CN209116827U - A kind of lamella heat exchanger of On Line Foul Removing Technology - Google Patents

Abstract

The utility model provides a kind of lamella heat exchanger of On Line Foul Removing Technology comprising core, shell, ultrasound wave descaling device and control device.The shell is set on the outside of the core, and can be radially spaced apart with the core.The ultrasound wave descaling device is arranged in the first end of the shell and can extend into the core.The control device is electrically connected to the ultrasound wave descaling device, and can control the ultrasound wave descaling device work, to carry out scale removal to the lamella heat exchanger.Lamella heat exchanger according to the present utility model can carry out scale removal to lamella heat exchanger in real time, extend the service life of lamella heat exchanger, improve production efficiency so that lamella heat exchanger is suitable for intermittent operation and reduce unnecessary cleaning.

Description

A kind of lamella heat exchanger of On Line Foul Removing Technology

Technical field

The utility model relates to technical field of heat exchangers, and in particular to a kind of lamella heat exchanger of On Line Foul Removing Technology.

Background technique

In each industrial circle such as oil gas, chemical industry, food, refrigeration, the working media in each process flow is required to carry out Various heat exchanges.Application of the lamella heat exchanger on some heat exchange stations has gradually shown it as new and effective The great advantages of heat exchanger.However, the difference of processing medium nature causes to exchange heat due to lamella heat exchanger longtime running Device fouling has become certainty.Dirt cause heat exchange efficiency reduce and product quality reduction, thus influence production be normally carried out and The safety of equipment.According to each technique time-based maintenance plan, usually require often to be cleared up after heat exchanger internal incrustation.However, Unnecessary cleaning and inappropriate cleaning method will be further increased the downtime of whole system and lead to water and change The waste for learning articles, to increase cost, and is also possible to lead to environment and ecological problem.

Accordingly, it is desirable to provide a kind of lamella heat exchanger of On Line Foul Removing Technology, at least partly to solve the above problems.

Utility model content

A series of concept of reduced forms is introduced in utility model content part, this will be in specific embodiment part Middle further description.The utility model content part of the utility model is not meant to attempt to limit claimed Technical solution key feature and essential features, do not mean that the guarantor for attempting to determine technical solution claimed more Protect range.

At least to be partially solved the above problem, the utility model discloses a kind of lamella heat exchanger of On Line Foul Removing Technology, Comprising:

Core；

Shell, the shell is set on the outside of the core, and can be radially spaced apart with the core；

Ultrasound wave descaling device, the ultrasound wave descaling device are arranged in the first end of the shell and can extend into In the core；And

Control device, the control device is electrically connected to the ultrasound wave descaling device, and can control the ultrasonic wave Apparatus for eliminating sludge work, to carry out scale removal to the lamella heat exchanger.

Lamella heat exchanger according to the present utility model can carry out scale removal, extension plate to lamella heat exchanger in real time The service life of shell heat exchanger improves production efficiency, so that lamella heat exchanger is suitable for intermittent operation, reduction need not The cleaning wanted.

Optionally, the lamella heat exchanger further includes the first fluid inlet duct for the second end that the shell is arranged in With first fluid outlet conduit, the first fluid inlet duct and the first fluid outlet conduit connect with the core respectively It is logical.

Optionally, the lamella heat exchanger further include:

Differential pressure pickup, the differential pressure pickup are respectively connected to the first fluid inlet duct and the first fluid Outlet conduit, to acquire the static pressure difference signal of the first fluid inlet duct and the first fluid outlet conduit；And

Data acquisition processing device, the data acquisition processing device are electrically connected to the differential pressure pickup and the control The static pressure difference signal to receive the static pressure difference signal of the differential pressure pickup acquisition, and is converted into fouling ginseng by device Number, and be compared with preset threshold value, when the fouling parameter is greater than the threshold value, the data acquisition process dress Control signal can be exported to the control device by setting, to start the ultrasound wave descaling device.

Optionally, the ultrasound wave descaling device includes ultrasonic transducer, is connected to the super of the ultrasonic transducer Sound wave amplitude transformer and the tool heads for being connected to the ultrasonic variable amplitude bar, the ultrasonic variable amplitude bar and tool heads setting exist In the core.

