CN203642544U

CN203642544U - Multi-temperature heat exchange system controlled by refrigerant of single compressor

Info

Publication number: CN203642544U
Application number: CN201320712931.5U
Authority: CN
Inventors: 张翔
Original assignee: PHST Corp
Current assignee: PHST Corp
Priority date: 2013-11-12
Filing date: 2013-11-12
Publication date: 2014-06-11
Anticipated expiration: 2023-11-12

Abstract

The utility model discloses a multi-temperature heat exchange system controlled by a refrigerant of a single compressor, wherein the requirement of controlling multiple independent temperatures is met by using a single refrigerating unit. The system comprises a first circulating fluid passage, a second circulating fluid passage, a cooling fluid loop, and a factory affair fluid passage, the first circulating fluid passage comprises a first heat exchanger, a first circulating fluid inlet and a first circulating fluid outlet 112, a first circulating fluid and a cooling fluid conduct heat exchange in the first heat exchanger, the second circulating fluid passage 120 comprises a second heat exchanger, a second circulating fluid inlet and a second circulating fluid outlet, and a second circulating fluid and the cooling fluid conduct heat exchange in the second heat exchanger. The temperature of a controlled object is controlled, the overall energy consumption is lowered, and the production cost is saved.

Description

Many temperature heat-exchange system of a kind of single compressed machine refrigerant control

[technical field]

The utility model relates to heat exchange field, relates in particular to many temperature heat-exchange system of a kind of single compressed machine refrigerant control.

[background technology]

How can accurately control the flow (the expansion flow of compressed refrigerant) of refrigerator refrigerant, carry out heat exchange with liquid or gas, thereby the precision temperature control that reaches liquid or gas is refrigerator refrigerant--water or air heat exchange frozen water machine in industry for the important topic of the temperature constant of equipment or object.For having multiple independent temperature control, the particularly constant temperature system of precision temperature demand for control, typically use multiple independently compressors and freeze or heat.Use media or the object of the multiple pinpoint target temperature of single refrigeration unit controls, particularly precision temperature control, need to solve the difference due to the operating mode of variant temperature channel, as: move or stop, temperature is high or low, and affects the problem of the precision of other channel temperature controls and the compression/expansion of refrigeration system refrigerant.

[utility model content]

The technical problems to be solved in the utility model is to provide many temperature heat-exchange system of a kind of single compressed machine refrigerant control, uses single refrigeration unit to complete multiple independent temperature demands for control, to reach temperature control, energy-conservation object.

For solving the problems of the technologies described above, the utility model provides many temperature heat-exchange system of a kind of single compressed machine refrigerant control, comprises the first circulation of fluid path, the second circulation of fluid path, cooling fluid circuit and factory's business fluid passage,

Described the first circulation of fluid path comprises First Heat Exchanger, the first circulation of fluid entrance and the outlet of the first circulation of fluid, the first circulation of fluid and cooling fluid carry out heat exchange at described First Heat Exchanger place, described First Heat Exchanger comprises first input end mouth, the first output port, the second input port being communicated with first input end mouth and the second output port being communicated with the second input port

Described the second circulation of fluid path comprises the second heat exchanger, the second circulation of fluid entrance and the outlet of the second circulation of fluid, the second circulation of fluid and cooling fluid carry out heat exchange at described the second heat exchanger place, described the second heat exchanger comprises the 3rd input port, the 3rd output port, the four-input terminal mouth being communicated with the 3rd input port and the 4th output port being communicated with four-input terminal mouth

Described cooling fluid circuit comprises compressor, the 3rd heat exchanger, the first electric expansion valve, the second electric expansion valve and the 3rd electric expansion valve, cooling fluid and factory's business fluid carry out heat exchange at described the 3rd heat exchanger place, described the 3rd heat exchanger comprises the 5th input port, the 5th output port being communicated with the 5th input port, the 6th input port and the 6th output port being communicated with the 6th input port, the output port of described the first electric expansion valve is connected with the second input port of described First Heat Exchanger, the input port of described the first electric expansion valve is connected with the 6th output port of described the 3rd heat exchanger, the output port of described the second electric expansion valve is connected with the four-input terminal mouth of described the second heat exchanger, the input port of described the second electric expansion valve is connected with the 6th output port of described the 3rd heat exchanger, described the 3rd output port of electric expansion valve and the input port of described compressor are connected, the input port of described the 3rd electric expansion valve is connected with the 6th output port of described the 3rd heat exchanger, the output port of described compressor is connected with the 6th input port of described the 3rd heat exchanger, the input port of described compressor is connected with the second output port of described First Heat Exchanger, or be connected with the 4th output port of described the second heat exchanger, or be connected with the output port of the 3rd electric expansion valve,

Described factory business fluid flows into from the 5th input port of described the 3rd heat exchanger, flows out from the 5th output port of described the 3rd heat exchanger.

