CN216536974U - Cooling condenser - Google Patents

Abstract

The utility model discloses a condenser, which comprises a shell, a condenser pipe assembly and a preheating pipe, wherein the shell is provided with a first side plate and a second side plate which are opposite in the length direction, the first side plate is provided with a cooling water inlet and a cooling water outlet which are spaced in the width direction of the shell, a top plate of the shell is provided with a steam inlet, a bottom plate of the shell is provided with a condensed water outlet, the condenser pipe assembly is provided with a cooling water flow channel, a water inlet of the cooling water flow channel is opposite to the cooling water inlet, a water outlet of the cooling water flow channel is opposite to the cooling water outlet, the preheating pipe is arranged in the shell in a penetrating mode, the preheating pipe is close to the steam inlet relative to the cooling water flow channel, and the preheating pipe is suitable for introducing waste water to be preheated. The condenser of the embodiment of the utility model can preheat the waste water by utilizing the high-temperature steam formed by evaporating the waste water, and simultaneously, the temperature of the high-temperature steam is reduced by utilizing the waste water, so that the consumption of cooling water is reduced, and the operation cost of a heat concentration system is reduced.

Description

Cooling condenser

Technical Field

The utility model relates to the technical field of chemical equipment, in particular to a condenser.

Background

The thermal concentration process is mature, safe and reliable, can treat high-concentration salt-containing wastewater, and is one of the mainstream technologies in the field of high-salt wastewater treatment at present. In the related art, in order to reduce the temperature difference between salt-containing wastewater and steam, a preheater is generally provided to preheat wastewater so as to increase the temperature of the wastewater, the temperature difference between the wastewater and the steam is reduced, and high-temperature steam formed by wastewater evaporation enters a condenser to exchange heat with a large amount of low-temperature circulating cooling water to form liquid water. However, in the related art, when the preheater is used to preheat the waste water, a large amount of steam is consumed, and when the condenser is used to condense the high-temperature steam, a large amount of cooling water is consumed, which results in high operation cost of the heat concentration system.

SUMMERY OF THE UTILITY MODEL

Therefore, the embodiment of the utility model provides a condenser, which can preheat waste water by using high-temperature steam formed by waste water evaporation, and simultaneously reduce the temperature of the high-temperature steam by using the waste water so as to reduce the using amount of cooling water and reduce the high operation cost of a heat concentration system.

The condenser according to the embodiment of the present invention includes: a housing having a first side plate and a second side plate arranged opposite to each other in a length direction thereof, the first side plate being provided with a cooling water inlet and a cooling water outlet spaced apart in a width direction of the housing, the housing having a top plate and a bottom plate arranged opposite to each other in the width direction thereof, the top plate having a steam inlet thereon, the bottom plate having a condensed water outlet thereon, the cooling water inlet being adjacent to the top plate with respect to the cooling water outlet; the condensation pipe assembly is arranged in the shell and is provided with a cooling water flow passage, a water inlet of the cooling water flow passage is opposite to the cooling water inlet, and a water outlet of the cooling water flow passage is opposite to the cooling water outlet; the preheating pipe penetrates through the shell, the preheating pipe is close to the steam inlet relative to the cooling water flow channel, the first end of the preheating pipe extends out of the first side plate, the second end of the preheating pipe extends out of the second side plate, and the preheating pipe is suitable for introducing waste water to be preheated.

According to the condenser of the embodiment of the utility model, the preheating pipe is arranged in the shell of the condenser in a penetrating way, so that the waste water in the preheating pipe can be preheated by utilizing the high-temperature steam entering the condenser, the temperature difference between the waste water and the steam is reduced, the consumption of energy by waste water evaporation is reduced, meanwhile, the temperature of the high-temperature steam entering the condenser is reduced by utilizing the heat exchange between the waste water in the heating pipe and the high-temperature steam, the temperature difference between the high-temperature steam and cooling water is reduced, the consumption of cooling water is saved, and the operation cost of a heat concentration system is reduced.

