DE69818696T2 - CONDENSER FOR HEAT EXCHANGE SYSTEMS - Google Patents

Description

The present invention relates to a capacitor for Heat exchange systems according to the preamble of claim 1. Such a heat exchanger is known for example from DE-A1-341 / 567.

Like someone with technical skills White, becomes a heat exchange system, such as B. a refrigerator, a freezer or a refrigerated display case Widely used to store food and drinks for a long time in cool temperatures (e.g. 2-5 ° C) durable close. Such a heat exchange system is through a cooling circuit operated.

1 Fig. 12 is a view illustrating a typical refrigeration cycle in a heat exchange system.

As shown in the drawing, the typical refrigeration cycle includes a compressor 1 , a capacitor 2 , a capillary tube 3 , an evaporator 4 and an accumulator 5 , The circuit of the coolant in the heat exchange system is described below. I.e. a coolant in the heat exchange system is through the compressor 1 compresses and thus has a relatively high temperature and a high pressure. The compressed coolant is in a condenser 2 introduced, which has a long coolant tube to reduce the coolant from a vapor phase to a liquid phase. Then the liquid coolant in the condenser 2 into a capillary tube 3 introduced. At this time, the liquid coolant becomes a mixed coolant consisting of vapor and liquid phases and having a low temperature and a low pressure. The above-mentioned mixed refrigerant is in an evaporator 4 evaporates quickly, but it absorbs heat from the surroundings of the heat exchange system. The mixed coolant in the evaporator 4 is in an accumulator 5 introduced to be divided into the vapor and liquid coolant. Such an accumulator 5 has suction and discharge pipes and a housing. I.e. The steam coolant in the mixed coolant is only in the compressor 1 is inserted and goes through the drain pipe, but the liquid coolant in the mixed coolant is discharged into and held in the case.

Briefly described, the refrigerant is through the compressor 1 condensed and into the condenser 2 introduced. At this time, the compressed coolant is at a relatively low temperature while passing through the long cooling pipe of the condenser 2 flows. Then the low temperature coolant flows through the capillary tube 3 , which allows the current speed of the coolant to be high. The coolant is from the capillary tube 3 to the evaporator 4 drained. In such a case, since the high pressure of the refrigerant drops, the refrigerant quickly becomes in the evaporator 4 evaporates while heat is absorbed from the environment of the heat exchange system, thus forming cool air to be circulated in the heat exchange system.

Above all, the condenser consists of a long coolant tube between the compressor and the capillary tube. The above-mentioned long coolant pipe is bent into a desired shape by a bending process. As a result, the high temperature of the coolant drops by itself as the coolant passes through the long coolant pipe of the condenser 2 flows. Alternatively, the heat of the coolant can be radiated by a fan, which, if necessary, around the condenser 2 is attached. In this case, the function of the condenser, namely the liquefaction of a steam coolant, is based on the efficiency of the radiant heat of the steam coolant.

However, the capacitor mentioned above is problematic because the radiant heat of the one flowing through the condenser refrigerant unexpectedly during the high of the fair weather season is reduced. Moreover the fan is forced to operate, causing noise and a increased Electricity consumption is generated.

description the invention

Accordingly, the present invention considering the above Problems that occur in the prior art, and one The object of the present invention is a condenser for heat exchange systems to deliver which is a cooling pipe has which with a liquid such. B. a brine, an anti-freeze or water with a relatively high density containing condensation medium is filled and thus the radiant heat of Capacitor increased, the power consumption of the capacitor is reduced and the durability of the capacitor extended.

To accomplish the task mentioned above, supplies the present invention a condenser for heat exchange systems comprising: a Condenser tube, which with a between a compressor and connected to a capillary tube placed coolant tube is to a coolant in a heat exchange system to allow to flow through the condenser tube; a liquid tube, which in one piece on a side wall of the condensation tube by an extrusion process is formed; and a cooling pipe, which has a long zigzag shape and a variety of its outside trained cooling fins contains and which one on the liquid pipe is attached that both ends of the liquid tube with a liquid inlet or a drain of the cooling tube are connected so that a condensation medium in the cooling tube is effective through the cooling tube and the liquid pipe circulates becomes.

As a preferred embodiment are two or more condenser tubes horizontal and in one piece both side walls of the liquid pipe formed by an extrusion process.

