SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a condensation corrosion prevention device to it is lower to alleviate the cooling efficiency who exists among the prior art, and condensing equipment is corroded by the impurity in the gas easily, influences equipment life's technical problem.
The utility model provides a condensation corrosion prevention device for the vapor in the condensation gas circuit, include: the condensation mechanism, the refrigeration mechanism, the heat dissipation mechanism and the reactant;
the condensing mechanism is connected with the heat dissipation mechanism, the refrigerating mechanism is arranged between the condensing mechanism and the heat dissipation mechanism, two sides of the refrigerating mechanism are respectively abutted against the condensing mechanism and the heat dissipation mechanism, the gas circuit is arranged in the condensing mechanism, the refrigerating mechanism is used for providing a cold source for the condensing mechanism, and the heat dissipation mechanism is used for taking away the heat of the refrigerating mechanism;
the reactant is positioned in the gas circuit, the reactant is connected with the condensing mechanism, and the reactant is used for carrying out chemical reaction with impurities in the gas circuit.
In an alternative embodiment, the condensing mechanism comprises an air inlet hole, an air outlet hole, a water discharge hole and a condensing main body;
the air inlet hole and the air outlet hole are arranged on one side of the condensation main body, the drain hole is arranged on the other side of the condensation main body, the air path is arranged in the condensation main body, and the air inlet hole, the air outlet hole and the drain hole are communicated with the air path.
In an alternative embodiment, a groove is arranged at one end of the condensation body away from the refrigeration mechanism;
the groove is sunken along the direction close to the refrigerating mechanism, the cross section of the groove is C-shaped, two ends of the groove are respectively communicated with the air inlet hole and the air outlet hole, one end of the groove, far away from the air inlet hole and the air outlet hole, is communicated with the drain hole, and the air path is arranged in the groove.
In an optional implementation mode, one end, close to the refrigeration mechanism, of the condensation main body is provided with a limiting groove, the shape of the limiting groove is consistent with that of the refrigeration mechanism, and the limiting groove is used for clamping the refrigeration mechanism.
In an optional embodiment, the condensation body is provided with a heat dissipation hole;
the heat dissipation hole penetrates through the condensation main body in the thickness direction, one end of the heat dissipation hole is arranged in the limiting groove, and the heat dissipation hole is used for dissipating heat of the condensation main body.
In an alternative embodiment, the condensing mechanism further comprises a sealing plate;
the sealing plate is arranged at one end, far away from the refrigerating mechanism, of the condensation main body, the sealing plate is connected with the condensation main body, and the sealing plate is used for sealing the groove.
In an alternative embodiment, the condensing mechanism further comprises a first seal and a second seal;
the first sealing piece and the second sealing piece are annular, the first sealing piece and the second sealing piece are arranged between the condensation main body and the sealing plate, the first sealing piece is arranged on the outer side of the groove, the second sealing piece is arranged on the inner side of the groove, and the first sealing piece and the second sealing piece are used for sealing the groove.
In an alternative embodiment, the condensation body is provided with a first sealing groove and a second sealing groove;
the first sealing groove and the second sealing groove are arranged at one end, close to the sealing plate, of the condensation main body, the first sealing groove is arranged on the outer side of the groove, the second sealing groove is arranged on the inner side of the groove, the first sealing groove is used for fixing the first sealing element, and the second sealing groove is used for fixing the second sealing element.
In an alternative embodiment, the heat dissipation mechanism comprises a fan and a heat sink;
the fan is arranged at one end, far away from the refrigerating mechanism, of the radiating fin, and the fan and the radiating fin are connected with the condensing mechanism through bolts.
In an optional embodiment, the heat preservation piece is further included;
the heat preservation piece is arranged at one end, far away from the refrigerating mechanism, of the condensing mechanism, and the heat preservation piece is wrapped on the end face and the periphery of the condensing mechanism.
The utility model provides a condensation corrosion prevention device is arranged in the vapor of condensation gas circuit, include: the condensation mechanism, the refrigeration mechanism, the heat dissipation mechanism and the reactant; the two sides of the refrigerating mechanism are respectively abutted with the condensing mechanism and the heat dissipation mechanism, a gas circuit is arranged in the condensing mechanism, and the refrigerating mechanism is used for providing a cold source for the condensing mechanism, so that the temperature of the condensing mechanism is reduced, namely, the temperature of gas in the gas circuit is reduced, so that water vapor is condensed into water drops when meeting the condensation and separated from the gas, and the water drops are discharged in a gas-liquid separation mode; the heat dissipation mechanism is used for taking away heat of the refrigeration mechanism, and can be connected with the refrigeration mechanism in a fan, a cooling fin and other modes, so that the refrigeration mechanism keeps a lower temperature in the refrigeration process, and the condensation efficiency of water vapor is improved; the reactant is arranged in the gas circuit and is connected with the condensing mechanism, and the reactant is used for carrying out oxidation-reduction reaction with impurities in the gas circuit, so that oxidant impurities in the gas circuit are reduced to obtain a stable reduction product, thereby alleviating the technical problem that the condensing equipment is easily corroded by the impurities in the gas and influences the service life of the equipment, achieving the technical effects of improving the cooling efficiency and prolonging the service life of the equipment.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.
Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.
It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.
In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate the position or positional relationship based on the position or positional relationship shown in the drawings, or the position or positional relationship which is usually placed when the product of the present invention is used, and are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element referred to must have a specific position, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.
Furthermore, the terms "horizontal", "vertical", "overhang" and the like do not imply that the components are required to be absolutely horizontal or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.
In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.
Some embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The embodiments described below and the features of the embodiments can be combined with each other without conflict.
As shown in fig. 1 and fig. 2, the embodiment of the utility model provides a condensation corrosion prevention device for the vapor in the condensation gas circuit includes: a condensing mechanism 100, a refrigerating mechanism 200, a heat dissipation mechanism 300 and reactants; the condensing mechanism 100 is connected with the heat dissipation mechanism 300, the refrigerating mechanism 200 is arranged between the condensing mechanism 100 and the heat dissipation mechanism 300, two sides of the refrigerating mechanism 200 are respectively abutted against the condensing mechanism 100 and the heat dissipation mechanism 300, a gas path is arranged in the condensing mechanism 100, the refrigerating mechanism 200 is used for providing a cold source for the condensing mechanism 100, and the heat dissipation mechanism 300 is used for taking away heat of the refrigerating mechanism 200; the reactant is located in the gas path, and the reactant is connected with the condensing mechanism 100, and the reactant is used for carrying out chemical reaction with the impurities in the gas path.
It should be noted that, in the present embodiment, the condensing mechanism 100 may be made of stainless steel material to prevent corrosion elements in the gas from corroding the condensing mechanism 100, wherein the condensing mechanism 100 and the heat dissipating mechanism 300 may be connected by bolts, the refrigerating mechanism 200 is fixed between the condensing mechanism 100 and the heat dissipating mechanism 300 due to the extrusion of the condensing mechanism 100 and the heat dissipating mechanism 300, the refrigerating mechanism 200 may employ peltier, one end of the refrigerating mechanism 200 outputting a cold source is attached to the condensing mechanism 100, the other end of the refrigerating mechanism 200 is attached to the heat dissipating mechanism 300, the refrigerating mechanism 200 outputting the cold source to the condensing mechanism 100 to lower the temperature of both the condensing mechanism 100 and the internal gas path thereof, that is, when the gas in the internal gas path is cooled, the water vapor in the gas is condensed into water droplets, and then the water droplets are removed from the condensing mechanism 100 by gas-liquid separation, thereby reach the purpose of getting rid of the vapor in the gas circuit, furtherly, heat dissipation mechanism 300 is used for continuously taking away the heat of refrigerating mechanism 200 and condensing mechanism 100, the refrigeration efficiency of refrigerating mechanism 200 has been guaranteed, prevent that refrigerating mechanism 200 temperature rising from leading to the refrigeration inefficiency, supplementary refrigerating mechanism 200 cools down condensing mechanism 100 simultaneously, and in the gas circuit, the reactant that this embodiment mentioned can set up to the silver-colored silk, the silver-colored silk setting can be dismantled with condensing mechanism 100 in the gas circuit and be connected, impurity in the gas circuit includes halogen, so that reactant and the impurity in the gas circuit take place redox reaction, thereby prevent halogen and condensing mechanism 100 reaction, make condensing mechanism 100 corroded, and then influence the life of device.
The embodiment of the utility model provides a condensation corrosion prevention device is arranged in the vapor of condensation gas circuit, include: a condensing mechanism 100, a refrigerating mechanism 200, a heat dissipation mechanism 300 and reactants; the two sides of the refrigeration mechanism 200 are respectively abutted against the condensation mechanism 100 and the heat dissipation mechanism 300, a gas path is arranged in the condensation mechanism 100, and the refrigeration mechanism 200 is used for providing a cold source for the condensation mechanism 100, so that the temperature of the condensation mechanism 100 is reduced, namely, the temperature of gas in the gas path is reduced, so that water vapor is condensed into water drops when meeting condensation and separated from the gas, and the water drops are discharged in a gas-liquid separation mode; the heat dissipation mechanism 300 is used for taking away heat of the refrigeration mechanism 200, and the heat dissipation mechanism 300 can be connected with the refrigeration mechanism 200 in a mode of a fan 310, a heat dissipation fin 320 and the like, so that the refrigeration mechanism 200 keeps a lower temperature in the refrigeration process, and the condensation efficiency of water vapor is improved; the reactant is located the gas circuit, and the reactant is connected with condensing mechanism 100, and the reactant is used for taking place redox reaction with the impurity in the gas circuit, makes the oxidant impurity in the gas circuit obtain stable reduction product after being reduced to it is corroded by the impurity in the gas easily to have alleviated condensing equipment, influences the technical problem of the life of equipment, has reached and has improved cooling efficiency, has prolonged the technical effect of the life of equipment simultaneously.