Further, described the first circulation of fluid path also comprises the first temperature sensor for detection of described the first circulation of fluid temperature, described the second circulation of fluid path also comprises the second temperature sensor for detection of described the second circulation of fluid temperature, and the circulation of fluid temperature detecting based on described the first temperature sensor and the second temperature sensor is controlled the switch ratio of the first electric expansion valve, the second electric expansion valve and the 3rd electric expansion valve.

Further, the switch ratio of described the first electric expansion valve, the second electric expansion valve and the 3rd electric expansion valve is controlled.

Further, described cooling fluid circuit has three loops, and Article 1 loop is: the loop that described compressor, described the 3rd heat exchanger, described the first electric expansion valve and described First Heat Exchanger form,

Article 2 loop is: the loop that described compressor, described the 3rd heat exchanger, described the 3rd electric expansion valve form,

Article 3 loop is: the loop that described compressor, described the 3rd heat exchanger, described the second electric expansion valve and described the second heat exchanger form.

Further, described the first circulation of fluid path also comprises the first circulating pump for increasing described the first circulation of fluid circulation power, the input port of described the first circulating pump is communicated with the first output port of described First Heat Exchanger, and the output port of described the first circulating pump is communicated with described the first circulation of fluid outlet.

Further, described the first circulating pump is provided with primary heater, to improve the temperature of the first circulation of fluid.

Further, described the second circulation of fluid path also comprises the second circulating pump for increasing described the second circulation of fluid circulation power, the input port of described the second circulating pump is communicated with the 3rd output port of described the second heat exchanger, and the output port of described the second circulating pump is communicated with described the second circulation of fluid outlet.

Further, described the second circulating pump is provided with secondary heater, to improve the temperature of the second circulation of fluid.

Further, described circulation of fluid is liquid or gas, and described cooling fluid is freon refrigerant, and described factory business fluid is cooling water.

Compared with prior art, the utility model uses single refrigeration unit to complete multiple independent temperature demands for control, makes it both to have controlled controlled object temperature, has reduced again overall energy consumption, has saved production cost.

[accompanying drawing explanation]

Fig. 1 is the structural representation in one embodiment of many temperature heat-exchange system of the single compressed machine refrigerant control in the utility model.

Wherein: 100 is many temperature heat-exchange system of single compressed machine refrigerant control, 110 is the first circulation of fluid path, 111 is the first circulation of fluid entrance, 112 is the first circulation of fluid outlet, 113 is First Heat Exchanger, 114 is the first temperature sensor, 115 is primary heater, 116 is the first circulating pump, 120 is the second circulation of fluid path, 121 is the second circulation of fluid entrance, 122 is the second circulation of fluid outlet, 123 is the second heat exchanger, 124 is the second temperature sensor, 125 is secondary heater, 126 is the second circulating pump, 130 is factory's business fluid passage, 131 is factory's business fluid intake, 132 is factory's business fluid issuing, 133 is the 3rd heat exchanger, 140 is cooling fluid circuit, 141 is the first electric expansion valve, 142 is the second electric expansion valve, 143 is the 3rd electric expansion valve, 144 is compressor.

[specific embodiment]

For above-mentioned purpose of the present utility model, feature and advantage can be become apparent more, below in conjunction with the specific embodiment, the utility model is described in further detail.

Alleged " embodiment " or " embodiment " refer to that the special characteristic relevant to described embodiment, structure or characteristic at least can be contained at least one implementation of the utility model herein.Different local in this manual " in one embodiment " that occur also nonessentially all refer to same embodiment, must not be yet with other embodiment mutually exclusive separately or select embodiment.In addition, represent sequence of modules in method, flow chart or the functional block diagram of one or more embodiment and revocablely refer to any particular order, also not forming restriction of the present utility model.

Fig. 1 is the structural representation in one embodiment of many temperature heat-exchange system of the single compressed machine refrigerant control in the utility model.As shown in Figure 1, many temperature heat-exchange system 100 of described single compressed machine refrigerant control comprises the first circulation of fluid path 110, the second circulation of fluid path 120, cooling fluid circuit 140 and factory's business fluid passage 130.

