical value and the unit is watt (W), namely the heat exchange power of the second heat exchange component and the heat exchange power of the third heat exchange component are kept constant; p of the first heat exchange part is 0.
Preferably, the period is 50 to 300 minutes, preferably 50 to 80 minutes.
In tests it was found that the pipe diameters, distances and pipe diameters of the left side pipe 21, the right side pipe 22, the central pipe 8 and the pipe diameters of the ring pipes can have an influence on the heat exchange efficiency and the uniformity. If the distance between the collector is too big, then heat exchange efficiency is too poor, and the distance between the ring shape pipe is too little, then the ring shape pipe distributes too closely, also can influence heat exchange efficiency, and the pipe diameter size of collector and heat exchange tube influences the volume of the liquid or the steam that holds, then can exert an influence to the vibration of free end to influence the heat transfer. Therefore, the pipe diameters and distances of the left pipe 21, the right pipe 22, the central pipe 8 and the pipe diameters of the ring pipes have a certain relationship.
The invention provides an optimal size relation summarized by numerical simulation and test data of a plurality of heat pipes with different sizes. Starting from the maximum heat exchange amount in the heat exchange effect, nearly 200 forms are calculated. The dimensional relationship is as follows:
the distance between the center of the central tube 8 and the center of the left tube 21 is equal to the distance between the center of the central tube 8 and the center of the right tube 22, L, the tube diameter of the left tube 21, the tube diameter of the central tube 8 and the radius of the right tube 22 are R, the radius of the axis of the innermost annular tube in the annular tubes is R1, and the radius of the axis of the outermost annular tube is R2, so that the following requirements are met:
R1/R2=a*(R/L)2-b (R/L) + c; wherein a, b, c are parameters, wherein 4.834<a<4.835,1.390<b<1.391,0.5585<c<0.5590, respectively; preferably, a is 4.8344, b is 1.3906, and c is 0.5587.
Preferably, 34< R <61 mm; 114< L <191 mm; 69< R1<121mm, 119< R2<201 mm.
Preferably, the number of annular tubes of the tube set is 3-5, preferably 3 or 4.
Preferably, 0.57< R1/R2< 0.61; 0.3< R/L < 0.32.
Preferably, 0.583< R1/R2< 0.60; 0.304< R/L < 0.316.
Preferably, the radius of the annular tube is preferably 10-40 mm; preferably 15 to 35mm, more preferably 20 to 30 mm.
Preferably, the centers of the left tube 21, the right tube 22 and the center tube 8 are on a straight line.
Preferably, the arc between the ends of the free ends 3, 4 around the centre axis of the left tube is 95-130 degrees, preferably 120 degrees. The same applies to the curvature of the free ends 5, 6 and the free ends 3, 4. Through the design of the preferable included angle, the vibration of the free end is optimal, and therefore the heat exchange efficiency is optimal.
The heating power of the electric heater is preferably 1000-2000W, and more preferably 1500W.
Preferably, the box body is of a circular section, and is provided with a plurality of heat exchange components, wherein one heat exchange component is arranged at the center of the circle of the circular section, and the other heat exchange components are distributed around the center of the circle of the circular section.
Preferably, the tube bundle of the tube bank 1 is an elastic tube bundle.
The heat exchange coefficient can be further improved by arranging the tube bundle of the tube group 1 with an elastic tube bundle.
Further preferably, the electric heater is an electric heating rod.
The number of the pipe groups 1 is multiple, and the plurality of pipe groups 1 are in a parallel structure.
The heat exchanger shown in fig. 6 has a circular cross-sectional housing in which the plurality of heat exchange members are disposed. Preferably, the number of the heat exchange components is three, the center of the central tube of each heat exchange component is positioned in an inscribed regular triangle with a circular cross section, the connecting lines of the centers of the central tubes form a regular triangle, the upper part of each central tube is provided with one heat exchange component, the lower part of each central tube is provided with two heat exchange components, and the connecting lines formed by the centers of the left tube, the right tube and the central tube of each heat exchange component are of a parallel structure. Through such setting, can make the interior fluid of heat exchanger fully reach vibrations and heat transfer purpose, improve the heat transfer effect.