Short description of the drawings

The above and other tasks, properties and advantages of the present invention will become more apparent from the following detailed description, which are related was taken with the accompanying drawings, in which:

1 Fig. 12 is a view illustrating a typical refrigeration cycle in a heat exchange system;

2 11 is a view illustrating a refrigeration cycle in a heat exchange system according to the present invention;

3 14 is a view illustrating the construction of a condenser for heat exchange systems according to the first embodiment of the present invention;

4 3 is an enlarged cross-sectional view showing the capacitor of FIG 3 illustrated; and

5 12 is an enlarged cross-sectional view illustrating the construction of a condenser for heat exchange systems according to the second embodiment of the present invention.

preferred embodiments the invention

2 Fig. 12 is a view illustrating a refrigeration cycle in a heat exchange system according to the present invention. The 3 and 4 14 are views illustrating the construction of a condenser for heat exchange systems according to the first embodiment of the present invention.

As in the 2 to 4 shown, the cooling circuit "A" contains a compressor 10 , a capacitor 20 , a capillary tube 30 , an evaporator 40 and an accumulator 50 , The circulation of a coolant in the heat exchange system is described below. I.e. the coolant in the heat exchange system is through the compressor 10 compresses and thus has a relatively high temperature and a high pressure. The compressed coolant is in the condenser 20 introduced, which has a long coolant tube to reduce the coolant from a vapor phase to a liquid phase. Then the liquid coolant in the condenser 20 into the capillary tube 30 introduced. At this time, the liquid coolant becomes a mixed coolant, which consists of vapor and liquid phases and has a low temperature and a low pressure. The coolant mixed above is quickly in the evaporator 40 evaporates, but heat is absorbed from the environment of the heat exchange system. The mixed coolant in the evaporator 40 is in the accumulator 50 introduced to be divided into the vapor and liquid coolant.

The capacitor also contains 20 a condenser tube 21 and a liquid tube 22 , I.e. the condenser tube 21 communicates with a coolant pipe 26 which is between the compressor 10 and the capillary tube 30 located as in 3 shown. For practical reasons, the condenser tube 21 in 3 illustrated in a straight line, but it actually has a long, spiral shape to match the performance of the capacitor 20 to improve.

The liquid pipe 22 is in one piece on one side wall 23 the condenser tube 21 of the capacitor 20 educated. Such a liquid pipe 22 is with a cooling pipe 25 , which has a long zigzag shape, connected so that both ends of the liquid tube 22 with a liquid inlet 25b or a process 25c of the cooling pipe 25 are connected. A variety of cooling fins 25a is also on the outer surface of the cooling tube 25 educated. The liquid pipe 22 is filled with a condensation medium, such as. As a calcium chloride solution, sodium chloride solution or magnesium chloride solution, which contains a medium such. B. a brine, an anti-freeze or water with a relatively high density.

As in 4 slots are shown 23a both on the upper and lower section of the side wall 23 between the condensation and the liquid pipe 21 respectively. 22 formed lengthways and thus enable the condensation and the liquid pipe 21 and 22 to be widely spaced if necessary. There is also a variety of cooling fins 24 radially on the outer surfaces of the condensation and liquid pipes 21 and 22 formed, thereby increasing the performance of the capacitor 20 increase.

To the capacitance of the capacitor 20 must increase the length of the cooling tube 25 To be long. I.e. a further extension tube (not shown), which has a compressed design, is placed with its two ends between the liquid inlet 25b and the process 25c of the liquid pipe 22 connected. There is also a pump (not shown) on the cooling tube 25 attached to a desired position. As an alternative, a fan operated by a control device can be placed around the cooling pipe 25 attached to the radiant heat of the cooling tube 25 to improve.

The manufacturing method of the capacitor according to this invention is described below. The liquid pipe 22 is in one piece on the condenser tube 21 formed by an extrusion process and thus enables the configuration of the condensation and liquid pipe 21 and 22 to be shaped like a peanut. After that the single body of the condensation and liquid tube 21 and 22 cut to a desired length. Because the slots 23a lengthways in the lower and upper section of the side walls 23 are formed, which between the condensation and the liquid tube 21 and 22 are formed in this case, the condensation and the liquid tube 21 and 22 are spaced far apart if necessary.

Then both ends of the condenser tube 21 through a welding process with the coolant pipe 26 connected, thus allowing the coolant to flow through the condenser tube 21 flows. In addition, both ends of the liquid tube are 22 with the liquid inlet 25b or the process 25c of the cooling pipe 25 connected, thus allowing the condensation medium to flow through the liquid tube 22 and the cooling pipe 25 flows.

