CN216811881U - Engine with heat dissipation cooling mechanism - Google Patents

Abstract

The application provides an engine with a heat dissipation and cooling mechanism, which belongs to the technical field of engines. The engine with a heat dissipation and cooling mechanism includes an engine body and a heat dissipation and cooling assembly. The heat dissipation and cooling assembly includes a water-cooled cooling member and an air-cooled cooling cover, the water-cooled cooling member is attached to the outer wall of the engine body casing, and the air-cooled cooling cover is connected to the water-cooled cooling The air-cooled heat dissipation cover and the water-cooled cooling element form an air extraction cavity, and a mounting piece is detachably connected to the bottom of the air-cooled heat dissipation cover. The combination of the water-cooled cooling parts and the mounting parts can conduct more comprehensive and effective water-cooling heat dissipation to the engine body, and the use of the air-cooled heat-dissipating cover parts with the water-cooled cooling parts and the mounting parts can accelerate the heat dissipation of the engine body, and the use of air cooling The combination of the type heat dissipation cover and the air extraction cavity can reduce the circulation of air around the engine body and reduce the warm-up time of the engine body.

Description

Engine with heat dissipation cooling mechanism

Technical Field

The application relates to the field of engines, in particular to an engine with a heat dissipation and cooling mechanism.

Background

An Engine (Engine) is a machine capable of converting other forms of energy into mechanical energy, including, for example, internal combustion engines (reciprocating piston engines), external combustion engines (stirling engines, steam engines, etc.), jet engines, and electric motors, among others.

The engine heat production influences its life in the use, therefore need adopt heat dissipation cooling mechanism to fall the heat treatment to the engine in the function, the engine heat dissipation cooling mechanism that refers to correlation technique adopts the water-cooling circulation mode to fall the heat treatment to the engine usually, be about to install the heat-conducting plate in the sender outer lane, set up the cooling channel cooling in the heat-conducting plate, the setting can reduce the effect of bringing the cooling for the engine like this, but advance and dispel the heat at the less area in engine outer lane, can not be more complete or the cooling to the engine of wider area, the cooling effect is unsatisfactory, the circulation of air around the engine still can not be reduced to the while when the sky is cold, reduce the time that the engine need preheat, and then can not promote the practicality of engine heat dissipation cooling mechanism.

How to invent an engine with a heat dissipation and temperature reduction mechanism to improve the problems becomes a problem to be urgently solved by the technical personnel in the field.

SUMMERY OF THE UTILITY MODEL

In order to compensate for the above insufficiency, the application provides an engine with heat dissipation cooling mechanism, aims at improving the problem that the engine heat dissipation cooling mechanism radiating effect among the correlation technique is relatively poor and can not preheat.

The embodiment of the application provides an engine with heat dissipation cooling mechanism, including engine body and heat dissipation cooling subassembly.

The heat dissipation and cooling assembly comprises a water-cooled cooling piece and an air-cooled cooling cover piece, wherein the water-cooled cooling piece is attached to the outer wall of the shell of the engine body, the air-cooled cooling cover piece is connected to the outside of the water-cooled cooling piece and is connected with the air-cooled cooling cover piece, and the water-cooled cooling piece forms an air draft cavity, the bottom of the air-cooled cooling cover piece is detachably connected with an installation piece, the installation piece is arranged at the bottom of the engine body and is fixedly connected with an external bearing platform.

In the implementation process, the engine body can be more comprehensively and effectively radiated in a circulating water cooling mode by utilizing the matching arrangement of the water-cooled cooling piece and the mounting piece; utilize air-cooled heat exchanger spare can cooperate water-cooled cooling spare and installed part to further realize the forced heat dissipation to engine body, radiating effect preferred and radiating efficiency are higher, and utilize the cooperation setting of air-cooled heat exchanger spare and convulsions cavity can also reduce the circulation of engine body surrounding air, and then reduce engine body preheating time, be convenient for with the heat dissipation cooling subassembly quick with the engine body dismouting with the help of the installed part, be favorable to the maintenance and the reuse of heat dissipation cooling subassembly, the practicality is higher.