Described the first circulation of fluid path 110 comprises First Heat Exchanger 113, the first circulation of fluid entrance 111 and the first circulation of fluid outlet 112.The first circulation of fluid and cooling fluid carry out heat exchange at described First Heat Exchanger 113 places.

Described First Heat Exchanger 113 comprises first input end mouth, the first output port, the second input port being communicated with first input end mouth and the second output port being communicated with the second input port.

Described the first circulation of fluid flows into First Heat Exchanger 113 through the first circulation of fluid entrance 111 by the first input end mouth of described First Heat Exchanger 113, fluid flows out from the first output port of First Heat Exchanger 113, and flows out by described the second circulation of fluid outlet 112.

Described the second circulation of fluid path 120 comprises that the second heat exchanger 123, the second circulation of fluid entrance 121 and the second circulation of fluid outlet 122, the second circulation of fluids and cooling fluid carry out heat exchange at described the second heat exchanger 123 places.

Described the second heat exchanger 123 comprises the 3rd input port, the 3rd output port, the four-input terminal mouth being communicated with the 3rd input port and the 4th output port being communicated with four-input terminal mouth.

Described the second circulation of fluid flows into the second heat exchanger 123 through the second circulation of fluid entrance 121 by the 3rd input port of described the second heat exchanger 123, fluid flows out from the 3rd output port of the second heat exchanger 123, and flows out by described the second circulation of fluid outlet 122.

Described factory business fluid intake 131 is connected with the 5th input port of described the 3rd heat exchanger 133, and described factory business fluid issuing 132 is connected with the 5th output port of described the 3rd heat exchanger 133.

Described cooling fluid circuit 140 comprises compressor 144, the 3rd heat exchanger 133, the first electric expansion valve 141, the second electric expansion valve 142 and the 3rd electric expansion valve 143.Cooling fluid and factory's business fluid carry out heat exchange at described the 3rd heat exchanger 133 places.

Described the 3rd heat exchanger 133 comprises the 5th input port, the 5th output port being communicated with the 5th input port, the 6th input port and the 6th output port being communicated with the 6th input port, the output port of described the first electric expansion valve 141 is connected with the second input port of described First Heat Exchanger 113, the input port of described the first electric expansion valve 141 is connected with the 6th output port of described the 3rd heat exchanger 133, the output port of described the second electric expansion valve 142 is connected with the four-input terminal mouth of described the second heat exchanger 123, the input port of described the second electric expansion valve 142 is connected with the 6th output port of described the 3rd heat exchanger 133, the output port of described the 3rd electric expansion valve 143 is connected with the input port of described compressor 144, the input port of described the 3rd electric expansion valve 143 is connected with the 6th output port of described the 3rd heat exchanger 133, the output port of described compressor 144 is connected with the 6th input port of described the 3rd heat exchanger 133, the input port of described compressor 144 is connected with the second output port of described First Heat Exchanger 113, or be connected with the 4th output port of described the second heat exchanger 123, or be connected with the output port of the 3rd electric expansion valve 143.

Described cooling fluid flows out the 6th input port through the 3rd heat exchanger 133 via the output of compressor 144, a part flows into First Heat Exchanger 113 through the first electric expansion valve 141, cooling fluid flows out from the second delivery outlet end of First Heat Exchanger 113, is got back in compressor 144 by the input of compressor 144; Another part, through the 3rd electric expansion valve 143, is got back in compressor 144 by the input of compressor 144; Some flows into the second heat exchanger 123 through the second electric expansion valve 142, and cooling fluid flows out from the 4th delivery outlet end of the second heat exchanger 123, is got back in compressor 144 by the input of compressor 144.

Wherein the switch ratio of the first electric expansion valve 141, the second electric expansion valve 142 and the 3rd electric expansion valve 143 is adjustable, be opened into 0% unlatching such as 100%, adjust grade, so have 0% for every 5% 1,5%, 10% ...---95%, 100% much more so switch ratio grades, like this with respect to overall system control flow bore, can point-device adjustment flow, thus the power of heat exchange can be controlled accurately, and then the temperature of accurate controlled circulation fluid.Each electric expansion valve, with stepper motor or the direct current generator of gauge tap ratio, is controlled the switch ratio of described electric expansion valve by controlling described stepper motor or direct current generator.When high temperature, as 80 degrees Celsius of circulation of fluids, need be down to 20 degrees Celsius, allowing the first electric expansion valve 141 open tunes up, the second electric expansion valve 142 is opened and is tuned up, the 3rd electric expansion valve 143 is opened and is turned down or close, and increases the heat exchange amount of cooling fluid and circulation of fluid, reduces the object of circulation of fluid temperature to reach high-amplitude; When low temperature, as 25 degrees Celsius of circulation of fluids, need be down to 20 degrees Celsius, allowing the first electric expansion valve 141 open turns down, the second electric expansion valve 142 is opened and is turned down, the 3rd electric expansion valve 143 is opened and is tuned up, and reduces the heat exchange amount of cooling fluid and circulation of fluid, reduces the object of circulation of fluid temperature to reach low amplitude.