Therefore, the circuit of the coolant in the heat exchange system is described below. I.e. the coolant in the heat exchange system is through the compressor 10 compresses, so that it has a relatively high temperature and high pressure. The compressed coolant is in the condenser 20 introduced to reduce the coolant from a vapor phase to a liquid phase. Then the liquid coolant in the condenser 20 into the capillary tube 30 introduced. At this time, the liquid coolant becomes a mixed coolant, which consists of vapor and liquid phases and has a low temperature and a low pressure. The coolant mixed above is quick in an evaporator 40 evaporates, but heat is absorbed from the environment of the heat exchange system.

Especially when the steam coolant, which has a relatively high temperature, through the condenser tube 21 of the capacitor 20 flows, the condensation medium, which has a high density, flows from the cooling pipe 25 to the liquid pipe 22 , At this time, the heat of the steam coolant, which is approximately 80 ° C, and through the condenser tube 21 flows, transferred to the condensation medium, which has a normal temperature and through the liquid tube 22 goes. As a result, the vapor coolant easily merges into the liquid coolant, whereas the condensing medium is at a relatively high temperature.

The circulation of the condensation medium in such a case is described below. First, the condensation medium has when the capacitance of the capacitor 20 is low, a relatively low temperature while passing by itself through the long cooling tube 25 flows. I.e. the condensation medium, which has a relatively low temperature and through the liquid inlet 25b flows into the upper section of the cooling tube 25 introduced. After that, the high temperature of the condensation medium drops as the coolant from the upper portion to the lower portion of the cooling tube 25 flows. As a result, the normal temperature condensing medium is discharged into the drain 25c of the cooling pipe 25 drained.

Then it will have a relatively high temperature and the liquid supply 25b flowing condensation medium when the capacitance of the capacitor 20 is high, from the upper section to the lower section of the cooling pipe 25 by means of a pump (not shown), which on the cooling pipe 25 is attached to a desired position. In this case, the cooling pipe 25 , which has a compressed design, to the outside of the capacitor 20 exposed, thus allowing the work of the cooling pipe piping 25 can be easily carried out. Alternatively, a fan (not shown), which is operated by a control device, can be arranged around the cooling pipe 25 attached to the radiant heat of the cooling tube 25 effectively increase.

5 12 is a view illustrating the construction of a condenser for heat exchange systems according to the second embodiment of the invention.

In the second embodiment, the capacitor contains 20 a liquid tube 22 and two condenser tubes 21a and 21b , I.e. the condenser tubes 21a and 21b are horizontal and in one piece on both side walls of the liquid tube 22 formed by an extrusion process. Thus, the heat of the steam coolant, which passes through the condenser tubes 21a and 21b flow, transferred faster to the condensation medium, which through the liquid tube 22 flows. As a result, the radiant heat of the capacitor is effectively and quickly carried outside.

commercial applicability

As mentioned above is a condenser for heat exchange systems this invention with a cooling tube, which with a liquid like z. B. a brine, an anti-freeze or water with a condensation medium containing a relatively high density is filled, and thus the radiant heat of the capacitor increased, the electrical power consumption of the capacitor is reduced and the Extended capacitor life.

In addition, the condensation medium, if the capacity of the capacitor is low, a normal temperature while it through the long cooling pipe flows. Is the capacity of the capacitor is high, so the condensation medium, which is a has relatively high temperature, forcibly by means of the cooling tube a pump circulates. As an alternative, a ventilator can cooling pipe be attached to effectively increase the radiant heat of the cooling tube.

In addition, the cooling tube, which is a Compressed construction, exposed to the outside of the condenser, and thus enables the work of the pipes of the cooling tube can be easily carried out.

Claims (2)

Capacitor ( 20 ) for heat exchanger systems, consisting of a condenser tube ( 21 ), which is connected to a compressor ( 10 ) and a capillary tube ( 30 ) arranged coolant pipe ( 26 ) is connected to allow a coolant in a heat exchanger system to flow through the condenser tube; characterized in that the condenser continues to consist of a liquid tube ( 22 ), which is formed on a side wall of the condenser tube integrated by an extrusion process; and a long cooling tube folded into a zigzag shape ( 25 ), which has a large number of molded cooling fins ( 25a ), and which is connected to the liquid tube in such a way that both ends of the liquid tube each have a liquid inlet ( 25b ) and a sequence ( 25c ) of the cooling tube, and so a coolant in this cooling tube effectively circulates through this and through the liquid tube. Condenser according to claim 1, characterized in that at least two or more condenser tubes ( 21a . 21b ) are horizontally integrated on both side walls of the liquid tube by an extrusion process.