Optionally, the shell includes the first end plate positioned at the first end, the second end plate positioned at the second end And the side plate extended between the first end plate and second end plate and along circumferential direction, the ultrasound wave descaling dress It sets and is connected to the first end plate, the first fluid inlet duct and the first fluid outlet conduit are respectively connected to described Second end plate.

Optionally, the core includes multiple single piece plates, and the single piece plate has first through hole and the second through-hole, adjacent The respective first through hole connection of single piece plate, the respective second through-hole connection of the adjacent single piece plate, the first fluid Inlet duct is connected to the first through hole, and the first fluid outlet conduit is connected to second through-hole, and described first is logical At least one of hole and second through-hole are provided with the ultrasound wave descaling device.

Optionally, the single piece plate is configured to circular plate structure.

Optionally, the ultrasound wave descaling device further includes being arranged on the outside of the side plate and being connected to the second of the shell Fluid inlet conduit and second fluid outlet conduit.

Optionally, the ultrasound wave descaling device further includes the mounting flange for being connected to the first end plate, the ultrasound The two sides of the mounting flange are arranged in wave transducer and the ultrasonic variable amplitude bar.

Optionally, the differential pressure pickup includes first connecting portion and second connecting portion, and the first connecting portion is connected to The first fluid inlet duct, the second connecting portion are connected to the first fluid outlet conduit, with described quiet in measuring Pressure difference signal.

Detailed description of the invention

The following drawings of the utility model embodiment is originally practical for understanding in this as a part of the utility model It is novel.Shown in the drawings of the embodiments of the present invention and its description, for explaining the principles of the present invention.In attached drawing In,

Fig. 1 is the schematic perspective view of the lamella heat exchanger of a preferred embodiment of the utility model；

Fig. 2 is the partial structure sectional view of the lamella heat exchanger in Fig. 1；

Fig. 3 is the schematic perspective view of the single piece plate in Fig. 2；And

Fig. 4 is the schematic perspective view of the ultrasound wave descaling device in Fig. 2.

Description of symbols:

100, lamella heat exchanger 110, core

111, single piece plate 114, first through hole

115, the second through-hole 120, first fluid inlet duct

130, first fluid outlet conduit 140, ultrasound wave descaling device

141, ultrasonic transducer 142, ultrasonic variable amplitude bar

143, tool heads 144, mounting flange

145, flange threaded hole 150, differential pressure pickup

151, first connecting portion 152, second connecting portion

160, data acquisition processing device 170, control device

121, the first pipe connecting flange 131, the second pipe connecting flange

180, shell 181, first end plate

182, the second end plate 183, side plate

184, first end plate through-hole 185, the first threaded hole

186, the second end plate through-hole 191, second fluid inlet duct

192, second fluid outlet conduit 193, third pipe connecting flange

194, the 4th pipe connecting flange

Specific embodiment

In the following description, a large amount of concrete details are given more thoroughly to manage in order to provide to the utility model Solution.It will be apparent, however, to one skilled in the art that the utility model embodiment may not need one or more These a details and be carried out.In other examples, in order to avoid obscuring with the utility model embodiment, for Some technical characteristics well known in the art are not described.

In order to thoroughly understand the utility model embodiment, detailed structure will be proposed in following description.Obviously, originally The execution of utility model embodiment is not limited to the specific details that those skilled in the art is familiar with.

The utility model provides a kind of lamella heat exchanger 100, the lamella heat exchanger 100 be able to carry out it is online (that is, Scale removal in real time).Lamella heat exchanger 100 mainly may include core 110, shell 180, ultrasound wave descaling device 140 and control Device 170.The lamella heat exchanger 100 of the utility model is described in detail below in conjunction with Fig. 1 to Fig. 4.

As depicted in figs. 1 and 2, core 110 can be using general arrangement as cylindrical structure.Shell 180 can be set in core 110 outside, and can be radially spaced apart with core.Namely the external peripheral surface of core 110 and shell 180 is interior The setting of circumferential surface interval.In the present embodiment, could be formed in core 110 first fluid channel (not shown) and with The disconnected second fluid channel of first fluid channel (not shown), second fluid channel can be connected to shell 180.It is first-class Body channel is for accommodating first fluid, the second fluid channel in gap and core 110 between shell 180 and core 110 Among can be used for accommodating second fluid.First fluid is different with the temperature of second fluid, so that first fluid and second fluid Between be able to carry out heat exchange, to achieve the purpose that heat exchange.