In a specific embodiment, the water-cooled cooling part comprises a heat-conducting plate I, a main water inlet channel and a water inlet sub-channel, wherein a water diversion pipeline communicated with the main water inlet channel is connected to the heat-conducting plate I, the outer end of the water diversion pipeline is communicated with a cold water tank I, and a gate valve is installed on the water diversion pipeline.

In a specific implementation scheme, main inlet channel sets up in top in the heat-conducting plate I, it is provided with four at least to advance moisture passageway, all it all sets up to advance moisture passageway I is inside, and all it evenly communicates in to advance moisture passageway main inlet channel.

In the above-mentioned realization in-process, the heat that utilizes heat-conducting plate I among the prior art can absorb the engine body and give off, open the gate valve of installation on air exhauster and the leading water pipeline, open the gate valve after the cold liquid in the cold water tank I under the action of gravity through leading water pipeline downflow to main water inlet channel, be shunted to each branch passageway of intaking through main water inlet channel again, utilize the cooperation of branch passageway of intaking and main water inlet channel to carry out quick water-cooling with other each faces except that the engine body detach the bottom surface.

In a specific implementation scheme, a refrigeration sheet body I is arranged on the outer wall of the cold water tank I, a silicone adhesive layer I is coated on the heat absorption surface of the refrigeration sheet body I, and the silicone adhesive layer I is adhered to the outer wall of the cold water tank I.

In the above-mentioned realization process, scribble I endothermic one side of refrigeration piece body with silicone grease glue film I, be favorable to increasing the endothermic refrigeration effect of refrigeration piece body I, and then indirectly promote water-cooled cooling piece result of use.

In a specific embodiment, the outer wall of the heat-conducting plate I is also equidistantly connected with metal radiating fins.

In the implementation process, the heat of the heat conducting plate I can be dissipated by utilizing the metal radiating fins.

In a specific embodiment, air-cooled radiator-hood spare includes the dustcoat body and main tuber pipe and follows the tuber pipe, the dustcoat body is connected to I outer wall of heat-conducting plate, main tuber pipe fixed connection to the dustcoat body, install the air exhauster on the dustcoat body, the direction orientation of blowing of air exhauster main tuber pipe tip.

In a specific implementation scheme, the number of the secondary air pipes is at least four, each secondary air pipe is communicated with the main air pipe, air suction holes are formed in the side walls of the secondary air pipes at equal intervals, and the blowing directions of all the air suction holes face the air suction cavity.

In the above-mentioned realization process, utilize the air exhauster to take out the heat in with the convulsions cavity to from tuber pipe and main tuber pipe in proper order through all induced drafts holes to finally discharge to heat dissipation cooling subassembly outside, it is more extensive effective to set up the convulsions area like this, is favorable to further realizing the forced heat dissipation to the engine body, the radiating effect preferred.

In a specific implementation scheme, the outer cover body is provided with heat dissipation holes communicated with the air draft cavity in a penetrating mode, and the outer wall of the outer cover body is further provided with baffles movably plugged in the heat dissipation holes.

In the implementation process, the knob is installed on the outer wall of the outer cover body, the through hole communicated with the knob is formed in the baffle, the knob is unscrewed to plug the baffle at the heat dissipation hole, the knob is screwed down to press the baffle, the air draft cavity can be plugged, the air draft cavity is not circulated any more, and the engine body is convenient to preheat.

In a specific embodiment, the installed part includes heat-conducting plate II and the even board that sets up in pairs, two even equal pull is connected with T shape pole, two on the board all be connected with the spring on the T shape pole, two the spring other end still all with correspond even the board is connected, the dustcoat body both sides all seted up with corresponding the jack of T shape pole looks adaptation.

In the above-mentioned implementation process, draw two T shape poles outward and cover the outer cover body outside at engine body, and make the jack that corresponds on T shape pole and the outer cover body aim at, the jack that the T shape pole inserted to correspond is pegged graft, utilizes the tightening force of spring can increase the stability that T shape pole was pegged graft, and the convenient cooling subassembly temperature that will dispel the heat is installed in the engine body outside fast like this, and need not damage engine body external structure.

