CN115406264A - Container formula is wet compound cooling arrangement futilely - Google Patents

Abstract

The invention provides a container type dry-wet composite cooling device, which comprises: a cooling assembly unit; the spraying unit is used for primarily cooling substances and arranged in the middle of the inside of the cooling assembly unit; the cooling assembly unit comprises a quick cooling component; the quick cooling assembly comprises: a first jetting assembly; the second spraying assembly is used for being matched with the first spraying assembly to cool the cooled substance and is arranged at one end opposite to the first spraying assembly; and the medium control mechanism is used for controlling the injection speed of the cooling medium and is arranged at the upper part of the first injection assembly and the lower part of the second injection assembly. The invention can automatically control the injection speed of the cooling medium according to the real-time temperature of the cooled substance, can quickly cool the transmitted substance on the premise of ensuring the minimum consumption of the medium in unit time, and has the advantages of high cooling efficiency, energy saving and environmental protection.

Description

Container formula is wet compound cooling arrangement futilely

Technical Field

The invention relates to the technical field of dry and wet cooling, in particular to container type dry and wet composite cooling equipment.

Background

The cooling tower mainly takes away heat by means of circulating water spraying and evaporation so as to achieve the purpose of cooling, ambient cold air enters the cooling tower, is guided and discharged out of the tower through a fan at the top of the cooling tower after being heated and humidified, damp and hot air in the cooling tower is discharged in time, and the damp and hot air brings adverse effects to subsequent cooling effects.

Chinese patent CN216977314U discloses a megawatt level integrated form intelligent cooling device, the power distribution box comprises a box body, the front and the back of box all are provided with the web, the top of box is provided with the roof, the size design of standard container is chooseed for use to box, web and roof, the inside of box is provided with cooling body, cooling body's left side is provided with intelligent control case, intelligent control case includes level sensor control unit, temperature sensor control unit, sprays pump intelligent control unit, fan intelligent control unit, water quality testing unit and alarm unit, alarm unit contains the buzzer siren, the inside of box and the upper and lower both sides that are located cooling body are provided with ventilation mechanism.

However, the technical scheme has the following defects:

1. according to the scheme, the conveyed substances are cooled only in a spraying mode, and in the spraying process, as spraying liquid is dispersed, sprayed media cannot be in complete contact with a pipeline for conveying the substances, so that the phenomenon of uneven cooling exists;

2. the scheme can not carry out rapid and continuous cooling according to the real-time temperature of the conveyed substance in the conveying process on the premise of keeping spraying, and has low cooling efficiency and poor cooling effect.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides container type dry-wet composite cooling equipment, which can be used for automatically controlling the spraying speed of a cooling medium according to the real-time temperature of a substance in a conveying pipeline on the premise of spraying, ensuring that the conveyed substance can be quickly cooled on the premise of consuming the least medium in unit time, and being high in cooling efficiency, energy-saving and environment-friendly.

In order to achieve the purpose, the invention provides the following technical scheme:

a container-type dry-wet hybrid cooling device, comprising:

a cooling assembly unit;

the spraying unit is used for primarily cooling substances and arranged in the middle of the inside of the cooling assembly unit;

the cooling assembly unit comprises a quick cooling component;

the quick cooling assembly comprises:

a first jetting assembly;

the second spraying assembly is used for being matched with the first spraying assembly to cool the cooled substance and is arranged at one end opposite to the first spraying assembly;

the medium control mechanism is used for controlling the injection speed of the cooling medium and is arranged at the upper part of the first injection assembly and the lower part of the second injection assembly; and

the first conveying pipe fitting is used for conveying a cooled substance and is arranged inside the first spraying assembly;

the cooled substance is conveyed along the inside of the first conveying pipe fitting, the spraying unit sprays cooling medium to the first conveying pipe fitting, and meanwhile, the first spraying assembly and the second spraying assembly swing back and forth along the first conveying pipe fitting and spray cooling work is carried out along the substance conveying direction under the action of the spraying speed controlled by the medium control mechanism.