Shell 180 may include positioned at the first end plate 181 of first end (right end in Fig. 1 and Fig. 2), positioned at second end Second end plate 182 of (left end in Fig. 1 and Fig. 2) and between first end plate 181 and the second end plate 182 while along week The side plate 183 extended to direction.First end plate 181 and the second end plate 182 can be set in parallel and be configured to circular plate knot Structure.Side plate 183 enables its both ends to be respectively connected to first end plate 181 and second end it is so structured that circular cylindrical structure Plate 182.

Fig. 2 and Fig. 3 are schematically shown, and core 110 may include multiple single piece plates 111.Single piece plate 111 can construct For circular corrugated plate shape structure.Multiple single piece plates 111 can link together side by side, with the shape between multiple single piece plates 111 At have first fluid channel and with the disconnected second fluid channel in first fluid channel, and second fluid channel is connected to shell Body 180.For example, first fluid channel and second fluid channel can be spaced setting, can preferably exchange heat, heat exchange effect is improved Rate.It will be understood by those skilled in the art that the structure of single piece plate 111 is not limited to present embodiment, and as needed, single piece plate 111 It is so structured that ellipse, square, rectangle, trapezoidal or arbitrarily other suitable shapes plate structure.

Single piece plate 111 can have first through hole 114 and the second through-hole 115.First through hole 114 is arranged in the second through-hole 115 lower section, and be spaced apart with the second through-hole 115.First through hole 114 and the second through-hole 115 can be round hole.Adjacent The connection of the respective first through hole 114 of single piece plate 111, adjacent respective second through-hole 115 of single piece plate 111 connection.Specifically, more The central axis of the first through hole 114 of a single piece plate 111 is horizontally disposed and can (substantially) be overlapped each other, multiple monolithics The central axis of second through-hole 115 of plate 111 is horizontally disposed and can (substantially) be overlapped each other.Those skilled in the art Member is it is appreciated that first through hole 114 and the structure of the second through-hole 115 are not limited to present embodiment, as needed, first through hole 114 and second through-hole 115 can also be other shapes through-hole.For example, first through hole 114 and the second through-hole 115 can be ellipse The through-hole of round, square or any other suitable shape.

Referring back to Fig. 1 and Fig. 2, ultrasound wave descaling device 140 is arranged in the first end of shell 180 and can extend into Core 110.For example, ultrasound wave descaling device 140 can connect to first end plate 181, and can be extended into from first end plate 181 Enter core 110.Lamella heat exchanger 100 may include two ultrasound wave descaling devices 140, two ultrasound wave descaling devices 140 It is separately positioned in first through hole 114 and the second through-hole 115.It will be understood by those skilled in the art that ultrasound wave descaling device 140 quantity is not limited to present embodiment.In a unshowned embodiment of the utility model, lamella heat exchanger 100 may include a ultrasound wave descaling device 140, the ultrasound wave descaling device 140 can be set in first through hole 114 or In the second through-hole of person 115.

As shown in figure 3, ultrasound wave descaling device 140 mainly may include ultrasonic transducer 141, be connected to ultrasonic waves The ultrasonic variable amplitude bar 142 of energy device 141 and the tool heads 143 for being connected to ultrasonic variable amplitude bar 142.142 He of ultrasonic variable amplitude bar Tool heads 143 can be set in core 110.Ultrasonic transducer 141 can be set in the outside of core 110.Ultrasonic waves The electrical power of input can be converted into mechanical output (i.e. ultrasonic wave) and transmit ultrasonic variable amplitude bar 142 again by energy device 141, and it is certainly Body consumes small part power.Ultrasonic variable amplitude bar 142 can amplify Oscillation Amplitude on demand, then again by energetic vibration Pass to tool heads 143, then by tool heads 143 by transfer of ultrasonic energy into process fluid, such as be transmitted to first fluid In so that the fouling materials such as impurity in first fluid under ultrasonic wave effect dispersion, it is loose, broken destroy, fall off, not easily It is attached on tube wall and falls off from tube wall (such as surface of single piece plate), and as these impurity are arranged in the flowing of first fluid Out, to achieve the effect that ultrasound wave descaling.