In some embodiments, the condensation duct assembly includes a first end plate and a second end plate, the first end plate and the second end plate both extending in a width direction of the shell and being spaced apart in a length direction of the shell, the first end plate being disposed adjacent to the first side plate and being spaced apart from the first side plate to form a first liquid flow chamber, the second end plate being disposed adjacent to the second side plate and being spaced apart from the second side plate to form a second liquid flow chamber, the shell having a front side plate and a rear side plate disposed opposite to each other in a thickness direction thereof, the first end plate being sandwiched between the front side plate and the rear side plate, the second end plate being sandwiched between the front side plate and the rear side plate, the first end plate, the second end plate, and the front side plate enclosing a gas flow chamber for allowing steam to pass therethrough, the cooling water inlet being adapted to inject cooling water into the first liquid flow chamber, the cooling water in the first liquid flow cavity is suitable for flowing out from the cooling water outlet.

In some embodiments, the condensation pipe assembly further includes a plurality of condensation pipes, each of the condensation pipes forms a cooling water channel, the plurality of condensation pipes are spaced apart in a width direction of the housing, first ends of the condensation pipes are connected to the first end plate, second ends of the condensation pipes are connected to the second end plate, the first end plate has a plurality of first through holes spaced apart in a length direction thereof, the plurality of first through holes are opposite to and communicate with the first ends of the plurality of condensation pipes, the second end plate has a plurality of second through holes spaced apart in a length direction thereof, the plurality of second through holes are opposite to and communicate with the second ends of the plurality of condensation pipes, and the first liquid flow chamber communicates with the second liquid flow chamber through the first through holes, the condensation pipes and the second through holes.

In some embodiments, the condenser tube assembly further includes a front cover plate, a top cover plate, and a bottom cover plate, the front cover plate, the top cover plate, and the bottom cover plate are all connected between the first end plate and the second end plate, the top cover plate and the bottom cover plate are opposite and spaced apart in the length direction of the housing, the top cover plate, the bottom cover plate, the top plate, and the bottom plate are parallel to each other, a rear side of the top cover plate is attached to and connected to the rear side plate, a rear side of the bottom cover plate is attached to and connected to the rear side plate, the top cover plate, the bottom cover plate, the first end plate, the second end plate, and the rear side plate may enclose a cooling water flow cavity having an opening, and the front cover plate is connected to the opening of the cooling water flow cavity to close the opening.

In some embodiments, the condenser further includes a plurality of flow partitioning plates, the plurality of flow partitioning plates are arranged in the cooling water flow cavity at intervals along the width direction of the housing, one end of each flow partitioning plate is connected to the first end plate, the other end of each flow partitioning plate is connected to the second end plate, a cooling water channel is formed between adjacent flow partitioning plates, the first end plate has a plurality of first through holes arranged at intervals along the length direction thereof, the plurality of first through holes are opposite to and communicate with the first ends of the plurality of cooling water channels, the second end plate has a plurality of second through holes arranged at intervals along the length direction thereof, and the plurality of second through holes are opposite to and communicate with the second ends of the plurality of cooling water channels.

In some embodiments, the cold circulation tube further comprises a plurality of first baffle plates and a plurality of second baffle plates, the plurality of first baffle plates are disposed between the first end plate and the first side plate, the plurality of first baffle plates are spaced apart along the width direction of the shell, the plurality of second baffle plates are disposed between the second end plate and the second side plate, the plurality of second baffle plates are spaced apart along the width direction of the shell, a first baffle flow channel is formed adjacent to the first baffle plate, a second baffle flow channel is formed adjacent to the second baffle plate, the plurality of first baffle flow channels are opposite to the plurality of second baffle flow channels, each first baffle flow channel is opposite to and in communication with at least one of the first through holes, and each second baffle flow channel is opposite to and in communication with at least one of the second through holes, it is a plurality of cooling water passageway, a plurality of first baffling runner and a plurality of second baffling runner constitutes jointly the cooling water runner, and is a plurality of first baffling runner is including the first outside baffling runner that is located the top and the second outside baffling runner that is located the bottom, first outside baffling runner with cooling water inlet intercommunication, the second outside baffling runner with cooling water outlet intercommunication.