Learn through numerical simulation and experiment, heat transfer part's size and circular cross-section's diameter have very big influence to the heat transfer effect, heat transfer part oversize can lead to adjacent interval too little, the space that the centre formed is too big, middle heat transfer effect is not good, the heat transfer is inhomogeneous, and on the same way, heat transfer part size undersize can lead to adjacent interval too big, leads to whole heat transfer effect not good. Therefore, the invention obtains the optimal size relation through a large amount of numerical simulation and experimental research.
The distance between the centers of the left side pipe and the right side pipe is L1, the side length of the inscribed regular triangle is L2, the radius of the axis of the innermost annular pipe in the annular pipes is R1, and the radius of the axis of the outermost annular pipe is R2, so that the following requirements are met:
10*(L1/L2)=d*(10*R1/R2)-e*(10*R1/R2)2-f; wherein d, e, f are parameters,
34.71<d<34.72,2.9315<e<2.9320,99.338<f<99.345;
further preferably, d =34.716, e =2.9319, f = 99.342;
with 720< L2<1130mm preferred. Preferably 0.58< R1/R2< 0.62.
Further preferred is 0.30< L1/L2< 0.4.
Preferably, the centers of the left tube 21, the right tube 22 and the center tube 8 are on a straight line.
Through the layout of the three heat exchange component structure optimization, the whole heat exchange effect can reach the best heat exchange effect.
When three heat exchange parts are arranged, three groups of heat exchange parts can be preferably arranged, and each group of heat exchange parts carries out intermittent heat exchange;
it is preferable that two sets are provided, two sets are provided at the lower portion, and one heat exchange part at the upper portion is provided at one set, to perform intermittent heat exchange.
It has been found in research and practice that a sustained, stable heat source results in fluid-forming stability of the internal heat exchange components, i.e., no fluid flow or little fluid flow, or a steady flow rate, resulting in a significant reduction in the vibrational performance of the tube bank 1, thereby affecting the efficiency of heat exchange and descaling of the tube bank 1. Therefore, the following improvements are required for the heat pipe.
In the inventor's prior application, a periodic heat exchange mode is provided, and the vibration of the heat exchange tube is continuously promoted through the periodic heat exchange mode, so that the heat exchange efficiency and the descaling effect are improved. However, adjusting the vibration of the tube bundle with a fixed periodic variation can lead to hysteresis and too long or too short a period. Therefore, the invention improves the previous application and intelligently controls the vibration, so that the fluid in the fluid can realize frequent vibration, and good descaling and heat exchange effects are realized.
Aiming at the defects in the technology researched in the prior art, the invention provides a novel electric heating heat exchanger capable of intelligently controlling vibration. The heat exchanger can improve the heat exchange efficiency, thereby realizing good descaling and heat exchange effects.
Preferably, the heat exchange is carried out in the descaling process in the manner described above.
Self-regulation vibration based on pressure
Preferably, a pressure detection element is arranged in the heat exchange component and used for detecting the pressure in the heat exchange component, the pressure detection element is in data connection with the controller, and the controller controls whether the electric heater heats or not according to the detected pressure.
Preferably, the controller controls the electric heater to stop heating if the pressure detected by the pressure detecting element is higher than a certain value, and controls the electric heater to heat if the pressure detected by the pressure detecting element is lower than a certain value.
The pressure detected by the pressure detecting element can basically reach saturation when the certain pressure is met, and the volume of the internal fluid is not changed greatly basically. So that the fluid undergoes volume reduction to thereby realize vibration. When the pressure is reduced to a certain degree, the internal fluid starts to enter a stable state again, and at the moment, the fluid needs to be heated so as to evaporate and expand again, so that the electric heater needs to be started for heating.
Preferably, the pressure detecting elements are arranged in the central tube 8 and/or the left side tube 21 and/or the right side tube 22.
Preferably, the pressure detecting elements are disposed within the center tube 8 and the left and right side tubes 21 and 22. The average of the pressures of the three channel boxes can be selected as regulating data.