In a specific embodiment, an L-shaped channel with an included angle being obtuse angle is arranged on the heat conducting plate II, one end part of each L-shaped channel is communicated with a return pipeline, the tail ends of all the return pipelines are communicated with a main pipeline, a cold water tank II is arranged at the bottom of the heat conducting plate II, a main pipeline is communicated with the top of the cold water tank II, a silicone adhesive layer II is adhered to the outer wall of the cold water tank II, the cold water tank II is connected with a refrigerating sheet body II through a silicone adhesive layer II, the bottom of the cold water tank II is communicated with a drain pipe, a circulating pump is arranged on the drain pipe, the water discharge pipe is communicated with the top of the cold water tank I, round holes corresponding to the water inlet sub-channels are equidistantly arranged on the heat conduction plate II, waterproof rubber rings are fixedly adhered to the other end of the L-shaped channel and all the round holes, the bottom end of the water inlet channel is communicated with a connecting pipe, and the connecting pipe is hermetically inserted with the inner ring of the waterproof rubber ring.

In the above-mentioned realization in-process, the dustcoat body moves down the linking pipe of in-process inlet subchannel bottom intercommunication and can tightly insert to waterproof rubber circle inner circle, reduce the probability that inlet subchannel and L shape passageway linking position leaked, increase the stability that water-cooled cooling spare used, scribble silicon grease glue film II in the endothermic one side of refrigeration piece body II, be favorable to increasing the endothermic refrigeration effect of refrigeration piece body II, and then indirectly promote water-cooled cooling spare result of use, start the circulating pump and can make the liquid stream in cold water storage cistern II reuse to cold water storage cistern I, be favorable to the saving and utilizing of resource.

Drawings

In order to more clearly explain the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that for those skilled in the art, other related drawings can be obtained from these drawings without inventive effort.

FIG. 1 is a schematic structural diagram of an engine with a heat dissipation and cooling mechanism according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of a heat dissipation and cooling assembly according to an embodiment of the present disclosure;

FIG. 3 is a schematic structural view of a water-cooled cooling element according to an embodiment of the present disclosure;

FIG. 4 is a schematic structural view of an air-cooled heat sink according to an embodiment of the present disclosure;

fig. 5 is a schematic structural view of a cross-sectional positional relationship between the outer cover and the baffle as well as the heat dissipation holes according to the embodiment of the present disclosure;

FIG. 6 is a schematic view of a mount configuration provided by an embodiment of the present application;

FIG. 7 is a schematic structural diagram illustrating a cross-sectional position relationship between a heat-conducting plate II and an L-shaped channel according to an embodiment of the present invention;

fig. 8 is a schematic structural diagram of an external top-view position relationship between the heat conducting plate ii and the return pipe according to the embodiment of the present application.

In the figure: 10-an engine block; 20-a heat dissipation and cooling component; 210-a water-cooled cooling element; 211-thermally conductive plate i; 212-main water intake channel; 213-water inlet branch channel; 214-a penstock; 215-cold water tank I; 220-air-cooled heat sink; 221-an outer cover body; 222-main air pipe; 223-secondary air pipe; 224-an exhaust fan; 225-air draft holes; 230-air draft cavity; 240-a mount; 241-heat conducting plate II; 242-connecting plate; 243-T shaped rod; 244-a spring; 245-L-shaped channel; 246-return line; 247-cold water tank ii; 248-a circulation pump; 250-heat dissipation holes; 260-baffle.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

To make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without making creative efforts shall fall within the protection scope of the present application.

Thus, the following detailed description of the embodiments of the present application, as presented in the figures, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. All other embodiments obtained by a person of ordinary skill in the art without any inventive work based on the embodiments in the present application are within the scope of protection of the present application.

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 application, 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 are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and thus should not be considered limiting.

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 application, "a plurality" means two or more unless specifically limited otherwise.

In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and encompass, for example, both fixed and removable connections or integral parts thereof; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as the case may be.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact of the first and second features, or may comprise contact of the first and second features not directly but through another feature in between. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

Referring to fig. 1-8, the present application provides an engine with a heat sink mechanism, which includes an engine body 10 and a heat sink assembly 20.