As an improvement, the cooling assembly unit further comprises:

a cooling aid assembly;

the cooling assistance assembly includes:

a support;

the medium collecting frame is arranged at the bottom in the bracket;

and the infusion pump is used for sending the cooling medium in the medium collection frame into the spraying unit and is arranged on the side part of the medium collection frame.

As an improvement, the quick cooling assembly further comprises:

the first liquid separation frame is connected to the side part of the bracket;

the side part of the first liquid separation frame is connected with a first reciprocating screw rod and a second reciprocating screw rod in a rotating mode near the lower part, and the first reciprocating screw rod and the second reciprocating screw rod are used for driving the second injection assembly to reciprocate;

and the side part of the first liquid distribution frame is connected with a third reciprocating lead screw and a fourth reciprocating lead screw which are used for driving the first injection assembly to reciprocate in a rotating way.

As a refinement, the first jetting assembly comprises:

a slider;

the reciprocating frame is connected to the lower end of the sliding block;

a flow guide hole for transmitting a cooling medium is formed in the reciprocating frame;

the middle inside the reciprocating frame is connected with a flow dividing piece;

the upper end and the lower end of the flow dividing piece and the inner wall of the reciprocating frame are both provided with a nozzle;

the spout runs through to reciprocal frame and reposition of redundant personnel outside by water conservancy diversion downthehole portion.

As an improvement, the medium control mechanism includes:

a liquid guide rod;

the baffle plate is connected with the inner wall of the liquid guide rod;

the sliding block is inserted in the liquid guide rod in a sliding mode and is located at the lower end of the partition plate;

two sides of the sliding block along the sliding direction of the liquid guide rod are connected with liquid sealing plates;

the liquid sealing plate is in sealing contact with the baffle plate;

and two sides inside the liquid guide rod are connected with limiting blocks used for limiting the sliding block.

As an improvement, a flow control groove is arranged in the baffle;

the flow control groove is gradually reduced along the moving direction of the sliding block;

a liquid inlet is formed in the sliding block;

the opening size of the liquid inlet is equal to the maximum opening of the flow control groove.

As an improvement, the first conveying pipe fittings are arranged in a double-layer staggered arrangement along the interior of the first spraying assembly;

a first liquid guide arc is arranged on the side part of the first conveying pipe fitting of the first layer;

a second liquid guide arc is arranged on the side part of the first conveying pipe fitting on the second layer;

the upper end of the second liquid guide arc is positioned at the liquid outlet end of the first liquid guide arc.

As an improvement, the flow dividing piece divides the interior of the reciprocating frame into two equal sections from top to bottom;

and the inner parts of the upper and lower areas are provided with first conveying pipe fittings which are arranged in a double-layer staggered manner.

As an improvement, the spray unit comprises:

a medium transfer pipe;

and the spraying port is used for spraying and cooling the first conveying pipe fitting and is connected to the lower end of the medium transfer pipe.

As an improvement, the cooling assistance assembly further comprises:

the third liquid distribution frame is connected to one side, opposite to the infusion pump, of the support;

a second air cooling pipe is connected to the side part of the third liquid distribution frame;

a first air cooling pipe is connected to the lower side of the side part of the third liquid distribution frame;

the first air cooling pipe and the outer side of the second air cooling pipe are both sleeved with radiating fins.

The invention has the beneficial effects that:

(1) According to the invention, the first conveying pipe fitting is matched with the second conveying pipe fitting to divide the cooled substance in the first liquid dividing frame along the lower part of the spraying unit and the reciprocating frame, the water cooling is carried out firstly after the material is subjected to reciprocating transportation, and then the material is subjected to air cooling through the first air cooling pipe and the second air cooling pipe respectively, so that the cooling path is prolonged in a smaller space, and the cooling effect is improved. .

(2) When the third reciprocating screw rod and the fourth reciprocating screw rod drive the reciprocating frame to move reversely, the liquid inlet moves along the direction that the opening of the flow control groove is gradually reduced, so that the cooling medium sprayed by the nozzle is gradually slowed down, the spraying speed of the cooling medium can be automatically controlled according to the real-time temperature of the cooled substance, the transferred substance can be rapidly cooled on the premise of ensuring the minimum consumption of the medium in unit time, the cooling efficiency is high, and the effects of energy conservation and environmental protection are achieved.