In an alternative embodiment, the condensing mechanism 100 includes an air inlet hole 110, an air outlet hole 120, a water discharge hole 130, and a condensing body 140; the air inlet hole 110 and the air outlet hole 120 are disposed at one side of the condensation main body 140, the water discharge hole 130 is disposed at the other side of the condensation main body 140, an air path is disposed in the condensation main body 140, and the air inlet hole 110, the air outlet hole 120 and the water discharge hole 130 are all communicated with the air path.
In this embodiment, the cross-section of the condensation main body 140 is rectangular, a side of the condensation main body 140 is provided with a drain hole 130, another side opposite to the side is provided with an air inlet hole 110 and an air outlet hole 120, and the drain hole 130, the air inlet hole 110 and the air outlet hole 120 are communicated through an air path in the condensation main body 140, in the using process, the condensation main body 140 can be vertically placed, that is, the drain hole 130 is located at a lower altitude position, the air inlet hole 110 and the air outlet hole 120 are located at a higher altitude position, so that the mixed gas enters from the air inlet hole 110, is condensed by the condensation main body 140 and is discharged from the air outlet hole 120, and water drops generated after condensation and impurities generated by chemical reaction can be discharged from the condensation main body 140 through the drain hole 130 at the lower altitude position, thereby avoiding a large amount of water drops and chemicals generated after reaction in the air path, and enabling the device to be used for a long time.
In an alternative embodiment, an end of the condensation body 140 remote from the refrigeration mechanism 200 is provided with a groove 141; the groove 141 is recessed along a direction close to the refrigeration mechanism 200, the cross section of the groove 141 is in a shape of a 'C', two ends of the groove 141 are respectively communicated with the air inlet hole 110 and the air outlet hole 120, one end of the groove 141, which is far away from the air inlet hole 110 and the air outlet hole 120, is communicated with the water discharge hole 130, and an air path is arranged in the groove 141.
In this embodiment, the groove 141 is an unclosed ring, two ends of the groove 141 are respectively communicated with the air inlet hole 110 and the air outlet hole 120, so that the air inlet hole 110 is discharged through the air outlet hole 120 after passing through the groove 141, the length of the air path is prolonged, the heat exchange time between the air and the condensation main body 140 is longer, the heat exchange is more sufficient, that is, the condensation of the water vapor is more sufficient, further, the drain hole 130 is arranged at the middle position of the groove 141, when the condensation main body 140 is vertically placed, the drain hole 130 can be located at the lowest position, at this time, water drops in the groove 141 can conveniently flow to the drain hole 130 and flow out from the drain hole 130 due to the action of gravity, and the water drops in the air path can conveniently flow out.
In an alternative embodiment, a limiting groove 142 is disposed at one end of the condensation body 140 close to the refrigeration mechanism 200, the shape of the limiting groove 142 is the same as that of the refrigeration mechanism 200, and the limiting groove 142 is used for clamping the refrigeration mechanism 200.
In this embodiment, the cross-section of spacing groove 142 and refrigeration mechanism 200 all is the rectangle, and spacing groove 142 is along keeping away from one side of refrigeration mechanism 200 sunken, and refrigeration mechanism 200 places in spacing groove 142 and with the bottom butt of spacing groove 142, the other end and the heat dissipation mechanism 300 butt of refrigeration mechanism 200, refrigeration mechanism 200 all around with the butt all around of spacing groove 142 to it is more firm to make refrigeration mechanism 200 install.
In an alternative embodiment, the condensation body 140 is provided with heat dissipation holes 143; the heat dissipation hole 143 penetrates along the thickness direction of the condensation body 140, one end of the heat dissipation hole 143 is disposed in the limiting groove 142, and the heat dissipation hole 143 is used for dissipating heat for the condensation body 140.
In this embodiment, the heat dissipation hole 143 is cylindrical, the heat dissipation hole 143 penetrates the condensation body 140 along the thickness direction of the condensation body 140, the heat dissipation hole 143 is located in the groove 141, and the axis of the heat dissipation hole 143 is located at the center of the condensation body 140, that is, one end of the heat dissipation hole 143 is opposite to the refrigeration mechanism 200, so that the refrigeration mechanism 200 can directly convey a cold source from the heat dissipation hole 143, the contact area between the condensation body 140 and the cold source is increased, that is, the condensation efficiency of the condensation body 140 is increased.
