CN203405022U - Air conditioning system for enclosed space - Google Patents

Abstract

The utility model provides an air conditioning system for an enclosed space. The air conditioning system for the enclosed space comprises an evaporator, a condenser and a compressor, and further comprises a first container, a first pipeline and a second container, wherein the top of the first container is open, the first container is arranged at the bottom of the evaporator, the output end of the first container is communicated with the first pipeline, the output end of the first pipeline is communicated with the second container, the second container is arranged outside the enclosed space, the compressor and the condenser are communicated through a second pipeline, and part of the second pipeline or the whole second pipeline is arranged inside the second container. The air conditioning system for the enclosed space has the advantages that the structure is simple, refrigeration performance is good, the energy efficiency ratio is high, the range of the operating temperature is wide, and the service life of the air conditioning system for the enclosed space is prolonged.

Description

The air handling system of enclosure space

Technical field

The utility model relates to air conditioning, particularly the air handling system of enclosure space.

Background technology

At present, the working method of compressed air conditioner is: first with compressor, refrigerant is compressed into high pressure, high-temperature gas, through copper pipe, enter in condenser again, the refrigerant of high pressure, high temperature is cooled to the liquid of high pressure low temperature, after after throttling arrangement current limliting, enter evaporimeter, in evaporimeter, pressure diminishes, refrigerant is evaporated to the gas of low temperature by absorbing the heat of evaporimeter surrounding air, finally again enter compressor, thereby form circulation.This mode of operation has some shortcomings, as:

When air-conditioning freezes under hot environment, refrigerant dispels the heat in condenser, and when ambient temperature is very high, radiating effect will reduce greatly, and refrigeration decreases, and has correspondingly reduced the energy loss-rate of air-conditioning and the service life of compressor.

Therefore, how cross improve air-conditioning operating temperature range, to improve Energy Efficiency Ratio, increase the service life be that the technical barrier solving is badly in need of in this area.

Utility model content

In order to solve the deficiency in above-mentioned prior art scheme, the utility model provide a kind of simple in structure, strengthen the air handling system that cooling-down effect, Energy Efficiency Ratio are high, improve the enclosure space of operating temperature range, system long service life.

The purpose of this utility model is achieved through the following technical solutions:

An air handling system for enclosure space, described air handling system comprises evaporimeter, condenser, compressor; Described air handling system further comprises:

The first container, described the first container upper opening, is arranged on the bottom of described evaporimeter, and output is communicated with the first pipeline;

The first pipeline, the output of described the first pipeline is communicated with second container;

Second container, described second container is arranged on the outside of described enclosure space, is communicated with the partly or entirely inside in described second container of the second pipe of described compressor and condenser.

According to above-mentioned air handling system, alternatively, described second container is provided with delivery outlet, and the position of described delivery outlet is higher than the second pipe in second container;

The 3rd pipeline, the input of described the 3rd pipeline is communicated with described delivery outlet, and output is communicated with extraneous.

According to above-mentioned air handling system, alternatively, described enclosure space is formed in room or rack.

According to above-mentioned air handling system, preferably, described rack is any in communication, analysis meter, electric power, switch board.

According to above-mentioned air handling system, preferably, the output of described the first pipeline is communicated with the water inlet of described second container bottom or reaches the bottom in described second container.Aqueous water enters the bottom of described second container from described the first pipeline, along with the rising of temperature, upwards flow, last (with evaporate seethe with excitement or from discharge outlet) discharge second container.

According to above-mentioned air handling system, alternatively, the second pipe cover in described second container has heat-shrink tube.

According to above-mentioned air handling system, preferably, the installation site of described the first container is higher than described second container.

According to above-mentioned air handling system, alternatively, described air handling system further comprises:

Conveying device, described conveying device is arranged on described the first pipeline, and input is communicated with described the first container, and output is communicated with described second container.Alternatively, intermittent work during described conveying device.