Preferably, the pressure detecting element is provided at the free end. Through setting up at the free end, can perceive the pressure variation of free end to realize better control and regulation.
Independently adjusting vibration based on temperature
Preferably, a temperature detection element is arranged in the heat exchange component and used for detecting the temperature in the heat exchange component, the temperature detection element is in data connection with the controller, and the controller controls whether the electric heater heats or not according to the detected temperature.
Preferably, the controller controls the electric heater to stop heating if the temperature detected by the temperature detecting element is higher than a certain value, and controls the electric heater to heat if the temperature detected by the temperature detecting element is lower than a certain value.
The temperature detected by the temperature detecting element can basically reach saturation of the evaporation of the internal fluid and basically does not change much the volume of the internal fluid under the condition of meeting a certain temperature, and in this case, the internal fluid is relatively stable, and the vibration of the tube bundle at the moment is poor, so that adjustment is needed to enable the tube bundle to vibrate, and heating is stopped. So that the fluid undergoes volume reduction to thereby realize vibration. When the temperature is reduced to a certain degree, the internal fluid starts to enter a stable state again, and the fluid needs to be heated to evaporate and expand again, so that the electric heater needs to be started for heating.
Preferably, the temperature detecting element is provided at an upper end disposed in the center tube 8 and/or the left side tube 21 and/or the right side tube 22.
Preferably, the temperature detecting elements are provided at the upper ends of the center tube 8 and the left and right side tubes 21 and 22.
Preferably, the temperature detection element is provided at the free end. Through setting up at the free end, can perceive the temperature variation of free end to realize better control and regulation.
Thirdly, automatically adjusting vibration based on liquid level
Preferably, a liquid level detecting element is arranged in the central tube 8 and used for detecting the liquid level of the fluid in the lower tube box, the liquid level detecting element is in data connection with a controller, and the controller controls whether the electric heater heats or not according to the detected liquid level of the fluid.
Preferably, the controller controls the electric heater to stop heating if the liquid level detected by the liquid level detecting element is lower than a certain value. The liquid level detected by the liquid level detection element is higher than a certain value, and the controller controls the electric heater to heat.
The liquid level detected by the liquid level detecting element can be adjusted to vibrate the tube bundle so as to stop heating under the condition that a certain liquid level (for example, the lowest limit) is met, the evaporation of the internal fluid is basically saturated, and the volume of the internal fluid is basically not changed greatly. So that the fluid undergoes volume reduction to thereby realize vibration. When the liquid level rises to a certain degree, the internal fluid starts to enter a stable state again, and at the moment, the fluid needs to be heated so as to evaporate and expand again, so that the electric heater needs to be started for heating.
Fourthly, automatically adjusting vibration based on speed
Preferably, a speed detection element is arranged in the free end of the tube bundle and used for detecting the flow speed of the fluid in the free end of the tube bundle, the speed detection element is in data connection with the controller, and the controller controls whether the electric heater heats or not according to the detected speed of the fluid.
Preferably, the controller controls the electric heater to stop heating if the speed detected by the speed detecting element is higher than a certain value. The speed detected by the speed detecting element is lower than a certain value, and the controller controls the electric heater to heat.
The speed detected by the speed detecting element can be adjusted to vibrate the tube bundle to stop heating, because the internal fluid is relatively stable and the tube bundle is deteriorated in vibration property in the case where the evaporation of the internal fluid is substantially saturated to form a stable flow and the speed of the internal fluid is not substantially changed when a certain speed (for example, the highest upper limit) is satisfied. So that the fluid undergoes volume reduction to thereby realize vibration. When the speed drops to a certain degree, the internal fluid starts to enter a stable state again, and at the moment, the fluid needs to be heated so as to evaporate and expand again, so that the electric heater needs to be started for heating.
Preferably, the heat exchanger comprises a descaling process, and the heat exchange is carried out in the descaling process in the manner described above.