Referring back to Fig. 1 and Fig. 2, ultrasound wave descaling device 140 can also include the Method for Installation for being connected to first end plate 181 The two sides of mounting flange 144 are arranged in orchid 144, ultrasonic transducer 141 and ultrasonic variable amplitude bar 142.Ultrasonic transducer 141 It is connected with ultrasonic variable amplitude bar 142 by flange transition, mounting flange 144 can be by ultrasonic transducer 141 and first fluid Keep apart.In the present embodiment, the flange specification for being suitble to the pressure rating can be selected according to different pressure ratings.

Specifically, first end plate through-hole 184 can be set in first end plate 181 and be arranged in first end plate through-hole 184 First threaded hole 185 (such as countersunk head threaded hole) in outside.Flange threaded hole 145 is correspondingly provided on mounting flange 144.It is super Sound wave apparatus for eliminating sludge 140 extends through first end plate through-hole 184 and enters the first through hole 114 or second of single piece plate 111 In through-hole 115.Mounting flange 144 is arranged in the outside of first end plate 181 and against first end plate 181, and passes through fastener It extends through flange threaded hole 145 and enters first end plate through-hole 184 mounting flange 144 is connected to first end plate 181, i.e., By the installation of ultrasound wave descaling device 140 to first end plate 181, to be able to carry out effective sealing, the inside core 110 is prevented One fluid leaks out, while being convenient for the installation and removal of ultrasound wave descaling device 140, so that ultrasound wave descaling device 140 has There is replaceability.

Control device 170 is electrically connected to ultrasound wave descaling device 140, and can control the work of ultrasound wave descaling device 140, To carry out scale removal to lamella heat exchanger 100.Control device 170 is provided with operation panel, can be controlled by operation panel super The starting of sound wave apparatus for eliminating sludge 140 stops working.In addition, ultrasound wave descaling device can also be adjusted by operation panel The power of 140 ultrasonic waves issued and frequency etc., it is convenient and efficient, it is easy to operate.

Lamella heat exchanger 100 can also include 120 He of first fluid inlet duct that the second end of shell 180 is arranged in First fluid outlet conduit 130, first fluid inlet duct 120 and first fluid outlet conduit 130 connect with core 110 respectively It is logical.First fluid inlet duct 120 and first fluid outlet conduit 130 can be respectively connected to the second end plate 182.

Specifically, the second end plate through-hole 186 there are two can be set on the second end plate 182, two the second end plate through-holes 186 It can be spaced setting along the vertical direction.More specifically, the central axis of underlying second end plate through-hole 186 can be with monolithic The central axis (substantially) of the first through hole 114 of plate 111 is overlapped, and the central axis for the second end plate through-hole 186 being located above can It is overlapped with the central axis (substantially) of the second through-hole 115 with single piece plate 111.One end of first fluid inlet duct 120 can be with It is inserted into underlying second end plate through-hole 186 and connects (such as welding) to the second end plate 182, first fluid outlet One end of pipeline 130 is inserted into the second end plate through-hole 186 being located above and connects (such as welding) to the second end plate 182.First fluid inlet duct 120 can be connected to first through hole 114 as a result, first fluid outlet conduit 130 and second Through-hole 115 is connected to, and the first fluid for allowing first fluid to enter core 110 via first fluid inlet duct 120 is logical In road, and flowed out from core 110 with after second fluid heat exchange via first fluid outlet conduit 130.

Lamella heat exchanger 100 can also include differential pressure pickup 150.Differential pressure pickup 150 is respectively connected to first-class Body inlet duct 120 and first fluid outlet conduit 130, to acquire first fluid inlet duct 120 and first fluid outlet The static pressure difference signal in road 130.Specifically, differential pressure pickup 150 includes first connecting portion 151 and second connecting portion 152, and first connects Socket part 151 is connected to first fluid inlet duct 120, and second connecting portion 152 is connected to first fluid outlet conduit 130, in Measure static pressure difference signal.

For example, the first pressure pipe (not shown) communicated therewith can be set on first fluid inlet duct 120, The the second pressure pipe (not shown) communicated therewith can be set on first fluid outlet conduit 130.First pressure pipe and Two pressure pipes can be hose.First pressure pipe can connect to first connecting portion 151, and the second pressure pipe can connect to second Interconnecting piece 152 enables differential pressure pickup 150 to measure first fluid inlet duct 120 and first fluid outlet conduit 130 Wall static pressure difference signal.