The heat dissipation and cooling assembly 20 can be quickly mounted and dismounted with the engine body 10 without the help of external tools, so that the use convenience of the heat dissipation and cooling assembly 20 is increased, the heat dissipation and cooling assembly 20 is convenient to dismount and reuse, and the practicability is high; the heat dissipation and cooling assembly 20 mainly comprises a water-cooled cooling element 210, an air-cooled heat dissipation cover element 220 and a mounting element 240, wherein an air draft cavity 230 is formed between the water-cooled cooling element 210 and the air-cooled heat dissipation cover element 220, and the engine body 10 can be more comprehensively and effectively dissipated heat in a circulating water cooling mode by utilizing the matching arrangement of the water-cooled cooling element 210 and the mounting element 240; utilize air-cooled heat exchanger 220 can cooperate water-cooled cooling piece 210 and installed part 240 to further realize the forced heat dissipation to engine body 10, the radiating effect preferred and radiating efficiency are higher, and utilize the cooperation setting of air-cooled heat exchanger 220 and convulsions cavity 230 can also reduce the circulation of engine body 10 surrounding air, and then reduce engine body 10 preheating time.

Referring to fig. 1 and 2, the heat sink assembly 20 includes a water-cooled heat sink 210 and an air-cooled heat sink 220, the water-cooled heat sink 210 is attached to the outer wall of the housing of the engine body 10, the air-cooled heat sink 220 is connected to the outside of the water-cooled heat sink 210, the connected air-cooled heat sink 220 and the water-cooled heat sink 210 form an air-extracting cavity 230, the bottom of the air-cooled heat sink 220 is detachably connected with a mounting member 240, the mounting member 240 is disposed at the bottom of the engine body 10, and the mounting member 240 is fixedly connected to an external supporting platform.

Referring to fig. 1, 2 and 3, the water-cooled cooling element 210 includes a heat conducting plate i 211, a main water inlet channel 212 and water inlet sub-channels 213, a water conduit 214 connected to the main water inlet channel 212 is connected to the heat conducting plate i 211, a cold water tank i 215 is connected to an outer end of the water conduit 214, a gate valve is installed on the water conduit 214, the main water inlet channel 212 is opened at a top portion of the heat conducting plate i 211, at least four water inlet sub-channels 213 are provided, all the water inlet sub-channels 213 are opened inside the heat conducting plate i 211, and all the water inlet sub-channels 213 are uniformly connected to the main water inlet channel 212, wherein, when the heat conducting plate i 211 in the prior art is used to absorb heat emitted from the engine body 10, the gate valves installed on the air exhauster 224 and the water conduit 214 are opened, cold water in the cold water tank i 215 flows down to the main water inlet channel 212 through the water conduit 214 under the action of gravity, and is then divided to the water inlet sub-channels 213 through the main water inlet channel 212, the mating of the water inlet sub passage 213 and the main water inlet passage 212 enables rapid water cooling of the engine body 10 on all surfaces except the bottom surface.

When this application specifically sets up, I215 outer walls of cold water storage cistern are equipped with refrigeration piece body I, I endothermic one side of refrigeration piece body scribbles silicone grease glue film I, silicone grease glue film I glues with I215 outer walls of cold water storage cistern, wherein, scribble I endothermic one side in refrigeration piece body with silicone grease glue film I, silicone grease glue film I itself has the stickness, directly during the use glue in I215 outer walls of cold water storage cistern can, be favorable to increasing the heat absorption refrigeration effect of refrigeration piece body I, and then indirectly promote water-cooled cooling piece 210 result of use. The I211 outer wall of heat-conducting plate still the equidistance is connected with the metal fin, and wherein, the metal fin sets up with I211 integrated into one piece of heat-conducting plate, utilizes the metal fin can give off the heat of I211 of heat-conducting plate.