Can find out, described cooling fluid circuit 140 has three paths, Article 1, path is: the loop that described compressor 144, described the 3rd heat exchanger 133, described the first electric expansion valve 141 and described First Heat Exchanger 113 form, concrete, described cooling fluid flows out from described compressor 144, flow through described the 3rd heat exchanger 133, the first electric expansion valve 141 and described First Heat Exchanger 113, carry out heat exchange at described the 3rd heat exchanger 133 and First Heat Exchanger 113 places, get back to subsequently described compressor 144.

Article 2 loop is: the loop that described compressor 144, described the 3rd heat exchanger 133, described the 3rd electric expansion valve 143 form, concrete, described cooling fluid flows out from described compressor 144, flow through described the 3rd heat exchanger 133 and the 3rd electric expansion valve 143, carry out heat exchange at described the 3rd heat exchanger 133 places, get back to subsequently described compressor 144.

Article 3 loop is: the loop that described compressor 144, described the 3rd heat exchanger 133, described the second electric expansion valve 142 and described the second heat exchanger 123 form, concrete, described cooling fluid flows out from described compressor 144, flow through described the 3rd heat exchanger 133, the second electric expansion valve 142 and described the second heat exchanger 123, carry out heat exchange at described the 3rd heat exchanger 133 and the second heat exchanger 123 places, get back to subsequently described compressor 144.

In the present embodiment, described the first circulation of fluid path 110 also comprises the first circulating pump 116 for increasing described the first circulation of fluid circulation power, the input port of described the first circulating pump 116 is communicated with the first output port of described First Heat Exchanger 113, and the output port of described the first circulating pump 116 is communicated with described circulation of fluid outlet 112.In order to improve the temperature of the first circulation of fluid, described the first circulating pump 116 is provided with primary heater 115.Described the second circulation of fluid path 120 also comprises the second circulating pump 126 for increasing described the second circulation of fluid circulation power, the input port of described the second circulating pump 126 is communicated with the 3rd output port of described the second heat exchanger 123, and the output port of described the second circulating pump 126 is communicated with described the second circulation of fluid outlet 122.In order to improve the temperature of the second circulation of fluid, described the second circulating pump 126 is provided with secondary heater 125.

On described the first circulation of fluid path 110, also comprise the first temperature sensor 114, it is for detection of the temperature of described the first circulation of fluid.The input port of described the first temperature sensor 114 is communicated with the output port of described the first circulating pump 116, and the output port of described the first temperature sensor 114 is connected with described the first circulation of fluid outlet 112.Described the first circulation of fluid flows out from the first output port of described First Heat Exchanger 113, through the first circulating pump 116 and the first temperature sensor 114, arrives the first circulation of fluid outlet 112.Described the second circulation of fluid path 120 also comprises the second temperature sensor 124, and it is for detection of the temperature of described the second circulation of fluid.The input port of described the second temperature sensor 124 is communicated with the output port of described the second circulating pump 126, and the output port of described the second temperature sensor 124 is connected with described the second circulation of fluid outlet 122.Described the second circulation of fluid flows out from the 3rd output port of described the second heat exchanger 123, through the second circulating pump 126 and the second temperature sensor 124, arrives the second circulation of fluid outlet 122.

The second circulation of fluid temperature that the first circulation of fluid temperature detecting based on described the first temperature sensor 114 and the second temperature sensor 124 detect is controlled the switch ratio of the first electric expansion valve 141, the second electric expansion valve 142 and the 3rd electric expansion valve 143, thereby realize the control to cooling fluid in many temperature heat-exchange system 100 of single compressed machine refrigerant control, and then realize the accurate temperature control of controlled device.

In the present embodiment, described circulation of fluid is liquid or gas, and described cooling fluid is freon refrigerant, and described factory business fluid is cooling water.

