CN104515227B - Dehumidification device - Google Patents

Abstract

Dehumidification device of the invention includes；Body shell, blower, heat pump assembly and heat exchanger.Body shell has air entry and blow-off outlet.Air entry is set to the periphery wall top of body shell.Heat pump assembly includes compressor, radiator, bulge and heat dump.Radiator, bulge and heat dump are successively set on the downstream of compressor on the direction that the refrigerant of heat pump assembly flows.Radiator is opposite with heat dump.Heat exchanger is provided between radiator and heat dump.Heat dump is made of the 1st region and the 2nd region, and the 2nd region is located at the position of side farther downstream than the 1st region on the direction of refrigerant flowing.Moreover, the 2nd region projects between air entry and heat exchanger.

Description

Dehumidification device

Technical field

It the present invention relates to the use of the dehumidification device that refrigeration cycle carries out cooling and dehumidifying.

Background technique

As being for example mounted with heat disclosed in Japanese Unexamined Patent Publication 2005-214533 bulletin known to existing dehumidification device The dehumidification device of crosspoint.The structure of this existing dehumidification device is following manner.

Compressor, radiator (condenser), bulge (throttling are sequentially connected by refrigerant piping in dehumidification device main body Device), heat dump (evaporator) and form refrigeration cycle.Moreover, the air for becoming dehumidifying object, which is cooled, to be removed in heat dump It is wet.The heat exchange department of straight AC type is configured with into the wind path of radiator from heat dump.

In said structure, enter heat exchange department from the air that inflow entrance flows into, and by after heat dump cooling and dehumidifying Air carry out heat exchange and be pre-chilled, from outflux be discharged.Then, so that the flowing of air is changed 270 ° using wind path, pass through The cooled dehumidifying of heat dump.Later, the air after cooling and dehumidifying is again introduced into heat exchange department from the inflow entrance of heat exchange department, by from The air heating that inflow entrance flows into, is discharged from outflux, is heated again in radiator, is sent to dehumidification device by air supplying part Outside.

Summary of the invention

Generally in the dehumidification device with refrigeration cycle, refrigerant is compressed within the compressor, so being flowed into compressor Refrigerant need sufficiently gasification.Therefore, it is necessary to refrigerants sufficiently to gasify in the heat dump being flowed into before compressor.

In heat dump, the refrigerant of liquid and the refrigerant of gas are mixed.Therefore, in existing dehumidification device In, in order to make refrigerant sufficiently gasify in heat dump, need to help the dehumidifying to the refrigerant downstream side of heat dump not Region become larger.

Therefore, the problem of in existing dehumidification device, there are heat dumps to become larger, and interferes the miniaturization of dehumidification device.

Then, the purpose of the present invention is to provide a kind of maintenance wet-out property and further small-sized dehumidification devices.

Therefore, dehumidification device of the invention includes body shell, blower, heat pump assembly and heat exchanger.Here, blower, heat Pump installation and heat exchanger are arranged in body shell.Body shell has air entry and blow-off outlet.Air entry is set to body shell Periphery wall top.Moreover, blower sucks air from blow-off outlet blow out air from air entry.Heat pump assembly includes compressor, heat dissipation Device, bulge and heat dump.Radiator, bulge and heat dump are set gradually on the direction that the refrigerant of heat pump assembly flows In the downstream of compressor.Radiator is opposite with heat dump.Heat exchanger is provided between radiator and heat dump.Heat dump by 1st region and the 2nd region are constituted, and the 2nd region is located at side farther downstream than the 1st region on the direction of refrigerant flowing Position.Moreover, the 2nd region projects between air entry and heat exchanger.

The dehumidification device utilizes the 2nd region heating for being drawn into the air in body shell for heat dump from air entry, is inhaling The gasification for the refrigerant for promoting liquids and gases to be mixed in hot device.Therefore, even if not making to inhale for the gasification of refrigerant Hot device becomes larger, and the gasification of refrigerant also can be sufficiently carried out in heat dump, can obtain and maintain wet-out property and small-sized remove Wet device.

Detailed description of the invention

Fig. 1 is the perspective view of the dehumidification device of embodiments of the present invention.

Fig. 2 is that the summary sectional view watched from the direction B is truncated using plane A for the dehumidification device of Fig. 1.

Fig. 3 is the figure for illustrating the heat exchanger of dehumidification device of embodiments of the present invention.

Fig. 4 is the figure for illustrating the heat dump of the dehumidification device.

Specific embodiment

Hereinafter, the embodiments of the present invention will be described with reference to the drawings.