(3) According to the invention, the middle inside the reciprocating frame is divided into two equal intervals through the flow dividing piece, and the first conveying pipe fittings are arranged in a double-layer staggered manner, so that when a plurality of groups of first conveying pipe fittings are sprayed along the inner part of the reciprocating frame and the nozzles at the upper end and the lower end of the flow dividing piece, the spraying can be carried out in an all-around dead angle-free manner, and the cooling effect is further improved.

(4) According to the invention, the sprayed cooling medium is attached to the first conveying pipe fitting to slide downwards along the first liquid guide arc, then slides to the second liquid guide arc and is attached to the other first conveying pipe fitting arranged in a staggered manner again, and finally falls into the medium collecting frame to be collected, so that the sprayed medium falls in a transitional manner along the liquid guide arc, the cooling medium can be in surface contact with a pipeline for conveying substances, the contact area between the cooling medium and the cooled substances is increased, and the effect of more uniform spraying is ensured.

(5) According to the invention, the radiating fins are sleeved on the outer sides of the first air cooling pipe and the second air cooling pipe, so that when sprayed cooled substances pass through the first air cooling pipe and the second air cooling pipe, heat can be continuously transferred to the outer parts of the radiating fins, the radiating area is increased, meanwhile, the heat on the surfaces of the radiating fins is rapidly brought out under the action of the fans, and the cooling effect is further improved.

In conclusion, the invention has the advantages of good cooling effect, high cooling efficiency and the like.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic view showing the flow state of the internal liquid according to the present invention;

FIG. 4 is a diagram of the relationship between the spray units and the cooling assembly units of the present invention;

FIG. 5 is a schematic view of the construction of the instant cooling assembly of the present invention;

FIG. 6 is a state diagram of the spraying process of the present invention;

FIG. 7 is an enlarged view of the invention at A in FIG. 6;

FIG. 8 is a view of the first injector assembly of the present invention in cooperation with a third reciprocating lead screw;

FIG. 9 is a diagram of the engagement of a media control mechanism with a first jetting assembly in accordance with the present invention;

FIG. 10 isbase:Sub>A cross-sectional view of the invention at A-A in FIG. 9;

FIG. 11 is a cross-sectional view of the present invention at B-B in FIG. 10;

FIG. 12 is a view showing the fitting relationship between the cooling aid assembly and the air-cooling unit according to the present invention;

fig. 13 is an enlarged view of the invention at B in fig. 12.

In the figure, 1, a cooling assembly unit; 2. a spraying unit; 3. an air-cooling unit; 11. a quick cooling assembly; 12. a cooling aid assembly; 111. a first liquid separating frame; 112. a first spray assembly; 113. a second jetting assembly; 114. a medium control mechanism; 115. a first conveying pipe; 1111. a first reciprocating screw; 1112. a second reciprocating screw; 1113. a third reciprocating screw; 1114. a fourth reciprocating screw; 11110. a first belt; 11120. a second belt; 11130. a third belt; 1120. a slider; 11201. a liquid inlet; 11202. a liquid sealing plate; 1121. a reciprocating frame; 1122. a flow splitter; 11211. a flow guide hole; 1123. a spout; 1140. a media inlet tube; 1141. a liquid guide rod; 11411. a limiting block; 1142. a baffle plate; 11421. a flow control groove; 1151. a first liquid guiding arc; 1152. a second liquid guiding arc; 1153. a second conveying pipe; 121. a support; 122. a media collection frame; 123. an infusion pump; 1231. a first catheter; 124. a first liquid inlet pipe; 1241. a media shunt box; 125. a second liquid separation frame; 126. a second liquid inlet pipe; 127. a third liquid distribution frame; 1271. a first air-cooled duct; 1272. a second air-cooled duct; 1273. a heat sink; 128. a liquid outlet pipe; 201. a medium transfer pipe; 202. a spray port; 301. a fan.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations or positional relationships based on those shown in the drawings, merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. 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 one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Example one

