KR20120039488A - Evaporator - Google Patents

Abstract

PURPOSE: An evaporator is provided to increase heating value in length part arranged in the upstream of air flow direction in a defrost pipe heater and reduce time for defrosting frost attached in plate fins at the upstream of the air flow direction. CONSTITUTION: An evaporator comprises a defrost pipe heater(8) which has a heater line, a pipe accommodating the heater line, and a lead line for power feed connected in both ends of the heater line. In the defrost pipe heater, heating density that is heating value per unit area in the exterior surface of the pipe is partially different in length direction of the defrost pipe heater. In case of the heating density of the defrost pipe heater, the middle part in the length direction is higher than both end parts. The heater line of the defrost pipe heater is a coil shape and the pitch of a part where the heating density is higher is lower than a part where the heating density is lower.

Description

Evaporator {EVAPORATOR}

TECHNICAL FIELD The present invention relates to an evaporator, and more particularly, to an evaporator suitably used in a refrigeration cycle for use in a refrigeration and refrigeration apparatus such as a refrigerator, a refrigerated showcase, a freezer, a refrigerated showcase and the like.

For example, a refrigeration cycle provided with a compressor, a condenser and an evaporator is installed in the heat insulation body of the refrigerator. The evaporator of such a refrigeration cycle consists of a plurality of plate fins arranged in parallel, and is provided with a plurality of fin groups provided with a plurality of spaced apart in the air flow direction, and a plurality of straight pipe portions fixed in a penetrating shape to all plate fins of each fin group. And a heat exchanger tube which connects two adjacent straight tube portions and has one bent tube portion smaller than the straight tube portion has been widely used.

However, in such an evaporator, implantation occurs on each plate fin by moisture in the air. When such an idea occurs, the attached frost becomes a resistance and the amount of air flowing between the plate fins of each fin group decreases rapidly or the amount of heat transfer between the air and the refrigerant flowing in the heat exchange tube decreases rapidly, thereby cooling in a relatively short time. There was a problem that the efficiency was lowered. Therefore, when the amount of implantation became more than a certain amount, it was necessary to melt and remove the frost.

As an evaporator capable of defrosting the generated frost, for example, a plurality of plate pins arranged in a parallel shape, a plurality of straight pipe portions fixed in a penetrating shape to the plate pins, and two adjacent straight pipe portions are connected to each other. A heat exchanger tube consisting of one small number of bent tube portions, a plurality of straight tube portions inserted into the inlet portions provided on both side edges of the plate pin and contacting the plate pins and two adjacent straight tube portions, and one less than the straight tube portion. It is known that the defrost pipe heater which consists of a number of bend pipe parts is provided, and the defrost pipe heater has a heater wire, the pipe which accommodates a heater wire, and the feeder lead wire connected to both ends of a heater wire (refer patent document 1). ).

By the way, the amount of frost adhered to the plate fin of the evaporator as described above tends to increase on the upstream side of the air flow direction, usually on the lower side, and on the downstream side of the air flow direction, usually on the upper side. However, the calorific value of the defrosting pipe heater of the evaporator described in Patent Literature 1 is constant over the entire length, and the number of straight pipe portions of the defrosting pipe heater is the air flow direction upstream side with a large amount of frosting to the plate fin and the air having a small amount of frosting. Since it is equalized to the downstream side in the flow direction, in order to defrost the frost attached to the plate fin in the air flow direction upstream side for a short time, it is necessary to increase the amount of heat generated in the entire defrost pipe heater. Therefore, the amount of heat generated from the straight pipe portion and the bent pipe portion disposed in the downstream portion in the air flow direction with a small amount of implantation to the plate fin is excessive, and the amount of power consumption increases, resulting in high cost. On the other hand, if the calorific value from the defrosting pipe heater is set to an amount that will not be surplused in the downstream portion of the air flow direction, it takes time to melt the frost attached to the plate fin in the upstream portion of the air flow direction, and again, the amount of power consumption Increase the cost.

In order to solve such a problem, it is also conceivable to arrange the defrosting pipe heater so that there are more straight pipes in the upstream portion of the air flow direction having a large amount of implantation to the plate fin than in the downstream portion of the air flow direction having a small amount of implantation. The entire length of the defrost pipe heater is increased, resulting in high material costs.

Japanese Patent Laid-Open No. 2007-46868

An object of the present invention is to solve the above problems and to provide an evaporator capable of efficiently defrosting frost attached to a plate fin at low cost.

This invention consists of the following forms in order to achieve the said objective.