In some embodiments, the condenser further comprises a partition plate, the preheating pipe is arranged on the first end plate and the second end plate in a penetrating mode, the partition plate is connected between the first end plate and the second end plate, and the partition plate is located between the preheating pipe and the flow partition plate.

In some embodiments, an air outlet is arranged on the front side plate, and the air outlet is externally connected with a vacuum pump.

In some embodiments, the front side plate is provided with a viewing port, and the viewing port is provided with a glass plate.

In some embodiments, the glass sheet is made of tempered glass.

Drawings

Fig. 1 is a schematic structural view of a condenser according to an embodiment of the present invention.

Reference numerals:

the device comprises a steam inlet 1, a condensate outlet 2, a preheating pipe water inlet 3, a preheating pipe water outlet 4, a cooling water inlet 5, a cooling water outlet 6, a front side plate 7, a cooling water channel 8, an observation port 9, a second end plate 10, a first baffle plate 11, a first baffle channel 111, a first side plate 12, an air outlet 13, a first end plate 14, a second baffle plate 15, a second baffle channel 151, a second side plate 16, a top plate 17, a bottom plate 18, a preheating pipe 19, a condenser pipe assembly 20, a shell 21 and a condenser pipe 22.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

As shown in fig. 1, the condenser according to the embodiment of the present invention includes a case 21, a condensation tube assembly 20, and a preheating tube 19.

The casing 21 has a first side plate 12 and a second side plate 16 opposed to each other in a length direction thereof (a left-right direction shown in fig. 1), the first side plate 12 is provided with a cooling water inlet 5 and a cooling water outlet 6 spaced apart in a width direction (an up-down direction shown in fig. 1) of the casing 21, the casing 21 has a top plate 17 and a bottom plate 18 arranged to be opposed to each other in the width direction thereof, the top plate 17 has a steam inlet 1 thereon, the bottom plate 18 has a condensed water outlet 2 thereon, and the cooling water inlet 5 is relatively adjacent to the top plate 17.

It should be noted that the condenser in this application is used for the hot concentrated processing of the waste water that contains salt, and the waste water that contains salt evaporates in the evaporimeter and forms high temperature steam, and high temperature steam gets into the condenser through steam inlet 1 and exchanges heat with the cooling water in the condenser and form the comdenstion water, and the comdenstion water is discharged from comdenstion water export 2.

Specifically, the condensation duct assembly 20 is disposed in the housing 21, and the condensation duct assembly 20 has a cooling water flow passage having a water inlet opposite to the cooling water inlet 5 and a water outlet opposite to the cooling water outlet 6. The cooling water flows into the condensation duct assembly 20 through the cooling water inlet 5 and flows along the cooling water flow passage, and the flowing cooling water can exchange heat with the high-temperature steam in the housing 21 sufficiently to condense the high-temperature steam into water drops.

The preheating pipe 19 is arranged in the shell 21 in a penetrating way, the preheating pipe 19 is close to the steam inlet 1 relative to the cooling water flow path, a first end of the preheating pipe 19 extends out of the first side plate 12, a second end of the preheating pipe 19 extends out of the second side plate 16, and the preheating pipe 19 is suitable for introducing waste water to be preheated. Specifically, the wastewater flows into the preheating pipe 19 through an inlet of the preheating pipe 19 and flows out through an outlet of the preheating pipe 19.

It can be understood that, before salt-containing waste water gets into the evaporimeter evaporation, preheat salt-containing waste water and can reduce the difference in temperature of waste water and steam to reduce the consumption of waste water evaporation to the energy, cool down steam and cooling water's the difference in temperature before high temperature steam gets into the condenser can reduce steam and cooling water, with the consumption that reduces the cooling water.