Referring to fig. 1, 2, 3, 4, and 5, the air-cooled heat dissipation cover 220 includes an outer cover 221, a main duct 222, and a secondary duct 223, the outer cover 221 is connected to the outer wall of the heat conduction plate i 211, the main duct 222 is fixedly connected to the outer cover 221, an exhaust fan 224 is installed on the outer cover 221, the blowing direction of the exhaust fan 224 faces one end of the main duct 222, specifically, an installation groove communicated with one end of the main duct 222 is formed in the outer cover 221, the outer wall of the exhaust fan 224 and the inner wall of the installation groove are sealed by a rubber ring in the prior art, and the exhaust fan 224 and the outer cover 221 are fixed by screws. Be provided with four at least from tuber pipe 223, every all communicates with main tuber pipe 222 from tuber pipe 223, and every runs through from tuber pipe 223 lateral wall equal equidistance and has seted up convulsions hole 225, all convulsions hole 225's the direction of blowing all towards convulsions cavity 230, wherein, utilize air exhauster 224 to take out the heat in the convulsions cavity 230 to follow tuber pipe 223 and main tuber pipe 222 through all convulsions holes 225 in proper order, and finally discharge to heat dissipation cooling assembly 20 outsidely, it is more extensive effective to set up the convulsions area like this, be favorable to further realizing the forced heat dissipation to engine body 10, the radiating effect preferred. Run through on the outer cover 221 and set up the louvre 250 with convulsions cavity 230 intercommunication, the baffle 260 of activity shutoff in louvre 250 is still installed to the outer wall of outer cover 221, and wherein, the knob is installed to outer cover 221 outer wall, sets up the through-hole that link up with the knob on the baffle 260, unscrews the knob and closes baffle 260 in louvre 250 and screw down the knob again and push down baffle 260, just can be with convulsions cavity 230 shutoff, makes it no longer circulate, makes things convenient for engine body 10 to preheat.

Referring to fig. 1, 3, 6, 7 and 8, the mounting member 240 includes a heat conducting plate ii 241 and coupling plates 242 arranged in pairs, the two coupling plates 242 are connected with T-shaped rods 243 in a drawing manner, and specifically, the coupling plates 242 are provided with through holes adapted to the T-shaped rods 243, so as to facilitate the drawing of the T-shaped rods 243. All the welding has spring 244 on two T shape poles 243, two spring 244 other ends still all weld with the even board 242 that corresponds, the jack with the T shape pole 243 looks adaptation that corresponds is all seted up to the dustcoat 221 both sides, wherein, draw two T shape poles 243 outward and cover the dustcoat 221 outside engine body 10, and make the jack that corresponds on T shape pole 243 and the dustcoat 221 aim at, the jack grafting that corresponds is inserted to T shape pole 243, the stability that utilizes the tightening force of spring 244 can increase the grafting of T shape pole 243, convenient quick with heat dissipation cooling module 20 temperature installation in the engine body 10 outside like this, and need not damage engine body 10 exterior structure.

When this application specifically sets up, set up the L shape passageway 245 that the contained angle is obtuse angle shape on heat-conducting plate II 241, L shape passageway 245 one end all communicates there is backflow pipeline 246, all backflow pipeline 246 end all communicates there is total pipeline, cold water storage cistern II 247 is installed to heat-conducting plate II 241 bottom, total pipeline end communicates in cold water storage cistern II 247 top, the water that flows out in backflow pipeline 246 flows back to cold water storage cistern II 247 inside through total pipeline again and utilizes, cold water storage cistern II 247 outer wall bonding nature silicone grease glue film II, wherein, silicone grease glue film II itself has the stickness, during the use directly glue can in cold water storage cistern II 247 outer wall. The cold water tank II 247 is connected with the refrigerating sheet body II through a silicone adhesive layer II, the bottom of the cold water tank II 247 is communicated with a drain pipe, a circulating pump 248 is installed on the drain pipe, the drain pipe is communicated with the top of the cold water tank I215, round holes corresponding to the water inlet sub-channel 213 are equidistantly formed in the heat conducting plate II 241, a waterproof rubber ring is fixedly adhered to the other end of the L-shaped channel 245 and all round holes, the bottom end of the water inlet sub-channel 213 is communicated with a linking pipe, and the linking pipe is in sealed insertion connection with an inner ring of the waterproof rubber ring, wherein the linking pipe communicated with the bottom end of the water inlet sub-channel 213 is tightly inserted into the inner ring of the waterproof rubber ring in the downward moving process of the outer cover body 221, the probability of water leakage at the linking part of the water inlet sub-channel 213 and the L-shaped channel 245 is reduced, the use stability of the water-cooled cooling piece 210 is improved, the silicone adhesive layer II is coated on the heat-absorbing surface of the refrigerating sheet body II, and the heat-absorbing refrigeration effect of the refrigerating sheet body II is improved, and then indirectly promote water-cooled cooling 210 result of use, start circulating pump 248 and can make the liquid in II 247 of cold water tank flow to and recycle in I215 of cold water tank, be favorable to the using as economic as resources.