(embodiment)

Fig. 1 is the perspective view of the dehumidification device of embodiments of the present invention.As shown in Figure 1, the body shell 1 of dehumidification device 10 For box shape, there is air entry 2 and blow-off outlet 3.The periphery wall top 1a of body shell 1 is arranged in air entry 2, and blow-off outlet 3 is arranged In position identical as air entry 2 or higher than air entry 2.

Here, the periphery wall top 1a of body shell 1 is located in the state of being provided with dehumidification device 10 than in body shell 1 The high position of the heart.In addition, being provided with the tank 4 for the water that storage is generated by dehumidifying in the lower part of dehumidification device 10.

Fig. 2 is that the sectional view watched from the direction B is truncated using plane A for the dehumidification device of Fig. 1.As shown in Fig. 2, dehumidifying dress Setting 10 includes body shell 1, blower 8, heat pump assembly 30 and heat exchanger (sensible heat exchanger) 11.Wind is provided in body shell 1 Machine 8, heat pump assembly 30 and heat exchanger 11.

Heat pump assembly 30 include compressor (Compressor) 6, refrigerant flowing direction 21 compressor 6 downstream Radiator (condenser) 5, bulge (capillary) 12 and the heat dump (evaporator) 13 set gradually.Heat pump assembly 30 by they It is connected with refrigerant piping 17, forms refrigeration cycle.Moreover, the air for becoming dehumidifying object, which is cooled, to be removed in heat dump 13 It is wet.

Blower 8 includes: the housing section 8a of swirl shape；It is fixed on the motor section 8b of housing section 8a；It is driven with by motor section 8b The blade part 8c of dynamic rotation.Blower 8 sucks air from air entry 2, from 3 blow out air of blow-off outlet.

Housing section 8a has suction inlet 9a and outlet 9b.Suction inlet 9a and heat dump 13, heat exchanger 11 and radiator 5 Relatively.That is, heat dump 13, heat exchanger 11, radiator 5 and suction inlet 9a configuration are in a straight line.

In addition, being provided with tank 4, drip tray 7 in body shell 1.The lower section of heat dump 13 is arranged in drip tray 7, receives logical The air for crossing heat dump 13 is dehumidified and the water that generates, and water is sent to tank 4.Radiator 5 and heat dump 13 are opposite, in radiator 5 Heat exchanger 11 is provided between heat dump 13.

Fig. 3 is the figure for illustrating the heat exchanger of dehumidification device of embodiments of the present invention.As shown in figure 3, heat exchanger 11 be, for example, the sensible heat exchanger of straight AC type.Heat exchanger 11 will be by the 1st heat transfer plate 11a of the formation such as resin or metal and 2 heat transfer plate 11b are alternately stacked to form.

Heat exchanger 11 has the 1st heat exchange wind path 11c and the 2nd heat exchange wind path 11d for mutually carrying out heat exchange.This hair In bright embodiment, the 1st heat exchange wind path 11c is the wind path in vertical direction, and the 2nd heat exchange wind path 11d is horizontal direction On wind path.

As shown in the arrow C of Fig. 2, the of the upper surface of the air inflow heat exchanger 11 sucked from air entry 2 by blower 8 The inflow entrance of 1 heat exchange wind path 11c.Then, it is flowed into the air of the inflow entrance of the 1st heat exchange wind path 11c, and is absorbed heat Air after 13 cooling and dehumidifying of device carries out heat exchange and is pre-chilled, the 1st heat exchange wind path 11c from the lower surface of heat exchanger 11 Outflux discharge.Moreover, the air being discharged from the outflux of the 1st heat exchange wind path 11c passes through the cooled dehumidifying of heat dump 13.

By the air after 13 cooling and dehumidifying of heat dump, heat exchanger is again introduced into from the inflow entrance of the 2nd heat exchange wind path 11d 11, the air heating flowed into from the inflow entrance of the 1st heat exchange wind path 11c.Then, from the outflux of the 2nd heat exchange wind path 11d The air of discharge is further heated in radiator 5, is passed out to outside dehumidification device 10 by blower 8.

Fig. 4 is the figure for illustrating the heat dump of dehumidification device of embodiments of the present invention.As shown in figure 4, heat dump 13 by 1st region 13a and the 2nd region 13b is constituted.On the direction 21 of refrigerant flowing, the 2nd region 13b is located at than the 1st region 13a The position of side farther downstream.1st region 13a is the moisture condensation region of heat dump 13.In the 1st region 13a, removed when air is cooled Water droplet 22 is generated when wet, water droplet 22 is sent to tank 4 via drip tray 7 shown in Fig. 2.