The inventor finds that generally, set up independent heating device and preheat waste water among the correlation technique, this certainly need consume more energy, and through locating the preheating pipe in the casing of condenser, the steam that can utilize waste water evaporation to produce preheats the waste water in the preheating pipe, utilize the waste water in the preheating pipe and high temperature steam's heat transfer to reduce high temperature steam's temperature simultaneously, thereby reduce the difference in temperature of high temperature steam and cooling water, avoided waste water to preheat the consumption of the energy promptly, saved the quantity of cooling water again.

According to the condenser of the embodiment of the utility model, the preheating pipe is arranged in the shell of the condenser in a penetrating way, so that the waste water in the preheating pipe can be preheated by utilizing the high-temperature steam entering the condenser, the temperature difference between the waste water and the steam is reduced, the consumption of energy by waste water evaporation is reduced, meanwhile, the temperature of the high-temperature steam entering the condenser is reduced by utilizing the heat exchange between the waste water in the heating pipe and the high-temperature steam, the temperature difference between the high-temperature steam and cooling water is reduced, the consumption of cooling water is saved, and the operation cost of a heat concentration system is reduced.

Further, as shown in fig. 1, the condensation duct assembly 20 includes a first end plate 14 and a second end plate 10, both the first end plate 14 and the second end plate 10 extending in the width direction of the shell 21 and being spaced apart in the length direction of the shell 21, the first end plate 14 being disposed adjacent to the first side plate 12 and being spaced apart from the first side plate 12 to define a first liquid flow chamber, the second end plate 10 being disposed adjacent to the second side plate 16 and being spaced apart from the second side plate 16 to define a second liquid flow chamber, the shell 21 having a front side plate 7 and a rear side plate (not shown) disposed opposite to each other in the thickness direction thereof, the first end plate 14 being sandwiched between the front side plate 7 and the rear side plate, the second end plate 10 being sandwiched between the front side plate 7 and the rear side plate, the first end plate 14, the second end plate 10 and the front side plate 7 enclose an air flow chamber for allowing steam to pass through, the cooling water inlet 5 is adapted to inject cooling water into the first liquid flow chamber, and the cooling water in the first liquid flow chamber is adapted to flow out from the cooling water outlet 6.

It is understood that the first and second end plates 14 and 10 may partition a cavity in the shell 21 to separate a steam flow space from a cooling water flow space to prevent high temperature steam from contacting the cooling water, and the first and second end plates 14 and 10 may serve as connection plates to fixedly connect the condensation duct assembly 20 with the shell 21.

Further, the condensation pipe assembly 20 further includes a plurality of condensation pipes 22, each condensation pipe 22 forms one cooling water channel 8, the plurality of condensation pipes 22 are arranged at intervals along the width direction of the housing 21, a first end of the condensation pipe 22 is connected to the first end plate 14, a second end of the condensation pipe 22 is connected to the second end plate 10, the first end plate 14 has a plurality of first through holes (not shown) arranged at intervals along the length direction thereof, the plurality of first through holes are opposite to and communicated with the first ends of the plurality of condensation pipes 22, the second end plate 10 has a plurality of second through holes (not shown) arranged at intervals along the length direction thereof, the plurality of second through holes are opposite to and communicated with the second ends of the plurality of condensation pipes 22, and the first liquid flow chamber is communicated with the second liquid flow chamber through the first through holes, the condensation pipe 22 and the second through holes.

As shown in fig. 1, the cooling water flows into the first flow chamber through the cooling water inlet 5, the cooling water in the first flow chamber flows into the condensation duct 22 through the first through hole, the cooling water flows along the condensation duct 22 and flows into the second flow chamber through the second through hole, and the cooling water in the second flow chamber flows into the condensation duct 22 through the second through hole and flows into the first flow chamber again through the first through hole to form a complete cooling water flow path.