Lamella heat exchanger 100 can also include data acquisition processing device 160.Data acquisition processing device 160 is electrically connected It is connected to differential pressure pickup 150 and control device 170, to receive the static pressure difference signal of the acquisition of differential pressure pickup 150, and by static pressure Difference signal is converted into fouling parameter, and is compared with preset threshold value, when fouling parameter is greater than threshold value, data acquisition Processing unit 160 can export control signal to control device 170, to start ultrasound wave descaling device 140.

Specifically, data acquisition processing device 160 is built-in with data processing algorithm, the static pressure difference signal that can come to transmission It is handled, the fouling parameter of resistance performance parameter and scaling degree inside lamella heat exchanger 100 can be obtained, so The fouling parameter is compared with preset threshold value again afterwards, thus judge inside lamella heat exchanger 100 whether fouling. When fouling parameter is lower than threshold value, data acquisition processing device 160 issues the control of a low level signal to control device 170 Signal, instruction control device 170 do not start ultrasound wave descaling device 140.

When 100 inside (such as inside core 110) fouling of lamella heat exchanger is serious, differential pressure pickup 150 is collected Pressure difference signal value will increase, and then corresponding fouling parameter value will increase.When fouling parameter is higher than threshold value, at data acquisition The control signal that device 160 issues a high level signal to control device 170 is managed, instruction control device 170 starts ultrasonic wave Apparatus for eliminating sludge 140, so as to be cleaned to lamella heat exchanger 100, to start scale removal, until data acquisition processing device The value for the fouling parameter that processing is formed again in 160 is lower than threshold value, and control device 170, which controls ultrasound wave descaling device 140, to be stopped Work.

In addition, data acquisition processing device 160 can carry out data processing to the static pressure difference signal of acquisition, to form pressure difference Changing rule figure and/or table, to assess and diagnose the fouling condition inside lamella heat exchanger 100 and other failure (examples Such as leakage) situations such as.

Data acquisition processing device 160 also has store function to store related data, and is provided with external interface.Example Such as, USB flash disk is inserted into external interface, the data of storage can be taken out by external interface, and can be to the number of extraction Report is formed according to being printed.

Lamella heat exchanger 100 can also include the first pipe connecting flange that 120 end of first fluid inlet duct is arranged in 121 and the second pipe connecting flange 131 of 130 end of first fluid outlet conduit is set.Specifically, the first pipe connecting flange 121 is set It sets in one end far from the second end plate 182 of first fluid inlet duct 120, the second pipe connecting flange 131 is arranged in first fluid One end far from the second end plate 182 of outlet conduit 130, the first pipe connecting flange 121 and the second pipe connecting flange 131 be respectively used to Other pipelines connection, for conveying first fluid.

Lamella heat exchanger 100 can also include the second fluid entrance that 183 outside of side plate is arranged in and is connected to shell 180 Pipeline 191 and second fluid outlet conduit 192.Second fluid can enter shell 180 via second fluid inlet duct 191 Inside, and enter in the second fluid channel of core 110 with after first fluid heat exchange via second fluid outlet conduit 192 outflows.

Lamella heat exchanger 100 can also include the third pipe connecting flange that 191 end of second fluid inlet duct is arranged in 193 and the 4th pipe connecting flange 194 of 192 end of second fluid outlet conduit is set.Specifically, third pipe connecting flange 193 is set It sets in one end of the separate side plate 183 of second fluid inlet duct 191, the setting of the 4th pipe connecting flange 194 is exported in second fluid One end of the separate side plate 183 of pipeline 192, third pipe connecting flange 193 and the 4th pipe connecting flange 194 are respectively used to manage with other Road connection, for conveying second fluid.

Lamella heat exchanger according to the present utility model directly can control ultrasound wave descaling device by control device Starting stops, additionally it is possible to passing through data collection and analysis instrument real-time reception first fluid inlet duct and first fluid outlet The static pressure difference signal in road, and data processing can be carried out to received static pressure difference signal, to judge inside lamella heat exchanger Fouling condition exports a control signal to control device according to the severity of fouling, to control ultrasound wave descaling device Starting stops, to realize On Line Foul Removing Technology function, is able to extend the service life of lamella heat exchanger, improves production effect Rate reduces unnecessary cleaning so that lamella heat exchanger is suitable for intermittent operation.

