CN205066219U - Indirect heating equipment - Google Patents

Abstract

The utility model provides an indirect heating equipment, wherein, indirect heating equipment includes: shell, compressor, evaporimeter, water reservoir section and water conduction sections, water conduction sections will the water that falls down in the indirect heating equipment is introduced water reservoir section, compressor, evaporimeter and water reservoir section set up the inside of shell, just compressor, evaporimeter and water reservoir section are in along the horizontal direction setting indirect heating equipment's bottom. Through with compressor and evaporimeter setting in indirect heating equipment's inside, application space that can be nimble reduces whole refrigerating system's volume, in addition, compressor, evaporimeter and water reservoir section along the horizontal direction setting in indirect heating equipment's bottom, therefore water reservoir section's opening size is less to reduce the evaporation of water, practiced thrift the water resource.

Description

Heat transmission equipment

Technical field

The utility model relates to refrigeration technology field, particularly relates to a kind of heat transmission equipment.

Background technology

Along with generally application and the worsening shortages of the energy of Refrigeration Technique, for the refrigeration of Refrigeration Technique and energy-conservation requirement also more and more higher.Heat transmission equipment is the vitals in refrigeration system, and general heat transmission equipment mainly comprises air cooled condenser, water cooled condenser and evaporative condenser.There is the defects such as operational efficiency is low, system cloud gray model expense is high, bulky in air cooled condenser, water cooled condenser needs configuration cooling tower and cooling water recirculation system, and water consumption is large and need the expense increasing water treatment.Evaporative condenser is a kind of compact heat transmission equipment, and the evaporation of main dependence moisture makes condensation of refrigerant dispel the heat, and operational efficiency is higher, and it has lower energy consumption relative to air cooled condenser and water cooled condenser.

Fig. 1 is the structural representation of existing evaporative condenser.As shown in Figure 1, evaporative condenser 100 comprises: the air inlet 101 of both sides, 102, water storage part 103, water pump 104, water pipe 105, spray portion 106, multiple condenser pipe 107, fan 108, air outlet 109 and dehydrator 110, wherein, outside air passes through the air inlet 101 of suction by both sides of fan 108, 102 inside entering evaporative condenser 100, cold-producing medium from top to bottom enters each condenser pipe 107, water in water storage part 103 is evacuated to spray portion 106 by water pump 104, heat exchange is carried out on the surface by spray portion 106 water being sprayed uniformly condenser pipe 107, and the air entering the inside of evaporative condenser 100 from bottom to top by each condenser pipe, substantially increase heat transfer effect, part sprays the water storage part 103 falling into bottom after the water on condenser pipe is heated, part spray is evaporated to water vapour after the water on condenser pipe is heated, part water vapour condenses into water droplet and falls into water storage part 103 on dehydrator 110, after the cold-producing medium of high-temperature gas enters condenser pipe 107, liquid is become to flow out from bottom through cooling condensation.

In above-mentioned existing evaporative condenser, evaporimeter and compressor are arranged on the outside of evaporative condenser 100, cold water passes in and out evaporimeter by interface, after low temperature liquid cold-producing medium enters evaporimeter, high-temperature low-pressure steam cold-producing medium is exported to compressor by evaporimeter, export high temperature and high pressure steam cold-producing medium in condenser pipe 107 by compressor, in condenser pipe, enter evaporimeter through overcooled cold-producing medium by expansion valve 111, thus form refrigerant loop.

Above it should be noted that, just conveniently to the technical solution of the utility model, clear, complete explanation is carried out to the introduction of technical background, and facilitate the understanding of those skilled in the art to set forth.Only can not think that technique scheme is conventionally known to one of skill in the art because these schemes have carried out setting forth in background technology part of the present utility model.

Utility model content

Inventor of the present utility model finds, in above-mentioned existing equipment, evaporimeter and compressor are arranged on the outside of evaporative condenser, cause the volume of whole refrigeration system comparatively large, and inconvenience is installed, in addition, water storage part covers the bottom of whole heat transmission equipment, its opening size is comparatively large, and greatly, the water capacity is easily evaporated and causes running off for the water in water storage part and the contact area of air.

The utility model embodiment provides a kind of heat transmission equipment, can application space flexibly, reduces the volume of whole refrigeration system, in addition, can reduce evaporation of water in water storage part, saving water resource.