In addition, it should be noted that the condensed water passage is not limited to be formed by a condensed water pipe, for example, the condensed water pipe assembly 20 may further include a front cover plate, a top cover plate, a bottom cover plate and a plurality of flow isolation plates, the front cover plate, the top cover plate and the bottom cover plate are all connected between the first end plate 14 and the second end plate 10, the top cover plate and the bottom cover plate are opposite and spaced apart in a length direction of the housing 21, the top cover plate, the bottom cover plate, the top plate 17 and the bottom plate 18 are parallel to each other, a rear side surface of the top cover plate is attached to and connected to the rear side plate, a rear side surface of the bottom cover plate is attached to and connected to the rear side plate, the top cover plate, the bottom cover plate, the first end plate 14, the second end plate 10 and the rear side plate may enclose a cooling water flow chamber having an opening, and the front cover plate is connected to the opening of the cooling water flow chamber to close the opening.

The plurality of flow baffles are arranged in the cooling water flow cavity at intervals along the width direction of the shell 21, one ends of the flow baffles are connected with the first end plate 14, the other ends of the flow baffles are connected with the second end plate 10, a cooling water channel 8 is formed between the adjacent flow baffles, the first end plate 14 is provided with a plurality of first through holes which are arranged at intervals along the length direction, the plurality of first through holes are opposite to and communicated with the first ends of the plurality of cooling water channels 8, the second end plate 10 is provided with a plurality of second through holes which are arranged at intervals along the length direction, and the plurality of second through holes are opposite to and communicated with the second ends of the plurality of cooling water channels 8.

Thus, the top cover plate, the bottom cover plate, the first end plate 14, the second end plate 10 and the rear side plate may enclose a sealed cooling water flow chamber, and the flow partition plate may partition a plurality of cooling water channels 8 in the flow chamber. It is understood that whether the condenser tubes 22 or the flow dividers are used to define the cooling water passages 8 in the present application may be varied depending on the actual circumstances.

Further, as shown in fig. 1, the condenser tube assembly 20 further includes a plurality of first baffle plates 11 and a plurality of second baffle plates 15, the plurality of first baffle plates 11 are disposed in the first liquid flow cavity, the plurality of first baffle plates 11 are spaced apart along the width direction of the shell 21, the plurality of second baffle plates 15 are disposed in the second liquid flow cavity, the plurality of second baffle plates 15 are spaced apart along the width direction of the shell 21, a first baffle flow channel 111 is formed adjacent to the first baffle plate 11, a second baffle flow channel 151 is formed adjacent to the second baffle plate 15, the plurality of first baffle flow channels 111 are opposite to the plurality of second baffle flow channels 151, each first baffle flow channel 111 is opposite to and communicates with at least one first through hole, each second baffle flow channel 151 is opposite to and communicates with at least one second through hole, the plurality of cooling water channels 8, the plurality of first baffle flow channels 111, and the plurality of second baffle flow channels 151 together form a cooling water flow channel, the plurality of first baffle flow channels 111 include a first outermost baffle flow channel located at the topmost end and a second outermost baffle flow channel located at the bottommost end, the first outermost baffle flow channel being communicated with the cooling water inlet 5, and the second outermost baffle flow channel being communicated with the cooling water outlet 6.

Specifically, after the cooling water flows into the first outermost baffling flow channel through the cooling water inlet 5, the cooling water can enter the cooling water channel 8 defined by the condenser tube 22 or the baffle plate through the first through hole opposite to the first outermost baffling flow channel, and flow into the second baffling flow channel 151 opposite to the first outermost baffling flow channel through the second through hole along the cooling water channel 8, and the cooling water in the second baffling flow channel 151 can flow into the second baffling flow channel 151 of the next layer through the baffling port of the second baffle plate 15.

The cooling water in the second baffle flow channel 151 of the next layer can flow into the cooling water channel 8 defined by the condenser tube 22 or the baffle plate through the second through hole opposite to the second through hole, and flow into the first baffle flow channel 111 opposite to the first through hole through the first through hole opposite to the cooling water channel 8 along the cooling water channel 8, and the cooling water in the first baffle flow channel 111 can flow into the first baffle flow channel 111 of the next layer through the baffle opening of the first baffle plate 11.