In addition, the 2nd region 13b is located at the position in the downstream side on the direction 21 for more leaning on refrigerant to flow than the 1st region 13a Set, thus be difficult to because condense region the 1st region 13a due to condense.In other words, the 2nd region 13b is compared with the 1st region 13a to removing It is wet not help.

The dehumidification device 10 of present embodiment is characterized in that the 2nd region 13b of heat dump 13 as shown in Figure 2 is arranged to It projects in the wind path between air entry 2 and heat exchanger 11.

As a result, heated the 2nd region 13b of heat dump 13 using the air being drawn into from air entry 2 in body shell 1, Promote the gasification of refrigerant, in the 2nd region 13b to ensure sufficient refrigerant superheat degree.Therefore, even if for refrigerant Gasify and heat dump 13 is made to become larger, the gasification of refrigerant also can be sufficiently carried out in heat dump 13.Then, sufficiently after gasification Refrigerant is flowed into the compressor 6 positioned at downstream, continues refrigeration cycle by compression herein.In other words, it is sucked from air entry 2 A part of air is pre-chilled before reaching radiator 5 by the 2nd region 13b, so can be improved the cooling effect of radiator 5 Rate can further decrease consumption electric power.

In addition, as shown in Fig. 2, the 2nd region 13b of heat dump 13 is preferably placed at the air entry upper end 2a of air entry 2 and inhales Height between the 2b of port lower end.As a result, it is possible to which the 2nd region 13b effectively heat, so can further promote the 2nd area The gasification of refrigerant in the 13b of domain.

In addition, the miniaturization of the dehumidification device 10 for Fig. 1, preferably the 2nd region for the Fig. 4 not helped to dehumidifying The 2nd zonal ventilation section 13c of 13b is smaller.It is therefore preferable that the 2nd zonal ventilation section 13c of the 2nd region 13b is than the 1st region The 1st zonal ventilation section 13d of 13a is small.Specifically, if the 2nd zonal ventilation section 13c is the 1st zonal ventilation section 13d 5% or more 25% hereinafter, then dehumidification device 10 becomes more small-sized.

In addition, as shown in Fig. 2, dehumidification device 10 is included from air entry 2 via the 1st heat exchange wind path 11c, heat dump 13 The 1st region 13a, the 2nd heat exchange wind path 11d and radiator 5 to blow-off outlet 3 dehumidifying wind path 14；With from air entry 2 via dissipate Hot device 5 to blow-off outlet 3 bypass wind path 15.Therefore, it is divided by blower 8 from the air that air entry 2 is drawn into body shell 1 logical The air and the air by bypassing wind path 15 for crossing dehumidifying wind path 14.

But in the heat exchanger upper end of the radiator upper end 5a of 5 upper end of the radiator of Fig. 2 and 11 upper end of heat exchanger The height of portion 11e is identical, does not bypass wind path 15 in the case where the wind path 14 that only dehumidifies, can also obtain above-mentioned the application The effect of invention.The following are the examples in the presence of bypass wind path 15 not necessarily.

As shown in the arrow D of Fig. 2, a part of the air in body shell 1 is drawn into from air entry 2 by blower 8, from air-breathing Mouth 2 flows through not via the 1st region 13a of heat exchanger 11 and heat dump 13 and via the bypass wind path of radiator 5 to blow-off outlet 3 15.In addition, the position than heat exchanger upper end 11e high is arranged in radiator upper end 5a.Moreover, being handed over from the heat of radiator 5 The radiator top 5c of the position of parallel operation upper end 11e to radiator upper end 5a forms a part of bypass wind path 15.

In the dehumidification device 10 of Fig. 2 of present embodiment, the air for being flowed into radiator 5 increases, so the system of radiator 5 The heat exchange amount of cryogen and the air sucked increases, and radiator 5 is further cooled.

In addition, the air sucked as shown in Figure 2 is divided by the air for the wind path 14 that dehumidifies and by bypass wind path 15 air.It is sent to the air quantity of heat exchanger 11 and heat dump 13 as a result, dehumidifying effect is maintained as most preferably, and by It send to the air quantity increase of radiator 5.In addition, having passed through dehumidifying wind path 14 and having bypassed the air of wind path 15, after being mixed by blower 8 It is blown out from blow-off outlet 3.

In addition, wind path 15 is bypassed not via heat exchanger 11 etc., so ventilation resistance is small compared with the wind path 14 that dehumidifies, it can The output for reducing blower 8 increases.Especially, only the radiator top 5c in radiator 5 forms a part for bypassing wind path 15, institute Become smaller with bypassing the ventilation resistance of wind path 15, the cooling efficiency of radiator 5 carries out well.As described above, dehumidification device 10 Dehumidifying effect can reduce consumption electric power without reducing.