According to the first aspect of the utility model embodiment, a kind of heat transmission equipment is provided, it is characterized in that, described heat transmission equipment comprises: shell, compressor, evaporimeter, water storage part and water guide sector, the water fallen in described heat transmission equipment is introduced described water storage part by described water guide sector, described compressor, evaporimeter and water storage part are arranged on the inside of described shell, and described compressor, evaporimeter and water storage part are arranged on the bottom of described heat transmission equipment in the horizontal direction.

According to the second aspect of the utility model embodiment, wherein, described water storage part has lid.

According to the third aspect of the utility model embodiment, wherein, described water storage part is arranged between described compressor and described evaporimeter.

According to the fourth aspect of the utility model embodiment, wherein, described heat transmission equipment also comprises: condensation part, and described water guide sector has at least one inclined-plane or curved surface, and into described condensation part is also guided the air sucking described heat transmission equipment in described water guide sector.

According to the 5th aspect of the utility model embodiment, wherein, described heat transmission equipment also comprises: the air inlet being arranged on described shell side, the position at least one inclined-plane of described water guide sector or the place, top of curved surface is higher than the position at the place, bottom of described air inlet, and the position at the place, bottom of at least one inclined-plane of described water guide sector or curved surface is lower than the position at the place, top of described air inlet.

According to the 6th aspect of the utility model embodiment, wherein, at least one inclined-plane of described water guide sector or the height of curved surface are greater than the height of described air inlet.

According to the 7th aspect of the utility model embodiment, wherein, the position at least one inclined-plane of described water guide sector or the place, top of curved surface is higher than the position at the place, top of described air inlet.

According to the eighth aspect of the utility model embodiment, wherein, the both sides of described shell respectively arrange an air inlet, and at least one inclined-plane of described water guide sector or curved surface are arranged on the central position of the horizontal direction of the air inlet of both sides.

According to the 9th aspect of the utility model embodiment, wherein, described water guide sector has two symmetrical inclined-planes or curved surface, and described two inclined-planes or curved surface are in its roof intersection.

According to the tenth aspect of the utility model embodiment, wherein, described two curved surfaces are configured to the structure of " people " font.

According to the 11 aspect of the utility model embodiment, wherein, the angle of described inclined-plane and horizontal direction is 30 degree ~ 60 degree.

According to the 12 aspect of the utility model embodiment, wherein, the line of two end points of described curved surface and the angle of horizontal direction are 30 degree ~ 60 degree.

According to the 13 aspect of the utility model embodiment, wherein, described water guide sector also has: extension, and described extension extends in the horizontal direction from the bottom of at least one inclined-plane described or curved surface.

According to the fourteenth aspect of the utility model embodiment, wherein, described water guide sector also has: opening portion, and described opening portion is arranged on the junction of described inclined-plane or curved surface and described extension.

According to the 15 aspect of the utility model embodiment, wherein, described water guide sector also has: aqueduct, and described aqueduct is connected with described opening portion, so that water is introduced described water storage part.

According to the 16 aspect of the utility model embodiment, wherein, described water guide sector also has: gutter, and described gutter is arranged on described inclined-plane or curved surface, and/or is arranged on described extension.

According to the 17 aspect of the utility model embodiment, wherein, described water guide sector also has:

Water retaining wall, described water retaining wall is arranged on the edge of described inclined-plane or curved surface, and/or is arranged on the edge of described extension.

The beneficial effects of the utility model are: by compressor and evaporimeter being arranged on the inside of heat transmission equipment, can application space flexibly, reduce the volume of whole refrigeration system, in addition, compressor, evaporimeter and water storage part are arranged on the bottom of heat transmission equipment in the horizontal direction, therefore the opening size of water storage part is less, thus decreases evaporation of water, has saved water resource.

With reference to explanation hereinafter and accompanying drawing, disclose in detail particular implementation of the present utility model, specifying principle of the present utility model can adopted mode.Should be appreciated that, thus embodiment of the present utility model is not restricted in scope.In the spirit of claims and the scope of clause, embodiment of the present utility model comprises many changes, amendment and is equal to.

The feature described for a kind of embodiment and/or illustrate can use in one or more other embodiment in same or similar mode, combined with the feature in other embodiment, or substitutes the feature in other embodiment.

Should emphasize, term " comprises/comprises " existence referring to feature, one integral piece, step or assembly when using herein, but does not get rid of the existence or additional of one or more further feature, one integral piece, step or assembly.