The invention also comprises intelligent control, and the specific technical scheme is as follows:
control of effluent temperature
The shell side outlet is provided with a temperature sensor, the temperature sensor is in data connection with the data acquisition controller, a preset temperature T1 of fluid at the shell side outlet is set, and T1 is stored in the data acquisition controller; the data acquisition controller acquires the temperature T2 detected by the temperature sensor; the data acquisition controller compares T2 with T1; and the data acquisition controller controls the heating power of the electric heater to heat according to the comparison result.
Preferably, the data acquisition controller automatically controls to decrease the heating power if T2> T1, and to increase the heating power if T2< T1; if T2= T1, the data acquisition controller automatically controls the heating power to remain unchanged.
Preferably, the magnitude of the heating power is controlled by controlling the magnitude of the voltage input to the electric heater.
Preferably, the temperature sensor is a plurality of temperature sensors, and the controller controls the operation of the heater according to temperature data measured by the plurality of temperature sensors.
Control of fluid flow
The shell-side inlet pipe is provided with a valve, the valve is in data connection with the data acquisition controller, the preset temperature T1 of fluid at the shell-side outlet is set, and T1 is stored in the data acquisition controller; the data acquisition controller acquires the temperature T2 detected by the temperature sensor; the data acquisition controller compares T2 with T1; and the data acquisition controller controls the opening and closing and the opening of the valve according to the comparison result.
Preferably, the data collection controller automatically controls the valve to increase the opening degree if T2> T1, and to decrease the opening degree if T2< T1; if T2= T1, the opening of the automatic control valve of the data acquisition controller is kept unchanged. By controlling the opening of the valve, the flow is increased when the temperature is high, and the flow is reduced when the temperature is low, so that the constancy of the outlet temperature is ensured.
Preferably, the temperature sensor is a plurality of temperature sensors, and the controller controls the operation of the heater according to temperature data measured by the plurality of temperature sensors.
(III) control of the shell pressure
A pressure sensor is arranged in the shell, the pressure sensor is in data connection with the data acquisition controller, a shell side preset pressure P1 is set, and P1 is stored in the data acquisition controller; the data acquisition controller acquires pressure P2 detected by the pressure sensor; the data acquisition controller compares P2 with P1; and the data acquisition controller controls the heating power of the electric heater to heat according to the comparison result. Through so setting up, can adjust heating power according to the pressure in the casing, avoid pressure too big to guarantee the safety of heat exchanger.
Preferably, if P1< P2<0.9 × P1, the data acquisition controller automatically controls to reduce the heating power, and if P2> = P1, the data acquisition controller automatically controls to stop the heating power for heating.
Preferably, the magnitude of the heating power is controlled by controlling the magnitude of the voltage input to the electric heater.
Preferably, the pressure sensor is a plurality of pressure sensors, and the controller controls the operation of the heater according to the pressure data measured by the plurality of pressure sensors.
The pressure sensor is arranged at the upper position of the shell.
(IV) control of case exhaust
A pressure sensor is arranged in the shell and is in data connection with a data acquisition controller, and an exhaust valve is arranged at the upper part of the shell side and is in data connection with the data acquisition controller; setting a shell side preset pressure P1 and storing P1 in a data acquisition controller; the data acquisition controller acquires pressure P2 detected by the pressure sensor; the data acquisition controller compares P2 with P1; and the data acquisition controller controls the opening and closing of the exhaust valve according to the comparison result. Through so setting up, can adjust discharge valve according to the pressure in the casing, avoid pressure too big to guarantee the safety of heat exchanger.
Preferably, if P2>0.98 × P1, the data acquisition controller automatically controls the exhaust valve to open until P2< =0.9 × P1, the data acquisition controller automatically controls the exhaust valve to close.
Preferably, the pressure sensor is a plurality of pressure sensors, and the controller controls the operation of the heater according to the pressure data measured by the plurality of pressure sensors.
The pressure sensor is arranged at the upper position of the shell.
It should be noted that the heating power of the electric heater is the average power of the entire heating time.
Preferably, the heat exchanger is used for hotels, and further can be used for heating stations of hotels, or heating hot water, heating and the like.
Although the present invention has been described with reference to the preferred embodiments, it is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.