The first baffling flow channel 111 of the next layer flows into the condensate water channel again through the first channel port opposite to the first baffling flow channel 111, and flows along the multilayer first baffling flow channel 111, the plurality of cooling water channels 8 and the multilayer second baffling flow channel 151 in sequence, so that the cooling water can flow along the cooling water flow channel at a certain flow rate, the heat exchange effect of the cooling water is increased, and the heat exchange capacity of the condenser can be controlled by controlling the flowing speed of the cooling water.

In some embodiments, as shown in fig. 1, the condenser further comprises a partition (not shown), the preheating pipe 19 is inserted into the first end plate 14 and the second end plate 10, the partition is connected between the first end plate 14 and the second end plate 10, and the partition is located between the preheating pipe 19 and the flow partition. When the flow partition plate is used to define the cooling water flow passage, the cooling water flow passage is not limited to a sealed flow passage, and in this case, the preheating pipe 19 needs to be separated from the flow partition plate by a partition plate in order to prevent the cooling water from contacting the preheating pipe 19.

In some embodiments, as shown in fig. 1, the front side plate 7 is provided with an air outlet 13, and the air outlet 13 is externally connected with a vacuum pump. Therefore, the vacuum pump can extract the uncondensed steam in the shell 21 through the air outlet 13, the phenomenon that the pressure of the shell 21 is too high is avoided, the steam is extracted out to enable the shell 21 to be in a negative pressure environment, and the high-temperature steam can continuously flow into the shell 21 through the steam inlet 1 conveniently.

Further, as shown in fig. 1, a viewing port 9 is provided in the front side plate 7, and a glass plate is provided at the viewing port 9. Thus, the user can observe and inspect through the glass plate. Preferably, the glass plate is made of tempered glass.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the utility model and to simplify the description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the utility model.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; may be mechanically coupled, may be electrically coupled or may be in communication with each other; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In the present disclosure, the terms "one embodiment," "some embodiments," "an example," "a specific example," or "some examples" and the like mean that a specific feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present disclosure. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims (10)

1. A condenser, comprising:

a housing having a first side plate and a second side plate arranged opposite to each other in a length direction thereof, the first side plate being provided with a cooling water inlet and a cooling water outlet spaced apart in a width direction of the housing, the housing having a top plate and a bottom plate arranged opposite to each other in the width direction thereof, the top plate having a steam inlet thereon, the bottom plate having a condensed water outlet thereon, the cooling water inlet being adjacent to the top plate with respect to the cooling water outlet;

the condensation pipe assembly is arranged in the shell and is provided with a cooling water flow passage, a water inlet of the cooling water flow passage is opposite to the cooling water inlet, and a water outlet of the cooling water flow passage is opposite to the cooling water outlet;

the preheating pipe penetrates through the shell, the preheating pipe is close to the steam inlet relative to the cooling water flow channel, the first end of the preheating pipe extends out of the first side plate, the second end of the preheating pipe extends out of the second side plate, and the preheating pipe is suitable for introducing waste water to be preheated.

2. A condenser as set forth in claim 1 wherein said condenser tube assembly includes first and second end plates each extending in a width direction of said shell and being spaced apart in a length direction of said shell, said first end plate being disposed adjacent to and spaced apart from said first side plate to form a first liquid flow chamber, said second end plate being disposed adjacent to and spaced apart from said second side plate to form a second liquid flow chamber, said shell having front and rear side plates disposed in opposition in a thickness direction thereof, said first end plate being sandwiched between said front and rear side plates, said second end plate being sandwiched between said front and rear side plates, said first, second and front side plates enclosing a gas flow chamber for allowing passage of vapor therethrough, the cooling water inlet is suitable for injecting cooling water into the first liquid flow cavity, and the cooling water in the first liquid flow cavity is suitable for flowing out from the cooling water outlet.