Accompanying drawing explanation

Included accompanying drawing is used to provide the further understanding to the utility model embodiment, which constituting a part for description, for illustrating embodiment of the present utility model, and coming together to explain principle of the present utility model with text description.Apparently, the accompanying drawing in the following describes is only embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, can also obtain other accompanying drawing according to these accompanying drawings.In the accompanying drawings:

Fig. 1 is the structural representation of existing evaporative condenser;

Fig. 2 is the structural representation of the heat transmission equipment of the utility model embodiment 1;

Fig. 3 is the structural representation of the heat transmission equipment of the utility model embodiment 2;

Fig. 4 is the water storage part of the utility model embodiment 2 and the three-dimensional structure diagram of water guide sector;

Fig. 5 is another three-dimensional structure diagram of the water guide sector of the utility model embodiment 2;

Fig. 6 is the another structural representation of the water guide sector of the utility model embodiment 2;

Fig. 7 is the another structural representation of the water guide sector of the utility model embodiment 2;

Fig. 8 is the schematic diagram utilizing the water guide sector of the utility model embodiment 2 to guide air;

Fig. 9 utilizes the water guide sector of the utility model embodiment 2 to prevent cross-ventilated schematic diagram;

Figure 10 is the three-dimensional structure diagram of the heat transmission equipment 300 of the utility model embodiment 2;

Figure 11 is the outside drawing of the heat transmission equipment 300 of the utility model embodiment 2.

Detailed description of the invention

With reference to accompanying drawing, by description below, aforementioned and further feature of the present utility model will become obvious.In the specification and illustrated in the drawings, specifically disclose particular implementation of the present utility model, which show the some embodiments that wherein can adopt principle of the present utility model, will be appreciated that, the utility model is not limited to described embodiment, on the contrary, the utility model comprises the whole amendments fallen in the scope of claims, modification and equivalent.

Embodiment 1

Fig. 2 is the structural representation of the heat transmission equipment of the utility model embodiment 1.As shown in Figure 2, this heat transmission equipment 200 comprises: shell 201, compressor 202, evaporimeter 203, water storage part 204 and water guide sector 205, wherein,

The water fallen in heat transmission equipment 200 is introduced water storage part 204 by water guide sector 205,

Compressor 202, evaporimeter 203 and water storage part 204 are arranged on the inside of shell 201, and compressor 202, evaporimeter 203 and water storage part 204 are arranged on the bottom of heat transmission equipment 200 in the horizontal direction.

From above-described embodiment, by compressor and evaporimeter being arranged on the inside of heat transmission equipment, can application space flexibly, reduce the volume of whole refrigeration system, in addition, compressor, evaporimeter and water storage part are arranged on the bottom of heat transmission equipment in the horizontal direction, and therefore the opening size of water storage part is less, thus decrease evaporation of water, save water resource.

In the present embodiment, this heat transmission equipment is such as evaporative condenser, also can be the condenser of other types, and the type of the utility model embodiment not heat exchanging equipment limits.The present embodiment is described for evaporative condenser.

In the present embodiment, this heat transmission equipment 200 can also comprise: be arranged on the air inlet 206 and 207 of shell 201 both sides, condensation part 208, fan 209, air outlet 210, water pipe 211, multiple spray portion 212 and dehydrator 213, wherein, compressor 202, evaporimeter 203 are connected by pipeline with condensation part 208, water in water storage part 204 is evacuated in water pipe 211 by water pump (not shown), and is evenly sprayed onto on condensation part 208 by water by spray portion 212.Wherein, water pump can be arranged on the inside of shell 201, in addition, water pump structure, compressor 202, evaporimeter 203 can use existing structure with the syndeton of condensation part 208 and the syndeton of water storage part 204 and water pipe 211, and arrange according to the size of heat transmission equipment and layout.

In the present embodiment, compressor 202, evaporimeter 203 and water storage part 204 are arranged on the bottom of heat transmission equipment 200 in the horizontal direction, and wherein, the relative position of compressor 202, evaporimeter 203 and water storage part 204 can set according to actual needs.

Such as, can water storage part 204 be arranged between compressor 202 and evaporimeter 203, also water storage part 204 can be arranged on the side bottom heat transmission equipment.