In sum, many temperature heat-exchange system 100 of single compressed machine refrigerant of the present utility model control arranges the first electric expansion valve 141 between the 6th output port of described the 3rd heat exchanger 133 and the second input port of described First Heat Exchanger 113; Between the 6th output port of described the 3rd heat exchanger 133 and the four-input terminal mouth of described the second heat exchanger 123, the second electric expansion valve 142 is set.Many temperature heat-exchange system 100 of described single compressed machine refrigerant control also comprises and is arranged at the first temperature sensor 114 for detection of described the first circulation of fluid temperature on described the first circulation of fluid path 110 and is arranged at the second temperature sensor 124 for detection of described the second circulation of fluid temperature on described the second circulation of fluid path 120, the second circulation of fluid temperature that the first circulation of fluid temperature detecting based on described the first temperature sensor 114 and described the second temperature sensor 124 detect is controlled the switch ratio of each electric expansion valve, regulate a part of cooling fluid and first, the heat exchange amount of the second circulation of fluid.Utilize more than 1 or 2 electric expansion valve ratios adjusting to reach wide temperature field control object, thereby effectively accomplish the accurate temperature controlling of circulating fluid a wider temperature range.

Its specific works principle is: described cooling fluid flows out from compressor 144, through the 3rd heat exchanger 133, described cooling fluid carries out after heat exchange at the 3rd heat exchanger 133 places and factory's business fluid, a part is through the first electric expansion valve 141 and First Heat Exchanger 113, and described cooling fluid is got back to compressor 144 after First Heat Exchanger 113 places and the first circulation of fluid are carried out heat exchange; A part is through the second electric expansion valve 142 and the second heat exchanger 123, and described cooling fluid is got back to compressor 144 at the second heat exchanger 123 places and after carrying out heat exchange with the second circulation of fluid; Another part is got back to compressor 144 after the 3rd electric expansion valve 143.

It should be noted that, above embodiment is only unrestricted in order to the technical solution of the utility model to be described, although the utility model is had been described in detail with reference to preferred embodiment, those of ordinary skill in the art is to be understood that, can modify or be equal to replacement the technical solution of the utility model, and not departing from the spirit and scope of technical solutions of the utility model, it all should be encompassed in the middle of claim scope of the present utility model.

Claims

1. many temperature heat-exchange system of single compressed machine refrigerant control, is characterized in that, comprises the first circulation of fluid path, the second circulation of fluid path, cooling fluid circuit and factory's business fluid passage,

2. many temperature heat-exchange system of single compressed machine refrigerant as claimed in claim 1 control, it is characterized in that: described the first circulation of fluid path also comprises the first temperature sensor for detection of described the first circulation of fluid temperature, described the second circulation of fluid path also comprises the second temperature sensor for detection of described the second circulation of fluid temperature, and the circulation of fluid temperature detecting based on described the first temperature sensor and the second temperature sensor is controlled the switch ratio of the first electric expansion valve, the second electric expansion valve and the 3rd electric expansion valve.

3. many temperature heat-exchange system of single compressed machine refrigerant as claimed in claim 2 control, is characterized in that: the switch ratio of described the first electric expansion valve, the second electric expansion valve and the 3rd electric expansion valve is controlled.

4. many temperature heat-exchange system of single compressed machine refrigerant as claimed in claim 1 control, it is characterized in that: described cooling fluid circuit has three loops, Article 1, loop is: the loop that described compressor, described the 3rd heat exchanger, described the first electric expansion valve and described First Heat Exchanger form

5. many temperature heat-exchange system of single compressed machine refrigerant as claimed in claim 1 control, it is characterized in that: described the first circulation of fluid path also comprises the first circulating pump for increasing described the first circulation of fluid circulation power, the input port of described the first circulating pump is communicated with the first output port of described First Heat Exchanger, and the output port of described the first circulating pump is communicated with described the first circulation of fluid outlet.

6. many temperature heat-exchange system of single compressed machine refrigerant as claimed in claim 5 control, is characterized in that: described the first circulating pump is provided with primary heater, to improve the temperature of the first circulation of fluid.

7. many temperature heat-exchange system of single compressed machine refrigerant as claimed in claim 1 control, it is characterized in that: described the second circulation of fluid path also comprises the second circulating pump for increasing described the second circulation of fluid circulation power, the input port of described the second circulating pump is communicated with the 3rd output port of described the second heat exchanger, and the output port of described the second circulating pump is communicated with described the second circulation of fluid outlet.

8. many temperature heat-exchange system of single compressed machine refrigerant as claimed in claim 7 control, is characterized in that: described the second circulating pump is provided with secondary heater, to improve the temperature of the second circulation of fluid.

9. many temperature heat-exchange system of single compressed machine refrigerant as claimed in claim 1 control, is characterized in that: described circulation of fluid is liquid or gas, described cooling fluid is freon refrigerant, and described factory business fluid is cooling water.