3. A condenser as set forth in claim 2 wherein said condenser tube assembly further comprises a plurality of condenser tubes each forming a cooling water passage, said plurality of condenser tubes being arranged at intervals in a width direction of said shell, the first end of the condensation pipe is connected with the first end plate, the second end of the condensation pipe is connected with the second end plate, the first end plate is provided with a plurality of first through holes which are arranged at intervals along the length direction of the first end plate, the plurality of first through holes are opposite to and communicated with the first ends of the plurality of condensation pipes, the second end plate is provided with a plurality of second through holes which are arranged at intervals along the length direction of the second end plate, the plurality of second through holes are opposite to and communicated with the second ends of the plurality of condensation pipes, the first liquid flow cavity is communicated with the second liquid flow cavity through the first through hole, the condensation pipe and the second through hole.

4. A condenser as claimed in claim 3, wherein the condenser tube assembly further comprises a front cover plate, a top cover plate and a bottom cover plate, the front cover plate, the top cover plate and the bottom cover plate are connected between the first end plate and the second end plate, the top cover plate and the bottom cover plate are opposite and spaced apart in a length direction of the housing, the top cover plate, the bottom cover plate, the top plate and the bottom plate are parallel to each other, a rear side surface of the top cover plate is attached to and connected to the rear side plate, a rear side surface of the bottom cover plate is attached to and connected to the rear side plate, the top cover plate, the bottom cover plate, the first end plate, the second end plate and the rear side plate may define a cooling water flow chamber having an opening, and the front cover plate is connected to the opening of the cooling water flow chamber to close the opening.

5. A condenser as set forth in claim 4 further comprising a plurality of flow partitioning plates arranged in said cooling water flow chamber at intervals in a width direction of said housing, one end of said flow partitioning plate being connected to said first end plate and the other end of said flow partitioning plate being connected to said second end plate, a cooling water passage being formed between adjacent ones of said flow partitioning plates, said first end plate having a plurality of first through holes arranged at intervals in a length direction thereof, said plurality of first through holes being opposed to and communicating with first ends of said plurality of cooling water passages, said second end plate having a plurality of second through holes arranged at intervals in a length direction thereof, said plurality of second through holes being opposed to and communicating with second ends of said plurality of cooling water passages.

6. A condenser as set forth in any one of claims 3 to 5 wherein said condenser tube assembly further comprises a plurality of first baffle plates disposed between said first end plate and said first side plate, a plurality of said first baffle plates being spaced apart along the width of said shell, a plurality of said second baffle plates being disposed between said second end plate and said second side plate, a plurality of said second baffle plates being spaced apart along the width of said shell, a first baffle flow passage being defined adjacent to said first baffle plates, a second baffle flow passage being defined adjacent to said second baffle plates, a plurality of said first baffle flow passages being opposed to a plurality of said second baffle flow passages, each of said first baffle flow passages being opposed to and communicating with at least one of said first through holes, each of said second baffle flow passages being opposed to and communicating with at least one of said second through holes, it is a plurality of cooling water passageway, a plurality of first baffling runner and a plurality of second baffling runner constitutes jointly the cooling water runner, and is a plurality of first baffling runner is including the first outside baffling runner that is located the top and the second outside baffling runner that is located the bottom, first outside baffling runner with cooling water inlet intercommunication, the second outside baffling runner with cooling water outlet intercommunication.

7. A condenser as claimed in claim 5, further comprising a partition, wherein said preheat tube is disposed through said first end plate and said second end plate, said partition is connected between said first end plate and said second end plate, and said partition is located between said preheat tube and a flow divider.

8. The condenser as claimed in claim 2, wherein the front plate is provided with an air outlet, and the air outlet is externally connected with a vacuum pump.

9. The condenser as claimed in claim 2, wherein said front plate is provided with a viewing port, and said viewing port is provided with a glass plate.

10. The condenser as claimed in claim 9, wherein said glass plate is made of tempered glass.

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