In the present embodiment, the shape of water storage part 204 can be arranged according to actual needs, such as, water storage part 204 can be designed to box shape.

In the present embodiment, water storage part 204 can have lid, and wherein, the size of the shape of lid can adapt with the opening of water storage part 204, in addition, lid can also be provided with and introduce water and reserved hole or gap for water guide sector 205.

By arranging lid in water storage part, evaporation of water and pollution in water storage part can be reduced, further saving water resource.

In the present embodiment, the water fallen in heat transmission equipment 200 is introduced water storage part 204 by water guide sector 205, such as, as shown in Figure 2, by water guide sector 205 being set to the flat board tilted, thus the water fallen is introduced water storage part 204.The utility model embodiment is not limited to this kind of structure, as long as the water fallen can be introduced in water storage part 204.

In the present embodiment, shell 201, the air inlet 206 and 207 being arranged on shell both sides, compressor 202, evaporimeter 203, condensation part 208, fan 209, air outlet 210, water pipe 211, spray portion 212 and dehydrator 213 can use existing structure and material, such as, condensation part 208 comprises multiple condenser pipe, fan 209 and air outlet 210 all adopt four, are evenly distributed on the top of heat transmission equipment.

From above-described embodiment, by compressor and evaporimeter being arranged on the inside of heat transmission equipment, can application space flexibly, reduce the volume of whole refrigeration system, in addition, compressor, evaporimeter and water storage part are arranged on the bottom of heat transmission equipment in the horizontal direction, and therefore the opening size of water storage part is less, thus decrease evaporation of water, save water resource.

Embodiment 2

The utility model embodiment provides a kind of heat transmission equipment, and wherein, the water guide sector structure of the heat transmission equipment of embodiment 2 and different in embodiment 1, other structures can be identical with embodiment 1.

Fig. 3 is the structural representation of the heat transmission equipment of the utility model embodiment 2.As shown in Figure 3, heat transmission equipment 300 comprises: shell 301, compressor 302, evaporimeter 303, water storage part 304, water guide sector 305, the air inlet 306 and 307 being arranged on shell 301 both sides, condensation part 308, fan 309, air outlet 310, water pipe 311, spray portion 312 and dehydrator 313, compressor 302, evaporimeter 303 are connected by pipeline with condensation part 308, wherein

Compressor 302, evaporimeter 303 and water storage part 304 are arranged on the inside of shell 301, and compressor 302, evaporimeter 303 and water storage part 304 are arranged on the bottom of heat transmission equipment in the horizontal direction,

The water fallen in heat transmission equipment is introduced water storage part 304 by water guide sector 305, and water guide sector 305 has two inclined-plane 314-1 and 314-2, and water guide sector 305 is also available guides the air sucking heat transmission equipment into condensation part 308 by inclined-plane 314-1 and 314-2.

Like this, by arranging the water guide sector with wind-guiding function, while guiding water, guide the air sucking heat transmission equipment into condensation part, thus the air quantity of the air flowing to condensation part can be made even, improve condensation effect, in addition, the inclined-plane that this water guide sector has or curved surface can prevent air between the air inlet of heat transmission equipment both sides, forming convection current, thus prevent air from being dispelled by the water droplet fallen, and have saved water resource.

In the present embodiment, air inlet 306 and 307 can have identical height and opening size, the position at the place, top of inclined-plane 314-1 and 314-2 of water guide sector 305 is higher than the position at the place, bottom of air inlet, further, the position at the place, bottom of inclined-plane 314-1 and 314-2 of water guide sector 305 is lower than the position at the place, top of air inlet 306 and 307.Like this, can guarantee that the air sucked from air inlet 306 and 307 can blow to inclined-plane 314-1 and 314-2 of water guide sector 305.

Such as, as shown in Figure 3, can by the position of the position at the inclined-plane of water guide sector 305 or place, curved surface top higher than the place, top of air inlet.Like this, can make the air inclined-plane that is more blown to water guide sector 305 that sucks from air inlet 306 and 307 or curved surface, thus improve wind effect further.

In the present embodiment, the top of inclined-plane or curved surface refers to that the end near side, condensation part 308, the bottom of inclined-plane or curved surface refer to the end near water storage part 304 side.

Such as, as shown in Figure 3, inclined-plane 314-1 with the 314-2 position in vertical direction of water guide sector 305 can be arranged on the height roughly the same with 307 positions with air inlet 306.