As shown in fig. 1-2, the present embodiment provides a container type dry-wet composite cooling device, comprising:

a cooling assembly unit 1;

the spraying unit 2 is used for primarily cooling the substance, and the spraying unit 2 is arranged in the middle inside the cooling assembly unit 1;

the cooling assembly unit 1 comprises a box body and a quick cooling component 11; the box body is designed by adopting the standard size of a container, so that the cooling equipment can be quickly assembled and disassembled without being singly packaged in the transportation process; meanwhile, the bottom of one side of the box body is provided with an openable water baffle, and a plurality of groups of fans 301 are fixed inside the lower portion of the box body after being detached in the transportation process, so that the whole transportation is facilitated.

The rapid cooling assembly 11 comprises:

a first jetting assembly 112;

the second spraying assembly 113 is used for matching with the first spraying assembly 112 to cool the cooled substance, and the second spraying assembly 113 is arranged at one end opposite to the first spraying assembly 112;

a medium control mechanism 114, the medium control mechanism 114 for controlling the injection speed of the cooling medium being disposed both in the upper portion of the first injection assembly 112 and in the lower portion of the second injection assembly 113; and

a first delivery pipe 115, wherein the first delivery pipe 115 for delivering the cooled substance is arranged inside the first injection assembly 112;

the cooled material is transported along the inside of the first conveying pipe member 115, and the spray unit 2 sprays the cooling medium to the first conveying pipe member 115, and at the same time, the first spray assembly 112 and the second spray assembly 113 perform the spray cooling work along the material transport direction under the control of the spray speed by the medium control mechanism 114 while oscillating back and forth along the first conveying pipe member 115.

As a modification, as shown in fig. 1 to 3, the cooling assembly unit 1 further includes:

a cooling aid assembly 12;

the cooling assistance assembly 12 includes:

a bracket 121;

the medium collecting frame 122 is arranged at the bottom in the bracket 121;

the infusion pump 123 is used for conveying the cooling medium in the medium collection frame 122 into the spraying unit 2, and the infusion pump 123 is arranged on the side part of the medium collection frame 122;

a first liquid guide pipe 1231 communicated with the interior of the medium flow dividing box 1241 is arranged at the upper end of the infusion pump 123;

the side part of the first liquid separation frame 111 is connected with a first liquid inlet pipe 124;

the side parts of the first conveying pipe 115, the first liquid guiding arc 1151, the second liquid guiding arc 1152 and the second conveying pipe 1153 are connected with the first liquid dividing frame 111;

the first conveying pipe 115 and the second conveying pipe 1153 are both communicated with the inside of the first liquid-separating frame 111, and a partition plate for separating the substance entering the second conveying pipe 1153 from the substance discharged from the first conveying pipe 115 is arranged in the middle of the inside of the first liquid-separating frame 111;

a second liquid separating frame 125 is arranged at the discharge end of the second conveying pipe fitting 1153 and the feed end of the first conveying pipe fitting 115;

the upper part of the first conveying pipe fitting 115 is communicated with a first air cooling pipe 1271 through a second liquid inlet pipe 126;

the discharge end of the second air-cooling tube 1272 is connected with an outlet tube 128.

Further, as shown in fig. 4-6 and 8, the quick cooling module 11 further includes:

a first liquid separation frame 111, wherein the first liquid separation frame 111 is connected to the side of the bracket 121;

a first reciprocating lead screw 1111 and a second reciprocating lead screw 1112 for driving the second spraying assembly 113 to reciprocate are rotatably connected to the side part of the first liquid separating frame 111 close to the lower part;

a third reciprocating lead screw 1113 and a fourth reciprocating lead screw 1114 for driving the first spraying assembly 112 to reciprocate are rotatably connected to the side part of the first liquid distribution frame 111.

It should be added that a driving motor is disposed at one end of the first reciprocating screw 1111 and inside the first liquid separation frame 111, which is not shown in the figure, the first reciprocating screw 1111 is connected to the second reciprocating screw 1112 through a first belt 11110, the second reciprocating screw 1112 is connected to the third reciprocating screw 1113 through a second belt 11120, and the third reciprocating screw 1113 is connected to the fourth reciprocating screw 1114 through a third belt 11130.