According to above-mentioned air handling system, alternatively, described second container is arranged on the periphery of described second pipe, surrounds at least in part described second pipe.On the sidewall of described second container, delivery outlet is set.

According to above-mentioned air handling system, alternatively, described second container tilts or vertically arranges.

Compared with prior art, the beneficial effect the utlity model has is:

Collect the condensed water that the moisture in enclosure space produces on evaporimeter, when the gas that is compressed into HTHP by compressor when refrigerant is carried to condenser, utilize the condensed water of collecting first once cooling to refrigerant, cooling to refrigerant by condenser again, thereby change over the pattern air-cooled, water-cooled combines by conventional (only) air-cooled pattern, cooling-down effect, the refrigeration performance of refrigerant have been improved, and the service life, Energy Efficiency Ratio, the increase operating temperature range that improve compressor, effectively utilized (temperature the is lower) condensed water wasting in prior art simultaneously.Condensed water enters second container from bottom, from the mode of top discharge, has further improved the cooling-down effect of refrigerant.

Accompanying drawing explanation

With reference to accompanying drawing, disclosure of the present utility model will be easier to understand.Those skilled in the art hold intelligible: these accompanying drawings are only for illustrating the technical solution of the utility model, and are not intended to protection domain of the present utility model to be construed as limiting.In figure:

Fig. 1 is the structural representation of air handling system of the present utility model.

The specific embodiment

Fig. 1 and following declarative description optional embodiment of the present utility model with instruction those skilled in the art, how to implement and to reproduce the utility model.In order to instruct technical solutions of the utility model, simplified or omitted some conventional aspects.Those skilled in the art should understand that be derived from the modification of these embodiments or replace will be in scope of the present utility model.Those skilled in the art should understand that following characteristics can combine to form a plurality of modification of the present utility model in every way.Thus, the utility model is not limited to following optional embodiment, and only by claim and their equivalent, is limited.

Embodiment 1:

Fig. 1 has schematically provided the structure diagram of air handling system of the enclosure space of the utility model embodiment, and as shown in Figure 1, described air handling system comprises:

External part, mainly by the second centrifugal blower outside enclosure space, condenser 3, compressor 2, second container 8, pipeline, formed, described pipeline comprises the second pipe that is communicated with described condenser 3 and compressor 2, described second pipe partly or entirely in described second container 8.Second pipe preferably adopts copper pipe, and in order to prevent the aqueous water corrosion copper pipe in second container 8, alternatively, the outside of the second channel in second container 8 cover has heat-shrink tube.

Built-in part, is mainly comprised of the evaporimeter 1 in enclosure space, the first centrifugal blower, the first container 6 and the first pipeline 7, between built-in and external part, by wall or division board 10, is separated.The upper opening of described the first container 6, is arranged on the bottom of evaporimeter 1, for collecting the condensed water of airborne moisture on evaporimeter 1 in enclosure space, and is transported in described second container 8 by described the first pipeline 7.Described the first container 6, the first pipeline 7 can adopt corrosion resistant stainless steel material.

In order to discharge in time the aqueous water in second container, alternatively, described second container is provided with delivery outlet, and the position of described delivery outlet is higher than the second pipe in second container;

The 3rd pipeline, the input of described the 3rd pipeline is communicated with described delivery outlet, and output is communicated with extraneous.

Alternatively, described enclosure space is formed in room or rack.Preferably, described rack is any in communication, analysis meter, electric power, control system cabinet.

In order to make the aqueous water in the first container freely flow into second container, preferably, the installation site of described the first container is higher than described second container.

In order to adapt to second container higher than the occasion of the first container, alternatively, described air handling system further comprises:

Conveying device, described conveying device is arranged on described the first pipeline, and input is communicated with described the first container, and output is communicated with described second container.Described conveying device can adopt suction pump.