In the present embodiment, as shown in Figure 3, the height H of inclined-plane 314-1 and 314-2 of water guide sector 305 can be set to the height h being greater than air inlet 306 and 307, like this, the air sucked from air inlet 306 and 307 can be made substantially all to be blown to inclined-plane 314-1 and 314-2 of water guide sector 305, thus to improve wind effect further.

In the present embodiment, as shown in Figure 3, inclined-plane 314-1 and 314-2 of water guide sector 305 can be arranged on the central position of the horizontal direction between air inlet 306 and 307, like this, the air of guiding condensation part into can be made more even, improve wind effect further.

Fig. 4 is the water storage part 304 of the utility model embodiment 2 and the three-dimensional structure diagram of water guide sector 305.As shown in Figure 4, water guide sector 305 has two inclined-plane 314-1 and 314-2, and the water fallen in heat transmission equipment is introduced water storage part 304 by water guide sector 305, and the air sucking this heat transmission equipment is also guided into the condensation part of this heat transmission equipment by water guide sector 305.

In the present embodiment, water guide sector 305 can have inclined-plane, also can have curved surface, and Fig. 4 has inclined-plane for water guide sector and is illustrated.Fig. 5 is another three-dimensional structure diagram of the water guide sector of the utility model embodiment 2, and as shown in Figure 5, water guide sector 305 has two curved surfaces 414-1,414-2, and other structures are identical with Fig. 4, repeat no more herein.

In the present embodiment, water guide sector 305 can have an inclined-plane or curved surface, also can have two or more inclined-plane or curved surface.Such as, if this heat transmission equipment each side has an air inlet, then water guide sector 305 can be set to correspond to each air inlet respectively has an inclined-plane, or respectively has multiple inclined-plane corresponding to each air inlet; If this heat transmission equipment only has an air inlet in side, then water guide sector 305 can be set to there is an inclined-plane, also can be set to that there is multiple inclined-plane.The utility model embodiment does not limit the quantity of inclined-plane or curved surface.

In the present embodiment, this inclined-plane or curved surface can be formed as various shape, as long as the air sucking heat transmission equipment can be guided into the condensation part of this heat transmission equipment.Such as, water guide sector 305 has two symmetrical inclined-planes or curved surface, and these two inclined-planes or curved surface are in its roof intersection, and when water guide sector has two symmetrical curved surfaces, these two curved surfaces can be configured to " people " character form structure.The utility model embodiment does not limit the shape of inclined-plane or curved surface.

What Fig. 4 and Fig. 5 was exemplary give, and water guide sector has two symmetrical inclined-planes or the situation of curved surface.Fig. 6 is the another structural representation of the water guide sector of the utility model embodiment 2, as shown in Figure 6, if heat transmission equipment only has an air inlet in side, then water guide sector 305 only has an inclined-plane 314, other structures are identical with Fig. 4, in addition, the inclined-plane in Fig. 6 also can replace with curved surface, repeats no more herein.

Fig. 7 is the another structural representation of the water guide sector of the utility model embodiment 2, as shown in Figure 7, water guide sector 305 has 4 inclined-planes, corresponding to the air inlet of heat transmission equipment side, respectively have two continuous print inclined-planes, other structures are identical with Fig. 4, in addition, inclined-plane in Fig. 7 also can replace with curved surface, repeats no more herein.

In the present embodiment, can arrange the inclined degree of inclined-plane or curved surface.As shown in Figure 4, the angle α of inclined-plane 314-1 and 314-2 and horizontal direction 30 degree ~ 60 degree can be set to, as shown in Figure 5, the angle β of the line of two of a curved surface end points and horizontal direction 30 degree ~ 60 degree can be set to.

Arranged by the angle of above-mentioned scope, wind effect can be improved further, make the air quantity of the air flowing to condensation part more even, thus further improve condensation effect.

In the present embodiment, water guide sector 305 can also have extension 315, and this extension 315 extends in the horizontal direction from the bottom of at least one inclined-plane or curved surface.As shown in Figure 4, extension 315 stretches out in the horizontal direction from the bottom of two inclined-plane 314-1 and 314-2 respectively, as shown in Figure 5, extension 315 stretches out in the horizontal direction from the bottom of two curved surfaces 414-1,414-2 respectively, as shown in Figure 6, extension 315 stretches out in the horizontal direction from the bottom on inclined-plane 314.