As a modification, as shown in fig. 8 to 11, the first injection assembly 112 includes:

a slider 1120;

a reciprocating frame 1121, wherein the reciprocating frame 1121 is connected to the lower end of the sliding block 1120;

a flow guide hole 11211 for transmitting a cooling medium is arranged inside the reciprocating frame 1121;

a flow divider 1122 is connected in the middle inside the reciprocating frame 1121;

the upper end and the lower end of the flow dividing piece 1122 and the inner wall of the reciprocating frame 1121 are both provided with a nozzle 1123;

the nozzle 1123 penetrates from the inside of the diversion hole 11211 to the outside of the reciprocating frame 1121 and the flow divider 1122.

Further, as shown in fig. 9 to 11, the medium control mechanism 114 includes:

a liquid guiding bar 1141;

the baffle 1142 is connected with the inner wall of the liquid guide rod 1141;

the sliding block 1120 is inserted into the liquid guide bar 1141 in a sliding manner and is located at the lower end of the baffle 1142;

both sides of the sliding block 1120 along the sliding direction of the liquid guide rod 1141 are connected with liquid sealing plates 11202;

the liquid sealing plate 11202 is in sealing contact with the baffle 1142;

two sides inside the liquid guide rod 1141 are connected with a limiting block 11411 for limiting the sliding block 1120;

it should be added that one end of the liquid guiding rod 1141 is communicated with the inside of the medium flow dividing box 1241 through the medium inlet pipe 1140.

Further, as shown in fig. 9-10, a flow control groove 11421 is formed inside the baffle 1142;

the flow control slots 11421 gradually decrease along the direction of movement of sliding block 1120;

a liquid inlet 11201 is formed in the sliding block 1120;

the opening of the liquid inlet port 11201 is equal to the maximum opening of the flow control groove 11421.

Wherein the first conveying pipe 115 is arranged in a double-layer staggered arrangement along the first injection assembly 112;

a first liquid guide arc 1151 is arranged on the side of the first conveying pipe 115 on the first layer;

a second liquid guide arc 1152 is arranged on the side part of the first conveying pipe 115 on the second layer;

the upper end of the second liquid guiding arc 1152 is positioned at the liquid outlet end of the first liquid guiding arc 1151;

a second delivery pipe 1153 is provided inside the second spray assembly 113.

The flow divider 1122 divides the inside of the reciprocating frame 1121 into two sections that are equal vertically;

and the inner parts of the upper and lower areas are provided with first conveying pipe fittings 115 which are arranged in a double-layer staggered manner.

As a modification, as shown in fig. 4 and 6, the spraying unit 2 includes:

a medium transfer pipe 201;

and a spray port 202, wherein the spray port 202 for spray cooling the first conveying pipe 115 is connected to the lower end of the medium transferring pipe 201.

It should be added that one end of the medium transfer pipe 201 is communicated with the inside of the medium flow-dividing box 1241.

In operation, as shown in fig. 2, a conveying track of a cooled substance sequentially enters the lower half part of the first liquid distribution frame 111, the second conveying pipe 1153, the second liquid distribution frame 125, the upper half part of the first liquid distribution frame 111, the second liquid inlet pipe 126, the first air-cooled pipe 1271, the third liquid distribution frame 127 and the second air-cooled pipe 1272 from the first liquid inlet pipe 124, and is finally discharged from the liquid outlet pipe 128, a cooling medium is circularly pumped out of the medium collection frame 122 by the liquid conveying pump 123 and then enters the medium distribution box 1241 along the first liquid guide pipe 1231, then the cooling medium in the medium distribution box 1241 enters the medium transfer pipe 201 and is sprayed through the spraying port 202, meanwhile, the cooling medium in the medium distribution box 1241 also enters the liquid guide rod 1141 through the medium inlet pipe 1140, then enters the reciprocating frame 1121 through the liquid inlet 01 and is sprayed through the spraying port 1123 to the first conveying pipe 115, and the sprayed cooling medium falls into the medium collection frame 122 for recycling;

according to the invention, the first conveying pipe 115 and the second conveying pipe 1153 are adopted to divide the cooled substance in the first liquid division frame 111 along the lower part of the spraying unit 2 and the reciprocating frame 1121, and the substance is subjected to reciprocating transportation, and is firstly subjected to water cooling, and then is respectively subjected to air cooling through the first air cooling pipe 1271 and the second air cooling pipe 1272, so that the cooling path is prolonged in a smaller space, and the cooling effect is improved.