In an alternative embodiment, the condensing mechanism 100 further includes a sealing plate 150; a sealing plate 150 is disposed at an end of the condensing body 140 away from the refrigerating mechanism 200, the sealing plate 150 being connected to the condensing body 140, the sealing plate 150 sealing the groove 141.
In this embodiment, the shape of the sealing plate 150 is the same as the shape of the condensation body 140, the sealing plate 150 may be connected to the condensation body 140 by bolts, and the sealing plate 150 may seal the groove 141 and the heat dissipation holes 143, that is, the sealing plate 150 may form a tight gas path with the groove 141, thereby preventing gas leakage during condensation, and simultaneously preventing a cold source of the refrigeration mechanism 200 from leaking from one end of the heat dissipation hole 143 away from the refrigeration mechanism 200, thereby ensuring sufficient contact between the cold source and the condensation body 140, and increasing condensation efficiency.
In an alternative embodiment, the condensing mechanism 100 further includes a first seal 160 and a second seal 170; the first and second sealing members 160 and 170 are ring-shaped, the first and second sealing members 160 and 170 are disposed between the condensation body 140 and the sealing plate 150, the first sealing member 160 is disposed at an outer side of the groove 141, the second sealing member 170 is disposed at an inner side of the groove 141, and both the first and second sealing members 160 and 170 are used to seal the groove 141.
In this embodiment, the first sealing member 160 and the second sealing member 170 may be configured as annular rubber rings, the diameter of the first sealing member 160 is larger than that of the second sealing member 170, the second sealing member 170 is disposed outside the heat dissipation hole 143 and inside the groove 141, the first sealing member 160 is disposed outside the groove 141 and inside the edge of the condensation body 140, and the first sealing member 160 and the second sealing member 170 are both pressed on the condensation body 140 by the sealing plate 150, so that the gas path inside the groove 141 is more tight, the influence of the internal gas leakage on the measurement accuracy is prevented, and the measurement is more accurate.
In an alternative embodiment, the condensation body 140 is provided with a first sealing groove 180 and a second sealing groove 190; the first and second seal grooves 180 and 190 are disposed at one end of the condensation body 140 close to the sealing plate 150, the first seal groove 180 is disposed at an outer side of the groove 141, the second seal groove 190 is disposed at an inner side of the groove 141, the first seal groove 180 is used to fix the first seal 160, and the second seal groove 190 is used to fix the second seal 170.
In this embodiment, the first and second seal grooves 180 and 190 are annular, the size of the first seal groove 180 is the same as that of the first seal 160, the size of the second seal groove 190 is the same as that of the second seal 170, the diameter of the first seal groove 180 is larger than that of the second seal groove 190, the second seal groove 190 is disposed outside the heat dissipation hole 143 and inside the groove 141, the first seal groove 180 is disposed outside the groove 141 and inside the edge of the condensation body 140, so that the first seal 160 is disposed in the first seal groove 180, the second seal 170 is disposed in the second seal groove 190, and the seal plate 150 compresses the first and second seals 160 and 170, thereby preventing the first and second seals 160 and 170 from deforming, and further stabilizing the sealing of the first and second seals 160 and 170.
In an alternative embodiment, heat dissipation mechanism 300 includes a fan 310 and a heat sink 320; the fan 310 is disposed at an end of the heat sink 320 away from the refrigeration mechanism 200, and both the fan 310 and the heat sink 320 are connected to the condensation mechanism 100 by bolts.
In this embodiment, the fan 310 abuts against the heat sink 320, and the fan 310 blows air towards the end away from the heat sink 320, so that the fan 310 can take away the heat of the heat sink 320, and further, the heat sink 320 can be made of heat-conducting metal, so that the heat dissipation effect is better, the heat of the refrigeration mechanism 200 and the heat of the condensation main body 140 can be conducted out, and the heat is exhausted by the fan 310, so that the condensation efficiency is higher.
In an alternative embodiment, a thermal insulator 400 is also included; the heat preservation part 400 is arranged at one end of the condensation mechanism 100 far away from the refrigeration mechanism 200, and the heat preservation part 400 is wrapped at the end face and the periphery of the condensation mechanism 100.
In this embodiment, the heat preservation 400 sets up in the outside of condensation main part 140 and closing plate 150, and heat preservation 400 passes through the bolt to be connected with closing plate 150, and heat preservation 400 is along the surface of closing plate 150 and the cladding all around of condensation main part 140, and heat preservation 400 adopts the heat preservation material, and heat preservation 400 can prevent the temperature of external temperature influence condensation main part 140, reduces the loss of the cold source that refrigeration mechanism 200 provided simultaneously, plays the technological effect that improves condensation efficiency.
Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.