1) A heat exchange tube and a plate formed by connecting a plurality of plate fins arranged in a parallel shape and a plurality of straight tube portions installed in a penetrating shape and two adjacent straight tube portions, and having one bent tube portion smaller than the straight tube portion. A defrost pipe heater comprising a plurality of straight pipe portions in contact with the fins and two adjacent straight pipe portions, and having one bent pipe portion smaller than the straight pipe portion, the defrost pipe heater connects the heater wire and the heater wire. In an evaporator having a pipe for feeding and a lead wire for feeding connected to both ends of the heater wire,

An evaporator in which a heat generation density, which is a heat generation amount per unit area of a pipe outer peripheral surface of a defrosting pipe heater, is partially different in the longitudinal direction of the defrosting pipe heater.

2) The evaporator as described in said 1) in which the exothermic density of the defrost pipe heater is higher than the access part of both ends in the middle part of a longitudinal direction.

3) The evaporator according to the above 1), wherein the heater wire of the defrosting pipe heater has a coil shape and is smaller than the pitch of a portion having a low heat generation density and a pitch of a portion having a high heat generation density.

4) The evaporator as described in said 1) in which the intermediate part of the defrost pipe heater is arrange | positioned above a wind.

5) The evaporator as described in said 1) in which a part of intermediate part of a defrost pipe heater is arrange | positioned above a wind rather than the straight part of the heat exchanger tube located in the uppermost wind side.

According to the evaporator of 1), since the exothermic density, which is the heat generation amount per unit area of the pipe outer circumferential surface of the defrosting pipe heater, is partially different in the longitudinal direction of the defrosting pipe heater, there is a large amount of implantation in the plate fin of the defrosting pipe heater. The exothermic density of the length part arrange | positioned at the airflow direction upstream part can be made higher than the exothermic density of the length part arrange | positioned similarly to the airflow direction downstream part with a small amount of implantation amount. Therefore, the exothermic density of the length part arrange | positioned at the air flow direction downstream part in a defrost pipe heater is made equal to the defrost pipe heater of the evaporator of patent document 1, and is arrange | positioned similarly to the air flow direction upstream side part. By making the exothermic density of the length part to become higher than the defrost pipe heater of the evaporator of patent document 1, the calorific value from the length part arrange | positioned in the air flow direction upstream in a defrost pipe heater is made large, and the air flow direction upstream It is possible to shorten the defrost time of the frost attached to the plate fin on the side, and at the same time, the excess amount of heat generated from the length portion disposed on the downstream side in the air flow direction where the amount of frosting is small by the plate fin in the defrost pipe heater is suppressed. Therefore, the power consumption can be reduced.

On the other hand, in the pipe heater for defrosting, the length-part heat-generating density arrange | positioned in the air flow direction upstream part with a lot of implantation amount by a plate fin is made equal to the defrosting pipe heater of the evaporator of patent document 1, and it is the air flow direction downstream similarly. When the exothermic density of the length portion disposed on the side portion is lower than the defrosting pipe heater of the evaporator described in Patent Document 1, the defrost time of frost attached to the plate fin on the upstream side of the air flow direction changes with the evaporator of Patent Document 1. However, the plate fin in the defrosting pipe heater makes it possible to reduce the amount of heat generated from the length portion disposed on the downstream side in the air flow direction with a small amount of defrosting, and thus the amount of power consumption can be reduced.

Furthermore, the overall length of the defrost pipe heater as compared with the case where the defrost pipe heater is arranged such that the plate fin has more straight pipe portions in the air flow direction upstream portion having a large amount of frosting than in the air flow direction downstream portion having a small amount of frosting. Can be shortened, resulting in lower material costs.

According to the evaporator of 2), the heat generation density of the defrosting pipe heater is higher than the access portions at both ends in the middle portion in the longitudinal direction, so that the heat generation amount from both ends in the longitudinal direction of the defrosting pipe heater is connected to the heater wire and the lead wire. The heat generation amount can be set to prevent damage to the lead wire in the vicinity and damage to the silicone rubber disposed around the connector connecting the heater wire and the lead wire.

According to the evaporator of 3), it is possible to relatively easily make a defrosting pipe heater in which the exothermic density, which is the amount of heat generated per unit area of the pipe outer circumferential surface, is partially different in the longitudinal direction.

BRIEF DESCRIPTION OF THE DRAWINGS The front view which shows the whole structure of the evaporator of this invention.
FIG. 2 is a front view of the evaporator shown in FIG. 1. FIG.
3 is a left side view of the evaporator shown in FIG.
4 is a right side view of the evaporator shown in FIG.
Fig. 5 is a partially enlarged vertical sectional view of the main part of Fig. 4 cut out.
FIG. 6 is a front view in which a part showing a state before bending a defrost pipe heater used in the evaporator of FIG. 1 in a meandering shape is omitted. FIG.
7 is a partially enlarged cross-sectional view of FIG. 6.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described with reference to drawings.

