초록 ▼

Refrigerating device formed by a main compressor (190), a condenser (140) downstream of and in fluid communication with the main compressor (190), main expansion means (170) downstream of the condenser (140) and an evaporator (180) downstream of and in fluid communication with the main expansion mea

Refrigerating device formed by a main compressor (190), a condenser (140) downstream of and in fluid communication with the main compressor (190), main expansion means (170) downstream of the condenser (140) and an evaporator (180) downstream of and in fluid communication with the main expansion means (170), which also comprises a turbocompressor unit (160) in fluid communication between the evaporator (180) and the main compressor (190) and a heat exchanger (150, 152) having a hot branch (150c) connected upstream, via an inlet line (145), to the condenser (140) and downstream, via an outlet line (149), to the main expansion means (170) and a cold branch (15Of) connected, upstream, to an expansion means (142, 144) mounted on a branch (146) of the line (145) and, downstream, to a turbine portion (162) of the turbocompressor unit (160). The invention also relates to a method for circulating a refrigerating fluid inside the abovementioned device.

대표청구항 ▼

1. A refrigerating device comprising: a main compressor;a condenser downstream of and in fluid communication with said main compressor;main expansion means downstream of said condenser;an evaporator downstream of and in fluid communication with said main expansion means; anda turbocompressor unit in

1. A refrigerating device comprising: a main compressor;a condenser downstream of and in fluid communication with said main compressor;main expansion means downstream of said condenser;an evaporator downstream of and in fluid communication with said main expansion means; anda turbocompressor unit in fluid communication between said evaporator and said main compressor and in fluid communication with at least one heat exchanger, said at least one heat exchanger having: a hot branch connected upstream, via an inlet line, to said condenser and downstream, via an outlet line, to said main expansion means; anda cold branch connected, upstream, to an expansion means mounted on a branch of said inlet line to said condenser and connected, downstream, to a turbine portion of said turbocompressor unit,wherein said cold branch being connected downstream to said turbine portion enables fluid communication between said at least one heat exchanger and said turbocompressor unit. 2. The refrigerating device according to claim 1, wherein said at least one heat exchanger is a tube-bundle heat exchanger. 3. The refrigerating device according to claim 1, wherein said at least one heat exchanger is a plate-type heat exchanger. 4. The refrigerating device according to claim 1, wherein said main expansion means and said expansion means are isoenthalpic throttling valves. 5. The refrigerating device according to claim 1 further comprising a first and a second heat exchanger arranged in series between said condenser and said main expansion means, wherein said turbocompressor unit comprises a first and a second turbine portion,wherein said first heat exchanger comprises: a first hot branch connected upstream, via a first inlet line, to said condenser and connected downstream, via a first outlet line, to said second heat exchanger; anda first cold branch, connected upstream to a first expansion means mounted on a first branch of said first inlet line to said condenser, and connected downstream to said first turbine portion of said turbocompressor unit,wherein said second heat exchanger comprises: a second hot branch connected upstream, via a connection line, to said first hot branch of said first heat exchanger and connected downstream to said main expansion means; anda second cold branch connected, upstream, to a second expansion means mounted on a second branch of said connection line, and connected, downstream, to said second turbine portion of said turbocompressor unit. 6. A method for circulating a refrigerating fluid, the method comprising: compressing the refrigerating fluid in a main compressor;condensing the refrigerating fluid in a condenser downstream of and in fluid communication with said main compressor;expanding the refrigerating fluid in main expansion means downstream of said condenser;evaporating the refrigerating fluid in an evaporator downstream of and in fluid communication with said main expansion means;between said condensation stage and said expansion stage, having at least one heat exchange stage involving a heat exchange inside at least one heat exchanger,said heat exchange being between the refrigerating fluid downstream from the condenser and an associated amount of the refrigerating fluid downstream from the condenser,said refrigerating fluid, downstream from the condenser, circulating inside a hot branch of said at least one heat exchanger,said associated amount circulating inside a cold branch of said at least one heat exchanger, wherein said associated amount is bled-off from the refrigerating fluid downstream from the condenser and is cooled inside an expansion means before flowing downstream into said cold branch of said at least one heat exchanger; andbetween said main expansion stage and said main compression stage, having a pre-compression stage involving pre-compression of the refrigerating fluid inside a turbocompressor unit,said pre-compression stage comprising at least one expansion stage involving expansion of the associated amount inside at least one turbine portion of the turbocompressor unit, the associated amount leaving the cold branch of said at least one heat exchanger to flow into said at least one turbine. 7. The method according to claim 6, wherein downstream of said at least one heat exchange stage between said condensation stage and said expansion stage further comprises: a second heat exchange stage in a second heat exchanger arranged in series with the at least one heat exchanger, said second heat exchange stage involving a second heat exchange between the refrigerating fluid leaving the hot branch of the at least one heat exchanger and a second associated amount of the refrigerating fluid,said refrigerating fluid, from the hot branch of the at least one heat exchanger, circulating inside a second hot branch of said second heat exchanger,said second associated amount circulating inside a second cold branch of said second heat exchanger, wherein said second associated amount is bled-off said refrigerating fluid from the hot branch of the at least one heat exchanger and is cooled inside a second expansion means before flowing into said second cold branch,wherein said pre-compression stage, between said main expansion stage and said main compression stage, is powered by expansion of the associated amount leaving the cold branch of the at least one heat exchanger in a first turbine portion of said turbocompressor unit, and by the expansion of the second associated amount leaving the second cold branch of the second heat exchanger in a second turbine portion of said turbocompressor unit. 8. The refrigerating device according to claim 5, wherein each of said first and second heat exchanger is a tube-bundle heat exchanger. 9. The refrigerating device according to claim 5, wherein each of said first and second heat exchanger is a plate-type heat exchanger. 10. The refrigerating device according to claim 5, wherein said main expansion means, said first expansion means, and said second expansion means are isoenthalpic throttling valves.