The working principle of the engine with the heat dissipation and cooling mechanism is as follows: when the engine body cooling device is used, the two T-shaped rods 243 are pulled outwards, the outer cover body 221 covers the outside of the engine body 10, the T-shaped rods 243 are aligned with the corresponding insertion holes in the outer cover body 221, the T-shaped rods 243 are inserted into the corresponding insertion holes for insertion, the insertion stability of the T-shaped rods 243 can be improved by the aid of the tightening force of the springs 244, the connecting pipes communicated with the bottom ends of the water inlet sub-channels 213 are tightly inserted into the inner rings of the waterproof rubber rings in the downward moving process of the outer cover body 221, so that the heat dissipation and cooling component 20 can be conveniently and quickly installed on the outer side of the engine body 10 without damaging the external structure of the engine body 10, when the engine body 10 needs to be cooled, heat dissipated by the engine body 10 can be absorbed by the aid of the heat conducting plate I211 in the prior art, the gate valves installed on the exhaust fan 224 and the water diversion pipeline 214 are opened, cold water in the cold water tank I215 flows downwards to the main water inlet channel 212 through the water diversion pipeline 214 under the action of gravity after the gate valves are opened, then the water is distributed to each water inlet sub-channel 213 through the main water inlet channel 212, the water inlet sub-channels 213 and the main water inlet channel 212 are matched to rapidly cool other surfaces of the engine body 10 except the bottom surface, heat absorbed by the heat conducting plate I211 is rapidly taken away, each water inlet sub-channel 213 is communicated with the L-shaped channel 245 with an obtuse angle through the connecting pipe, so that liquid in each water inlet sub-channel 213 can be rapidly circulated into the L-shaped channel 245, the liquid in the L-shaped channel 245 flows to the backflow pipeline 246 by means of gravity and finally flows into the cold water tank II 247, the heat absorbed by the heat conducting plate II 241 can be rapidly taken away, the heat dissipation and temperature reduction treatment of the whole area of the engine body 10 is facilitated, the liquid in the cold water tank II 247 can flow into the cold water tank I215 for reutilization by starting the circulating pump 248, and the resource saving and utilization are facilitated, when the heat of the engine body 10 needs to be stored in the cold day, the gate valve can be closed, water is not left in the water inlet branch channel 213, the main water inlet channel 212 and the L-shaped channel 245, so that the heat storage of the engine body 10 is not affected, when the water cooling is performed, the heat in the air draft cavity 230 is sequentially pumped to the auxiliary air pipe 223 and the main air pipe 222 through all the air draft holes 225 by the air draft fan 224, and is finally discharged to the outside of the heat dissipation and cooling assembly 20, so that the forced heat dissipation of the engine body 10 can be further realized, the heat dissipation effect is better, when the heat of the engine body 10 needs to be stored in the cold day, the air draft fan 224 is closed, the heat dissipation holes 250 are blocked by the baffle 260, so that the air in the air draft cavity 230 can not circulate any more, and the preheating time of the engine body 10 is shortened.

It should be noted that the specific model specifications of the baffle 260 exhaust fan 224, the spring 244, the circulating pump 248, the refrigerating sheet body i and the refrigerating sheet body ii need to be determined by type selection according to the actual specification of the device, and the specific type selection calculation method adopts the prior art in the field, so detailed description is omitted.

The power supply and the principle of the suction fan 224, the circulation pump 248 and the cooling plate bodies i and ii will be clear to the skilled person and will not be described in detail here.

The above embodiments are merely examples of the present application and are not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application. 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.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (10)

1. An engine with a heat dissipation and cooling mechanism is characterized by comprising

An engine body (10);

heat dissipation cooling subassembly (20), heat dissipation cooling subassembly (20) are including water-cooled cooling piece (210) and air-cooled heat exchanger spare (220), water-cooled cooling piece (210) laminate in engine body (10) casing outer wall, air-cooled heat exchanger spare (220) are connected to water-cooled cooling piece (210) are outside, after the connection air-cooled heat exchanger spare (220) with water-cooled cooling piece (210) form convulsions cavity (230), detachable connection has installed part (240) in air-cooled heat exchanger spare (220) bottom, installed part (240) set up in engine body (10) bottom, just installed part (240) and external load-bearing platform fixed connection.