It should be noted that, during the process of transporting the substance to be cooled along the first transporting pipe 115 and the second transporting pipe 1153, the medium transferring pipe 201 always keeps spraying the cooling medium in the medium flow dividing box 1241 to the first transporting pipe 115 and the second transporting pipe 1153 through the spraying port 202, as shown in fig. 2 and fig. 6, during the spraying process, the temperature of the substance to be cooled entering the second transporting pipe 1153 from the lower half part of the first liquid dividing frame 111 is much higher than the temperature of the substance to be cooled entering the second liquid dividing frame 125 from the second transporting pipe 1153 after spraying, and meanwhile, the temperature of the substance to be cooled entering the first transporting pipe 115 from the second liquid dividing frame 125 is much higher than the temperature of the substance to be cooled entering the upper half part of the first liquid dividing frame 111 after spraying, because when transporting different types of substance to be cooled or transporting the substance to be cooled at different transporting speeds, the spraying range is relatively dispersed, and it cannot be ensured that the substance to be cooled transported at different speeds or different types of substance to be cooled is transported completely cooled;

therefore, when the invention works, a driving motor at one end of a first reciprocating lead screw 1111 is started, the driving motor rotates through the first reciprocating lead screw 1111, the first reciprocating lead screw 1111 drives a second reciprocating lead screw 1112 to rotate through a first belt 11110, the first reciprocating lead screw 1111 and the second reciprocating lead screw 1112 synchronously rotate to drive a second injection assembly 113 to reciprocate along the direction of a second conveying pipe 1153, meanwhile, the second reciprocating lead screw 1112 drives a third reciprocating lead screw 1113 to rotate through a second belt 11120, the third reciprocating lead screw 1113 drives a fourth reciprocating lead screw 1114 to rotate through a third belt 11130, the third reciprocating lead screw 1113 and the fourth reciprocating lead screw 1114 drive the first injection assembly 112 to reciprocate along the direction of the first conveying pipe 115, the invention describes the first conveying pipe 115 in detail by using the first injection assembly 112, wherein the injection principle of the second injection assembly 113 on the second conveying pipe 1153 is the same as the injection principle of the first injection assembly 112 on the first conveying pipe 115, and is not described herein;

as shown in fig. 9-11, during the process that the third reciprocating screw 1113 and the fourth reciprocating screw 1114 drive the reciprocating frame 1121 to move along the direction of the first delivery pipe 115, the reciprocating frame 1121 drives the sliding block 1120 to move along the interior of the liquid guiding rod 1141 and at the lower end of the baffle 1142, so that the cooling medium in the liquid guiding rod 1141 flows into the interior of the flow guiding hole 11211 through the flow controlling slot 11421 at the position where the liquid inlet port 11201 is in butt joint with the flow controlling slot 11421, and the cooling medium in the liquid guiding rod 1141 is sealed by the liquid sealing plate 11202 at the position where the liquid inlet port 11201 is not in butt joint with the flow controlling slot 11421, when the liquid inlet port 11201 moves from the end with the smaller opening of the flow controlling slot 11421 to the end with the larger opening of the flow controlling slot 11421, the first delivery pipe 115 correspondingly changes from the low temperature state about to enter the inner upper portion of the first liquid separating frame 111 to the high temperature state about to enter the first delivery pipe 115 by the second liquid separating frame 125, the opening along the moving direction of the baffle 1142 is gradually increased, so that the more cooling medium enters the flow guide hole 11211 from the liquid guide rod 1141 in unit time, the faster the speed of the cooling medium sprayed by the nozzle 1123 is, so as to cool the first conveying pipe 115 with gradually increased temperature, when the third reciprocating lead screw 1113 and the fourth reciprocating lead screw 1114 drive the reciprocating frame 1121 to move in opposite directions, the liquid inlet 11201 moves along the direction in which the opening of the flow control groove 11421 is gradually reduced, so that the cooling medium sprayed by the nozzle 1123 is gradually slowed down, thereby achieving the effects of automatically controlling the spraying speed of the cooling medium according to the real-time temperature of the cooled substance, rapidly cooling the conveyed substance on the premise of ensuring the minimum consumption of the medium in unit time, having high cooling efficiency, saving energy and protecting environment;