In the present embodiment, extension 315 can with at least one inclined-plane or curved surface one-body molded, also can be set to independent parts with at least one inclined-plane or curved surface, be connected by existing method of attachment.

In the present embodiment, extension guides the air sucking heat transmission equipment into condensation part together with inclined-plane or curved surface, by arranging extension, can guide the air of suction into inclined-plane or curved surface preferably, thus improving wind effect further.

In the present embodiment, the water fallen in heat transmission equipment can be introduced water storage part 304 by water guide sector 305, such as, as shown in Figure 4, an opening 316 can be set in the junction of inclined-plane 314-1 and 314-2 and extension 315, so that the water collected by inclined-plane 314-1 and 314-2 and extension 315 is introduced water storage part 304.

In the present embodiment, the size of opening 316 and position can be arranged according to actual needs, such as, as shown in Figure 4, the length of opening 316 is about 1/2nd of the junction length of inclined-plane 314-1 and 314-2 and extension 315, and the length of opening 316 also can be slightly less than the length of whole junction.The utility model embodiment does not limit the size of opening 316 and position.

In the present embodiment, water guide sector 305 can also comprise aqueduct, and as shown in Figure 4, aqueduct 317 is connected with opening 316, and the water for flowing out from opening 316 is introduced in water storage part 304; Also can not arrange aqueduct, the water that water guide sector 305 is collected directly is flowed in water storage part 304 by opening 316.

In the present embodiment, water guide sector 305 can also be included on inclined-plane 314-1 and 314-2, and/or extension 315 arranges gutter, opening 316 is guided into for by the water of collection, such as, as shown in Figure 4, gutter 318 is set in the centre of inclined-plane 314-1 and 314-2 and extension 315.In addition, also only on inclined-plane 314-1 and 314-2 or only, gutter 318 can be set on extension 315, also gutter can be set.

In the present embodiment, this gutter can be set to extend to whole inclined-plane and extension, also can arrange in subregion.

By arranging aqueduct and gutter, preferably the water that water guide sector is collected can be introduced water storage part, improving diversion effect.

In the present embodiment, water guide sector 305 can also be included on the edge of inclined-plane 314-1 and 314-2, and/or the water retaining wall that the edge of extension 315 is arranged.Such as, as shown in Figure 4, the edge of extension 315 arranges water retaining wall 319.In addition, also water retaining wall can be set on the edge of inclined-plane 314-1 and 314-2, or on the edge of inclined-plane 314-1 and 314-2 or curved surface 414-1,414-2, and the edge of extension 405 all arranges water retaining wall.

In the present embodiment, the height of water retaining wall can set according to actual needs, as long as can prevent the water collected from overflowing.

By arranging water retaining wall, the water that can prevent water guide sector from collecting flows out to outside water storage part, further saving water resource.

Fig. 8 is the schematic diagram utilizing the water guide sector of the utility model embodiment 2 to guide air.As shown in Figure 8, suck the guiding of air by the inclined-plane of water guide sector 305 of heat transmission equipment, uniformly the condensation part 308 flowing to heat transmission equipment from bottom to top.

Fig. 9 utilizes the water guide sector of the utility model embodiment 2 to prevent cross-ventilated schematic diagram.As shown in Figure 9, even if when strong wind weather, due to the stop of inclined-plane 314-1 and 314-2, convection current cannot be formed between air inlet 306 and 307.

Figure 10 is the three-dimensional structure diagram of the heat transmission equipment 300 of the utility model embodiment 2, and Figure 11 is the outside drawing of the heat transmission equipment 300 of the utility model embodiment 2.As shown in Figure 10 and Figure 11, compressor 302, evaporimeter 303 and water storage part 304 bottom being arranged on heat transmission equipment 300 side by side, the water in water storage part 304 is evacuated in water pipe 311 by water pump 320.The symmetrical inclined-plane of two of water guide sector 305 is arranged on the central position of the horizontal direction between air inlet 306 and 307, thus guide the air of suction into condensation part 308 uniformly, and, when strong wind weather, due to the stop on two of water guide sector 305 symmetrical inclined-planes, can prevent from forming convection current between air inlet 306 and 307.

From above-described embodiment, by compressor and evaporimeter being arranged on the inside of heat transmission equipment, can application space flexibly, reduce the volume of whole refrigeration system, in addition, compressor, evaporimeter and water storage part are arranged on the bottom of heat transmission equipment in the horizontal direction, and therefore the opening size of water storage part is less, thus decrease evaporation of water, save water resource.