Unless otherwise defined, the technology of technical and scientific term used herein and the technical field of the utility model The normally understood meaning of personnel is identical.Term used herein is intended merely to describe specifically to implement purpose, it is not intended that limit The utility model processed.Terms such as herein presented " settings " can both indicate that a component was attached directly to another portion Part can also indicate that a component is attached to another component by middleware.It describes in one embodiment herein Feature can be applied in combination another embodiment individually or with other feature, unless this feature is in another implementation It is not suitable for or is otherwise noted in mode.

The utility model is illustrated by above embodiment, but it is to be understood that, above embodiment It is only intended to the purpose illustrated and illustrated, and is not intended to limit the invention within the scope of described embodiment.This Field technical staff it is understood that introduction according to the present utility model can also make more kinds of variants and modifications, this A little variants and modifications are all fallen within the utility model range claimed.

Claims (10)

1. a kind of lamella heat exchanger of On Line Foul Removing Technology characterized by comprising

Core；

Shell, the shell is set on the outside of the core, and can be radially spaced apart with the core；

Ultrasound wave descaling device, the ultrasound wave descaling device are arranged in the first end of the shell and can extend into described Core；And

Control device, the control device is electrically connected to the ultrasound wave descaling device, and can control the ultrasound wave descaling Device work, to carry out scale removal to the lamella heat exchanger.

2. lamella heat exchanger according to claim 1, which is characterized in that the lamella heat exchanger further includes that setting exists The first fluid inlet duct and first fluid outlet conduit of the second end of the shell, the first fluid inlet duct and institute First fluid outlet conduit is stated to be connected to the core respectively.

3. lamella heat exchanger according to claim 2, which is characterized in that the lamella heat exchanger further include:

Differential pressure pickup, the differential pressure pickup are respectively connected to the first fluid inlet duct and first fluid outlet Pipeline, to acquire the static pressure difference signal of the first fluid inlet duct and the first fluid outlet conduit；And

Data acquisition processing device, the data acquisition processing device are electrically connected to the differential pressure pickup and control dress It sets, to receive the static pressure difference signal of the differential pressure pickup acquisition, and the static pressure difference signal is converted into fouling parameter, And be compared with preset threshold value, when the fouling parameter is greater than the threshold value, the data acquisition processing device Control signal can be exported, to the control device to start the ultrasound wave descaling device.

4. lamella heat exchanger according to claim 2, which is characterized in that the ultrasound wave descaling device includes ultrasonic wave Energy converter, the ultrasonic variable amplitude bar for being connected to the ultrasonic transducer and the tool heads for being connected to the ultrasonic variable amplitude bar, The ultrasonic variable amplitude bar and tool heads setting are in the core.

5. lamella heat exchanger according to claim 4, which is characterized in that the shell includes being located at the first end First end plate, positioned at the second end plate of the second end and between the first end plate and second end plate and along week The side plate extended to direction, the ultrasound wave descaling device are connected to the first end plate, the first fluid inlet duct and The first fluid outlet conduit is respectively connected to second end plate.

6. lamella heat exchanger according to claim 5, which is characterized in that the core includes multiple single piece plates, described Single piece plate has first through hole and the second through-hole, the respective first through hole connection of the adjacent single piece plate, the adjacent list The respective second through-hole connection of sheet, the first fluid inlet duct are connected to the first through hole, and the first fluid goes out Mouth pipeline is connected to second through-hole, and at least one of the first through hole and second through-hole are provided with the ultrasound Wave apparatus for eliminating sludge.

7. lamella heat exchanger according to claim 6, which is characterized in that the single piece plate is configured to circular plate knot Structure.

8. lamella heat exchanger according to claim 5, which is characterized in that the ultrasound wave descaling device further includes setting On the outside of the side plate and the second fluid inlet duct and second fluid outlet conduit of the connection shell.

9. lamella heat exchanger according to claim 5, which is characterized in that the ultrasound wave descaling device further includes connection To the mounting flange of the first end plate, the ultrasonic transducer and the ultrasonic variable amplitude bar are arranged in the mounting flange Two sides.

10. lamella heat exchanger according to claim 3, which is characterized in that the differential pressure pickup includes the first connection Portion and second connecting portion, the first connecting portion are connected to the first fluid inlet duct, and the second connecting portion is connected to The first fluid outlet conduit, in the measurement static pressure difference signal.