as shown in fig. 7 and 10, when the nozzles 1123 spray, the middle inside the reciprocating frame 1121 is divided into two equal sections by the flow divider 1122, and the first conveying pipe fittings 115 are arranged in a double-layer staggered manner, so that when a plurality of groups of nozzles 1123 spray a plurality of groups of first conveying pipe fittings 115 along the inside of the reciprocating frame 1121 and the upper and lower ends of the flow divider 1122, the cooling effect can be further improved without a dead angle in all directions;

in addition, as shown in fig. 7, during the spraying process of the nozzle 1123 on the upper inner wall of the reciprocating frame 1121 or the lower end of the flow divider 1122, the sprayed cooling medium slides downwards along the first liquid guiding arc 1151 and adheres to the first conveying pipe 115, then slides down to the second liquid guiding arc 1152 and adheres to another first conveying pipe 115 arranged in a staggered manner again, and finally falls into the medium collecting frame 122 for collection, so that the sprayed medium falls down along the liquid guiding arc in a transition manner, the cooling medium can be in surface contact with a pipeline for conveying a substance, the contact area between the cooling medium and the substance to be cooled is increased, and the effect of more uniform spraying is ensured.

Example two

As shown in fig. 12 to 13, in which the same or corresponding components as those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, only the points of difference from the first embodiment will be described below for the sake of convenience. The second embodiment is different from the first embodiment in that:

the cooling assistance assembly 12 further comprises:

a third dispensing frame 127, wherein the third dispensing frame 127 is connected to the side of the bracket 121 opposite to the infusion pump 123;

a second air cooling pipe 1272 is connected to the upper part of the side part of the third liquid distribution frame 127;

a first air cooling pipe 1271 is connected to the lower part of the side part of the third liquid distribution frame 127;

the outer sides of the first air-cooling pipe 1271 and the second air-cooling pipe 1272 are both provided with cooling fins 1273.

Additionally, an air cooling unit 3 is arranged at the upper part of the cooling assembly unit 1;

the air-cooling unit 3 includes several sets of fans 301.

It should be noted that, during operation, the fan 301 is started, the fan 301 continuously exhausts the damp heat in the bracket 121, and the first air-cooled tube 1271 and the second air-cooled tube 1272 are both sleeved with the heat dissipation fins 1273, so that the heat of the sprayed cooled substance can be continuously transferred to the outside of the heat dissipation fins 1273 when passing through the inside of the first air-cooled tube 1271 and the second air-cooled tube 1272, the heat dissipation area is increased, and meanwhile, the heat on the surface of the heat dissipation fins 1273 is rapidly taken out under the action of the fan 301, thereby further improving the cooling effect.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A container formula is wet compound cooling apparatus futilely which characterized in that includes:

a cooling assembly unit;

the spraying unit is used for primarily cooling the substance and is arranged in the middle inside the cooling assembly unit;

the cooling assembly unit comprises a quick cooling component;

the quick cooling assembly comprises:

a first spray assembly;

the second spraying assembly is used for being matched with the first spraying assembly to cool the cooled substance and is arranged at one end opposite to the first spraying assembly;

the medium control mechanism is used for controlling the injection speed of the cooling medium and is arranged at the upper part of the first injection assembly and the lower part of the second injection assembly; and

the first conveying pipe fitting is used for conveying a cooled substance and is arranged in the first spraying assembly;

the cooled material is conveyed along the inside of the first conveying pipe fitting, the spraying unit sprays cooling medium to the first conveying pipe fitting, and meanwhile, the first spraying assembly and the second spraying assembly swing back and forth along the first conveying pipe fitting and spray cooling work is carried out along the material conveying direction under the action of the spraying speed controlled by the medium control mechanism.