In addition, as shown in Fig. 2, radiator upper end 5a can be located under the air entry upper end 2a and air entry of air entry 2 Hold the height between 2b.The air sucked from air entry 2, advances in the top of heat exchanger 11 along horizontal direction, reaches and makees For the radiator top 5c of a part of bypass wind path 15.The air can be from air entry 2 to radiator top 5c direction of travel Radiator top 5c is hardly reached to bending, so the ventilation resistance of bypass wind path 15 further becomes smaller.

In addition, the radiator lower end from the position of the heat exchanger upper end 11e of the radiator 5 of Fig. 2 to 5 lower end of radiator The bottom radiator 5d of portion 5b forms a part of dehumidifying wind path 14.Moreover, from the radiator upper end 5a of radiator top 5c It, can be than from the radiator lower end of bottom radiator 5d to the radiator upper length 5e of the position of heat exchanger upper end 11e The bottom radiator length 5f of portion 5b to the position of heat exchanger upper end 11e is short.

It is small to bypass the ventilation resistance compared with the wind path 14 that dehumidifies of wind path 15, so even if radiator top 5c compares bottom radiator 5d, the balance of the cooling of radiator 5 for being also able to maintain the dehumidifying carried out by dehumidifying wind path 14 and being carried out by bypass wind path 15, energy The decline of 10 dehumidifying effects of dehumidification device is enough prevented, and further decreases consumption electric power.

In addition, can be more than the stream of the air by dehumidifying wind path 14 by the flow of the air of the bypass wind path 15 of Fig. 2 Amount.The radiator 5 that as a result, it is possible to balance the dehumidifying for carrying out being carried out well by dehumidifying wind path 14 and carried out by bypass wind path 15 Cooling, the decline of 10 dehumidifying effects of dehumidification device can be prevented, and further decrease consumption electric power.

As shown in Fig. 2, radiator top 5c is connect with the refrigerant piping 17 from compressor 6, bottom radiator 5d with Refrigerant piping 17 from bulge 12 connects.Refrigerant in compressor 6 as high temperature is flowed into radiator top 5c. Therefore, for radiator top 5c compared with bottom radiator 5d, temperature is higher.In addition, wind path 15 is bypassed compared with the wind path 14 that dehumidifies, Ventilation resistance is smaller.

Therefore, the air more than air that portion 5c flowing ratio passes through dehumidifying wind path 14 on a heat sink, so can balance good The cooling of the dehumidifying carried out by dehumidifying wind path 14 and the radiator 5 carried out by bypass wind path 15 is carried out well.

In addition, as shown in Fig. 2, the blow-off outlet 3 of body shell 1 can be set identical as air entry 2 or higher than air entry 2 Position.Since blow-off outlet 3 is arranged in higher position, so effectively blown out from the air after the dehumidifying of dehumidification device 10, Dehumidification efficiency is got higher.

In addition, as shown in Fig. 2, the 2nd region 13b of heat dump 13 can be set in the position lower than radiator upper end 5a It sets.As a result, proceeding to the top of heat dump 13 and heat exchanger 11 from the air that air entry 2 sucks, reaches and form bypass wind The radiator top 5c of a part on road 15.The air is not rolled over continually from air entry 2 to radiator top 5c direction of travel It is curved, so the ventilation resistance of bypass wind path 15 further becomes smaller.

In addition, as shown in Fig. 2, can also with the suction inlet 9a of the housing section 8a of blower 8 and heat dump 13, heat exchanger 11 and Radiator 5 is opposite, bypasses and is connected near wind path 15 and a part of the peripheral part of radiator 5.

Furthermore it is possible to which the air quantity sent out to radiator top 5c shown in Fig. 2 is bigger closer to radiator upper end 5a. On a heat sink in portion 5c, radiator upper end 5a is temperature highest, so more closer to radiator upper end 5a air output When, the heat exchange amount of radiator 5 becomes larger.As a result, radiator 5 is cooled efficiently, the consumption electric power of dehumidification device 10 is dropped It is low.

Specifically, radiator upper end 5a is located at the height between air entry upper end 2a and air entry lower end 2b, moreover, Radiator upper end 5a is located at than air entry upper end 2a closer to the position of air entry lower end 2b.Moreover, on a heat sink It can have spatial portion 16 between end 5a and body shell 1.Heat dump 13, heat are configured in order from 2 side of air entry in body shell 1 Exchanger 11, radiator 5 and blower 8.A part of spatial portion 16 is by the outer of the housing section 8a of radiator upper end 5a and blower 8 Surface surrounds.It is easy to enter radiator top 5c from following 2 surface currents as a result,.