In order to improve the cooling-down effect of refrigerant in second pipe, preferably, the output of described the first pipeline is communicated with the water inlet of described second container or reaches the bottom in described second container.Thereby make the water that temperature is lower from bottom, enter second container continuously or discontinuously, after the mediate contact with refrigerant, temperature rises and upwards flows, and finally drains; Also, what drain is all the water that temperature is higher, and what enter is all the water that temperature is lower.In order to improve the cooling-down effect of refrigerant in second pipe, alternatively, described second container is arranged on the periphery of described second pipe, surrounds at least in part described second pipe.

The course of work of above-mentioned air handling system, specifically comprises the following steps:

The heat absorption of refrigerant evaporation in evaporimeter, temperature reduces due to heat radiation to make circulated air in enclosure space, and airborne moisture is liquefied as water droplet on evaporimeter, flows to the first container and collects, and by the first pipeline, be transported to second container and store;

When refrigerant is compressed into HTHP gas by compressor is carried to condenser, first pass through second container inside, utilize first cooling refrigerant of the condensed water collected, then it is cooling to send condenser to.

In order to discharge aqueous water unnecessary in second container, draining threshold value is set, when aqueous water water level is during higher than threshold value, unnecessary aqueous water is discharged by discharge outlet, the 3rd pipeline.

In order further to strengthen the cooling-down effect of refrigerant, preferably, described aqueous water enters the bottom of described second container from described the first pipeline, along with the rising of temperature, upwards flows, and finally discharges second container.

The benefit reaching according to the utility model embodiment 1 is: because air handling system is by (only) air-cooled Mode change pattern that cold-peace water-cooled combines that becomes a common practice, brought many advantages, as, have simple in structure, do not need to increase original paper and driving arrangement, improved the cooling-down effect of refrigerant, the refrigeration performance of system, and the life-span of having improved compressor, and then improved Energy Efficiency Ratio, operating temperature range.Aqueous water enters second container from bottom, from the mode of top discharge, has improved further the cooling-down effect of refrigerant.

Embodiment 2:

Application examples according to the air handling system of embodiment 1 in communication cabinet cooling.

In this application examples, enclosure space is formed in communication cabinet.The first container adopts water leg, is arranged on the bottom of evaporimeter.The bottom of water leg is the second container lower than water leg by the first pipeline communication installation site, and the output of the first pipeline is communicated with the water inlet of described second container bottom, and the first container, the first pipeline and second container all adopt stainless steel material.Side wall upper part at second container is provided with discharge outlet (position height of discharge outlet is drain height threshold value), and position is higher than the second pipe in second container, and the input of the 3rd pipeline is communicated with described discharge outlet, and output is communicated with sewer.Second pipe adopts copper pipe, and the second pipe outside cover in second container has heat-shrink tube, the part of second pipe to be coiled in described second container, has increased the length of second pipe, thereby strengthened the cooling-down effect of refrigerant in the limited space of second container.

In the course of work of above-mentioned air handling system, the aqueous water that temperature is lower enters from the bottom of second container, along with second pipe in the mediate contact of refrigerant, water temperature rises, and upwards flows simultaneously, finally from the discharge outlet on top, discharges, what guaranteed like this to drain is all the aqueous water that temperature is higher, and the lower water of temperature all enters from bottom, constantly replace the water that temperature is higher, improved significantly the cooling-down effect of refrigerant.

Embodiment 3:

Application examples according to the air handling system of embodiment 1 in analysis meter cabinet.

In this application examples, the first container adopts water leg, is arranged on the bottom of evaporimeter.The bottom of water leg is the second container higher than water leg by the first pipeline communication height, and the output of the first pipeline reaches the bottom in described second container, and the first container, the first pipeline and second container all adopt stainless steel material.On the sidewall of second container, be provided with discharge outlet, higher than the second pipe in second container, the input of the 3rd pipeline is communicated with described discharge outlet, and output is communicated with sewer.Second pipe adopts copper pipe, and all, in second container, in second pipe outside, cover has heat-shrink tube.Conveying device adopts suction pump, for the aqueous water of collecting in the first container is pumped in second container.Because system power is low, the speed of the aqueous water that evaporimeter produces is limited, and therefore described suction pump need to intermittently be worked, and has by control circuit or software control, and the intermittent time, power was larger by the power determination of air handling system, and the intermittent time is shorter.