2. The container type dry-wet composite cooling device according to claim 1,

the cooling assembly unit further includes:

a cooling aid assembly;

the cooling aid assembly includes:

a support;

the medium collecting frame is arranged at the bottom in the bracket;

and the infusion pump is used for sending the cooling medium in the medium collection frame into the spraying unit and is arranged on the side part of the medium collection frame.

3. The container type dry-wet composite cooling device according to claim 2,

the quick cooling assembly further comprises:

the first liquid separation frame is connected to the side part of the bracket;

the side part of the first liquid separation frame is connected with a first reciprocating screw rod and a second reciprocating screw rod in a rotating mode near the lower part, and the first reciprocating screw rod and the second reciprocating screw rod are used for driving the second injection assembly to reciprocate;

and the side part of the first liquid distribution frame is connected with a third reciprocating lead screw and a fourth reciprocating lead screw which are used for driving the first injection assembly to reciprocate in a rotating way.

4. The container type dry-wet composite cooling device according to claim 1,

the first jetting assembly includes:

a slider;

the reciprocating frame is connected to the lower end of the sliding block;

a flow guide hole for transmitting a cooling medium is formed in the reciprocating frame;

the middle inside the reciprocating frame is connected with a flow dividing piece;

the upper end and the lower end of the flow dividing piece and the inner wall of the reciprocating frame are both provided with a nozzle;

the spout runs through to reciprocal frame and reposition of redundant personnel outside by water conservancy diversion downthehole portion.

5. The container type dry-wet composite cooling device according to claim 4,

the medium control mechanism includes:

a liquid guide rod;

the baffle plate is connected with the inner wall of the liquid guide rod;

the sliding block is inserted in the liquid guide rod in a sliding mode and is located at the lower end of the baffle;

two sides of the sliding block along the sliding direction of the liquid guide rod are connected with liquid sealing plates;

the liquid sealing plate is in sealing contact with the baffle plate;

and two sides inside the liquid guide rod are connected with limiting blocks used for limiting the sliding block.

6. The container type dry-wet composite cooling device according to claim 5,

a flow control groove is formed in the baffle;

the flow control groove is gradually reduced along the moving direction of the sliding block;

a liquid inlet is formed in the sliding block;

the opening size of the liquid inlet is equal to the maximum opening of the flow control groove.

7. The container type dry-wet composite cooling device according to claim 6,

the first conveying pipe fittings are arranged in a double-layer staggered arrangement along the first spraying assembly;

a first liquid guide arc is arranged on the side part of the first conveying pipe fitting of the first layer;

a second liquid guide arc is arranged on the side part of the first conveying pipe fitting on the second layer;

the upper end of the second liquid guide arc is positioned at the liquid outlet end of the first liquid guide arc.

8. The container type dry-wet composite cooling device according to claim 7,

the flow dividing piece divides the interior of the reciprocating frame into two equal sections from top to bottom;

and the inner parts of the upper and lower areas are provided with first conveying pipe fittings which are arranged in a double-layer staggered manner.

9. The container type dry-wet composite cooling device according to claim 1,

the spray unit includes:

a medium transfer pipe;

and the spraying port is used for spraying and cooling the first conveying pipe fitting and is connected to the lower end of the medium transfer pipe.

10. The container type dry-wet composite cooling device according to claim 2,

the cooling assistance assembly further comprises:

the third liquid distribution frame is connected to one side, opposite to the infusion pump, of the support;

a second air cooling pipe is connected to the side part of the third liquid distribution frame;

a first air cooling pipe is connected to the lower side of the side part of the third liquid distribution frame;

and radiating fins are sleeved on the outer sides of the first air cooling pipe and the second air cooling pipe.

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