The face opposite with air entry 2 that the 1st face in above-mentioned 2 faces is radiator top 5c.2nd face is radiator upper end Portion 5a.It is considered that air is flowed into radiator upper end 5a via bypass wind path 15 and spatial portion 16.Alternatively, it is also possible to recognize Are as follows: a part for reaching the air of spatial portion 16 collides the outer surface of the housing section 8a opposite with air entry 2, changes downwards Direction flows into radiator upper end 5a.

That is, air is flowed into radiator top 5c from 2 faces, it is possible to think to be flowed into bypass wind path from air entry 2 15 air flows into more closer to radiator upper end 5a.Like this, on a heat sink in portion 5c, closer to radiator upper end 5a air inflow in portion's is more, so the cooling for carrying out radiator top 5c well can be balanced.

Claims (10)

1. a kind of dehumidification device, it is characterised in that:

Including body shell, blower, heat pump assembly and heat exchanger,

The blower, the heat pump assembly and the heat exchanger are arranged in the body shell,

The body shell has air entry and blow-off outlet,

The periphery wall top of the body shell is arranged in the air entry,

The blower sucks air from the air entry and blows out the air from the blow-off outlet,

The heat pump assembly includes compressor, radiator, bulge and heat dump,

The radiator, the bulge and the heat dump are successively set on the direction that the refrigerant of the heat pump assembly flows It sets in the downstream of the compressor,

The radiator is opposite with the heat dump,

The heat exchanger is arranged between the radiator and the heat dump,

The heat dump is made of the 1st region and the 2nd region, and the moisture in the air of sucking is made in the 1st region For moisture condensation to dehumidify, the 2nd region is located at side farther downstream than the 1st region on the direction that the refrigerant flows Position, thus compared with the 1st region to it is described dehumidifying do not work,

Only the 2nd region projects to the air between the air entry and the heat exchanger in the heat dump In flow path.

2. dehumidification device as described in claim 1, it is characterised in that:

2nd region is located at the height between the air entry upper end and air entry lower end of the air entry.

3. dehumidification device as claimed in claim 1 or 2, it is characterised in that:

The 2nd zonal ventilation section in the 2nd region is less than the 1st zonal ventilation section in the 1st region.

4. dehumidification device as claimed in claim 3, it is characterised in that:

The 2nd zonal ventilation section is 5% or more 25% or less the 1st zonal ventilation section.

5. dehumidification device as claimed in claim 2, it is characterised in that:

The heat exchanger has the 1st heat exchange wind path and the 2nd heat exchange wind path for mutually carrying out heat exchange,

The dehumidification device includes

From the air entry via the 1st heat exchange wind path, the 1st region, the 2nd heat exchange wind path and the heat dissipation Device to the blow-off outlet dehumidifying wind path；With

From the air entry via the bypass wind path of the radiator to the blow-off outlet,

By the blower from the air entry be drawn into the air in the body shell be separated into the dehumidifying wind path and The bypass wind path is blown after having passed through the air mixing of the dehumidifying wind path and the bypass wind path from the blow-off outlet Out,

The radiator upper end of the radiator upper end is arranged in higher than the heat exchanger upper end of the heat exchanger upper end Position,

The radiator from the heat exchanger upper end to the radiator top of the radiator upper end, form the side A part of ventilation path.

6. dehumidification device as claimed in claim 5, it is characterised in that:

Height of the radiator upper-end part of driving between the air entry upper end and the air entry lower end, in the radiator There is spatial portion between upper end and the body shell.

7. dehumidification device as claimed in claim 5, it is characterised in that:

The radiator from the heat exchanger upper end to the radiator of the radiator lower end of the radiator lower end under Portion forms a part of the dehumidifying wind path,

The radiator upper length from the radiator upper end to the heat exchanger upper end on the radiator top, than The bottom radiator length from the radiator lower end to the heat exchanger upper end of the bottom radiator is short.

8. dehumidification device as claimed in claim 5, it is characterised in that:

Height identical as the air entry or the position higher than the air entry is arranged in the blow-off outlet.

9. dehumidification device as claimed in claim 5, it is characterised in that:

The position lower than the radiator upper end is arranged in 2nd region.

10. dehumidification device as claimed in claim 5, it is characterised in that:

The blower includes: the housing section of swirl shape；It is fixed on the motor section of the housing section；It is driven with by the motor section The blade part of rotation,

The housing section has suction inlet and outlet,

The suction inlet is opposite with the heat dump, the heat exchanger and the radiator.