In the course of work of above-mentioned air handling system, aqueous water in second container is constantly accumulated, when surpassing described discharge outlet height, unnecessary aqueous water is discharged, thereby make the lower aqueous water of temperature forming on evaporimeter add to off and on second container interior (also displacing the aqueous water of part after refrigerant heating), maintain the cooling-down effect of refrigerant in second pipe.

Embodiment 4:

Application examples according to the air handling system of embodiment 1 in room.

In this application examples, the first container adopts water leg, is arranged on the bottom of evaporimeter.The bottom of water leg is the water inlet lower than the bottom of the second container of water leg by the first pipeline communication height, second container is arranged on the periphery of part second pipe, partly or entirely surround this part second pipe, the inner side that makes second pipe tube wall is refrigerant, outside is aqueous water, and the first container, the first pipeline and second container all adopt stainless steel material.Second container tilts or vertically arranges, and upper opening is provided with discharge outlet on the top of the sidewall of second container, and the input of the 3rd pipeline is communicated with described discharge outlet, and output is communicated with sewer.

In the course of work of above-mentioned air handling system, the aqueous water that temperature is lower enters from the bottom of second container, along with second pipe in the mediate contact of refrigerant, water temperature rises, and upwards flows simultaneously, finally from the discharge outlet on top, discharge, or drain from upper opening with the form of steam, what guaranteed like this to drain is all the aqueous water that temperature is higher, and the lower water of temperature all enters from bottom, constantly replace temperature higher be water, improved significantly the cooling-down effect of refrigerant.

Above-described embodiment is only exemplarily to have provided the application examples of air handling system in room, communication cabinet, analysis meter cabinet, certainly can also be applied in the racks such as electric power cabinet, switch board.This for a person skilled in the art, embodiment and implementation result can expect.

Claims (10)

1. an air handling system for enclosure space, described air handling system comprises evaporimeter, condenser, compressor; It is characterized in that: described air handling system further comprises:

The first container, described the first container upper opening, is arranged on the bottom of described evaporimeter, and output is communicated with the first pipeline;

The first pipeline, the output of described the first pipeline is communicated with second container;

Second container, described second container is arranged on the outside of described enclosure space, is communicated with the partly or entirely inside in described second container of the second pipe of described compressor and condenser.

2. air handling system according to claim 1, is characterized in that: described second container is provided with delivery outlet, and the position of described delivery outlet is higher than the second pipe in second container;

The 3rd pipeline, the input of described the 3rd pipeline is communicated with described delivery outlet, and output is communicated with extraneous.

3. air handling system according to claim 1, is characterized in that: described enclosure space is formed in room or rack.

4. air handling system according to claim 1, is characterized in that: the output of described the first pipeline is communicated with the water inlet of described second container bottom or reaches the bottom in described second container.

5. air handling system according to claim 1, is characterized in that: the outside cover of the second pipe in described second container has heat-shrink tube.

6. air handling system according to claim 1, is characterized in that: the installation site of described the first container is higher than described second container.

7. air handling system according to claim 1, is characterized in that: described air handling system further comprises:

Conveying device, described conveying device is arranged on described the first pipeline, and input is communicated with described the first container, and output is communicated with described second container.

8. air handling system according to claim 1, is characterized in that: described second container is arranged on the periphery of described second pipe, surrounds at least in part described second pipe.

9. air handling system according to claim 8, is characterized in that: on the sidewall of described second container, delivery outlet is set.

10. air handling system according to claim 8, is characterized in that: described second container tilts or vertically arranges.