Further, by arranging the water guide sector with wind-guiding function, while guiding water, guide the air sucking heat transmission equipment into condensation part, thus the air quantity of the air flowing to condensation part can be made even, improve condensation effect, in addition, the inclined-plane that this water guide sector has or curved surface can prevent air between the air inlet of heat transmission equipment both sides, forming convection current, thus prevent air from being dispelled by the water droplet fallen, and have saved water resource.

More than being described the utility model in conjunction with concrete embodiment, but it will be apparent to those skilled in the art that these descriptions are all exemplary, is not the restriction to the utility model protection domain.Those skilled in the art can make various variants and modifications according to spirit of the present utility model and principle to the utility model, and these variants and modifications are also in scope of the present utility model.

Claims (17)

1. a heat transmission equipment, is characterized in that, described heat transmission equipment comprises: shell, compressor, evaporimeter, water storage part and water guide sector,

The water fallen in described heat transmission equipment is introduced described water storage part by described water guide sector,

Described compressor, evaporimeter and water storage part are arranged on the inside of described shell, and described compressor, evaporimeter and water storage part are arranged on the bottom of described heat transmission equipment in the horizontal direction.

2. heat transmission equipment according to claim 1, is characterized in that,

Described water storage part has lid.

3. heat transmission equipment according to claim 1, is characterized in that,

Described water storage part is arranged between described compressor and described evaporimeter.

4. heat transmission equipment according to claim 1, is characterized in that, described heat transmission equipment also comprises: condensation part,

Described water guide sector has at least one inclined-plane or curved surface, and into described condensation part is also guided the air sucking described heat transmission equipment in described water guide sector.

5. heat transmission equipment according to claim 4, is characterized in that, described heat transmission equipment also comprises: the air inlet being arranged on described shell side,

The position at least one inclined-plane of described water guide sector or the place, top of curved surface is higher than the position at the place, bottom of described air inlet, and the position at the place, bottom of at least one inclined-plane of described water guide sector or curved surface is lower than the position at the place, top of described air inlet.

6. heat transmission equipment according to claim 5, is characterized in that,

At least one inclined-plane of described water guide sector or the height of curved surface are greater than the height of described air inlet.

7. heat transmission equipment according to claim 5, is characterized in that,

The position at least one inclined-plane of described water guide sector or the place, top of curved surface is higher than the position at the place, top of described air inlet.

8. heat transmission equipment according to claim 5, is characterized in that,

The both sides of described shell respectively arrange an air inlet, and at least one inclined-plane of described water guide sector or curved surface are arranged on the central position of the horizontal direction of the air inlet of both sides.

9. heat transmission equipment according to claim 4, is characterized in that,

Described water guide sector has two symmetrical inclined-planes or curved surface, and described two inclined-planes or curved surface are in its roof intersection.

10. heat transmission equipment according to claim 9, is characterized in that,

Described two curved surfaces are configured to the structure of " people " font.

11. heat transmission equipments according to claim 4, is characterized in that,

The angle of described inclined-plane and horizontal direction is 30 degree ~ 60 degree.

12. heat transmission equipments according to claim 4, is characterized in that,

The line of two end points of described curved surface and the angle of horizontal direction are 30 degree ~ 60 degree.

13. heat transmission equipments according to claim 4, is characterized in that, described water guide sector also has:

Extension, described extension extends in the horizontal direction from the bottom of at least one inclined-plane described or curved surface.

14. heat transmission equipments according to claim 13, is characterized in that, described water guide sector also has:

Opening portion, described opening portion is arranged on the junction of described inclined-plane or curved surface and described extension.

15. heat transmission equipments according to claim 14, is characterized in that, described water guide sector also has:

Aqueduct, described aqueduct is connected with described opening portion, so that water is introduced described water storage part.

16. heat transmission equipments according to claim 13, is characterized in that, described water guide sector also has:

Gutter, described gutter is arranged on described inclined-plane or curved surface, and/or is arranged on described extension.

17. heat transmission equipments according to claim 13, is characterized in that, described water guide sector also has:

Water retaining wall, described water retaining wall is arranged on the edge of described inclined-plane or curved surface, and/or is arranged on the edge of described extension.