2. The engine with the heat dissipation and temperature reduction mechanism is characterized in that the water-cooled temperature reduction part (210) comprises a heat conduction plate I (211), a main water inlet channel (212) and a water inlet sub-channel (213), a water guide pipeline (214) communicated with the main water inlet channel (212) is connected to the heat conduction plate I (211), the outer end of the water guide pipeline (214) is communicated with a cold water tank I (215), and a gate valve is mounted on the water guide pipeline (214).

3. The engine with the heat dissipation and cooling mechanism as claimed in claim 2, wherein the main water inlet channel (212) is arranged at the top of the heat conducting plate I (211), the number of the water inlet sub-channels (213) is at least four, all the water inlet sub-channels (213) are arranged inside the heat conducting plate I (211), and all the water inlet sub-channels (213) are uniformly communicated with the main water inlet channel (212).

4. The engine with the heat dissipation and cooling mechanism is characterized in that a refrigerating sheet body I is arranged on the outer wall of the cold water tank I (215), a silicone adhesive layer I is coated on the heat absorption surface of the refrigerating sheet body I, and the silicone adhesive layer I is adhered to the outer wall of the cold water tank I (215).

5. The engine with the heat dissipation and cooling mechanism is characterized in that metal cooling fins are further equidistantly connected to the outer wall of the heat conduction plate I (211).

6. The engine with the heat dissipation and temperature reduction mechanism according to claim 5, wherein the air-cooled heat dissipation cover member (220) comprises an outer cover body (221), a main air pipe (222) and a secondary air pipe (223), the outer cover body (221) is connected to the outer wall of the heat conduction plate I (211), the main air pipe (222) is fixedly connected to the outer cover body (221), an exhaust fan (224) is installed on the outer cover body (221), and the blowing direction of the exhaust fan (224) faces one end of the main air pipe (222).

7. The engine with the heat dissipation and cooling mechanism is characterized in that at least four secondary air pipes (223) are arranged, each secondary air pipe (223) is communicated with the main air pipe (222), each secondary air pipe (223) is provided with an air suction hole (225) at the side wall thereof at equal intervals, and the blowing directions of all the air suction holes (225) face to the air suction cavity (230).

8. The engine with the heat dissipation and cooling mechanism according to claim 7, wherein the outer cover body (221) is provided with heat dissipation holes (250) communicated with the air draft cavity (230) in a penetrating manner, and baffles (260) movably plugged in the heat dissipation holes (250) are further installed on the outer wall of the outer cover body (221).

9. The engine with the heat dissipation and temperature reduction mechanism according to claim 8, wherein the mounting member (240) includes a heat conduction plate II (241) and coupling plates (242) arranged in pairs, two coupling plates (242) are connected with T-shaped rods (243) in a drawing manner, two T-shaped rods (243) are connected with springs (244), the other ends of the springs (244) are connected with the corresponding coupling plates (242), and two sides of the outer cover body (221) are provided with insertion holes matched with the corresponding T-shaped rods (243).

10. The engine with the heat dissipation and cooling mechanism according to claim 9, wherein an L-shaped channel (245) with an obtuse angle is formed in the heat conducting plate ii (241), one end of the L-shaped channel (245) is communicated with a return pipe (246), the tail ends of all the return pipes (246) are communicated with a main pipe, a cold water tank ii (247) is installed at the bottom of the heat conducting plate ii (241), the main pipe is communicated with the top of the cold water tank ii (247), a silicone adhesive layer ii is adhered to the outer wall of the cold water tank ii (247), the cold water tank ii (247) is connected with a cooling sheet body ii through the silicone adhesive layer ii, a drain pipe is communicated with the bottom of the cold water tank ii (247), a circulating pump (248) is installed on the drain pipe, the drain pipe is communicated with the top of the cold water tank i (215), and circular holes corresponding to the water inlet branch channels (213) are equidistantly formed in the heat conducting plate ii (241), waterproof rubber rings are fixedly attached to the other end of the L-shaped channel (245) and all the round holes, the bottom end of the water inlet sub-channel (213) is communicated with connecting pipes, and the connecting pipes are in sealed insertion connection with inner rings of the waterproof rubber rings.

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