In the following description, the top, bottom, left and right sides of FIGS. 1 and 2 will be referred to as up and down, left and right, and the surface surface side (right side of FIG. 3, left side of FIG. 4) of FIG. . 1 to 4 show the overall structure of the evaporator of the present invention, and FIG. 5 shows the structure of the main part thereof. 6 and 7 show the configuration of the defrost pipe heater used in the evaporator.

1 to 4, the evaporator 1 is composed of a plurality of aluminum plate fins 2 arranged in parallel in the left and right direction, and a plurality of fin groups spaced apart in the vertical direction (ventilation direction). (3) and the plurality of straight pipe portions 5 extending in the left and right directions fixed in the penetrating shape to the plate pins 2 of the respective pin groups 3 and two adjacent straight pipe portions 5 adjacent to each other, and further straight pipes. An aluminum heat exchanger tube 4 consisting of one bent tube portion 6 or 7 less than the portion 5, and a plurality of straight tube portions 9 and adjacent portions extending in the left and right direction in contact with the plate fin 2; The pipe heater 8 for defrosting which consists of two bent pipe | tube parts 11 and 12 smaller than the straight pipe | tube 9, and all the fin groups 3 It is provided with the aluminum side plate 13 (14) 14 arrange | positioned at the left-right direction outer side, As shown by the arrow X in FIG. Emitter is flowing upward.

The plate pin 2 has a rectangular flat plate shape long in the front-rear direction, and as shown in FIG. 5, two through-holes 15 are formed at the center in the height direction at intervals in the front-rear direction, and nodules in each corner portion. 16 is formed. And the indentation part for heater 17 in which the straight pipe part 9 of the defrost pipe heater 8 was penetrated by the nodule 16 of two adjacent plate fins 2 of the fin group 3 adjacent to each other up and down. ) Is formed.

The pin pitch between the plate fins 2 which the fin group 3 of the air flow direction downstream (upper side) adjoins is smaller than the pin pitch of the fin group 3 of the air flow direction upstream (lower side). In the illustrated example, the pin pitch between the plate pins 2 adjacent to the pin group 3 is largest as the pin group 3 at the lower end thereof and smaller toward the upper pin group 3.

The heat exchanger tube 4 is installed in two vertical planes spaced in the front-rear direction, spaced in the vertical direction, respectively, and further connected to the plurality of straight pipe portions 5 extending in the left-right direction and vertically adjacent to the vertical pipe portion 5. It consists of the 1st bend pipe part 6 which connects to left and right alternately between each other, and the 2nd bend pipe part 7 which connects the right part of the upper two straight pipe parts 5, and is connected. The straight pipe portion 5 of the heat exchange tube 4 passes through each through hole 15 of the plate fin 2 of the fin group 3 and is fixed to the plate fin 2.

The defrost pipe heater 8 is installed in two vertical planes spaced in the front-rear direction, and is provided with a plurality of straight pipe portions 9 which are spaced in the vertical direction, and extend in the left-right direction, and the straight pipe portions adjacent to each other vertically. (9) It is comprised by the 1st bend pipe part 11 which mutually connects left and right alternately, and the 2nd bend pipe part 12 which connects the left ends of the two lower straight pipe parts 9 with each other. The straight pipe portion 9 except for the lower straight pipe portion 9 of the defrost pipe heater 8 has a heater indentation composed of nodules 16 of two plate fins 2 adjacent to each other up and down of the fin group 3. It penetrates in the part 17, and the straight pipe part 9 is contact | abutted by the front and back both edges of the plate pin 2 by this. In addition, the lower end straight pipe part 9 of the defrost pipe heater 8 is penetrated into the lower nodule 16 in the plate fin 2 of the lower fin group 3, whereby the straight pipe part 9 is inserted. Is in contact with both edges of the front and rear of the plate pin (2). The right end part of the upper two straight pipe parts 9, ie, both ends of the defrost pipe heater 8, are bent downward, and a lead wire 23 is connected thereto.

6 and 7, the defrost pipe heater 8 includes a glass core wire 18, a heater wire 19 bent in a coil shape around the core wire 18, a core wire 18 and a heater. An electric insulator 21 covering the periphery of the wire 19 and connected to both ends of the aluminum pipe 22 and the heater wire 19 accommodating the core wire 18, the heater wire 19, and the electric insulator 21. It has the lead wire 23 for power feeding. The heater wire 19 and the lead wire 23 are connected by connectors (not shown) disposed in both ends of the pipe 22, and the connector circumference is covered by the silicone rubber 24. Part of the silicone rubber 24 protrudes outside the pipe 22.

In the defrosting pipe heater 8, the heat generation density, which is a calorific value per unit area of the outer peripheral surface of the pipe 22, is partially different in the longitudinal direction of the defrosting pipe heater 8, and is represented by an intermediate portion indicated by the range R1 in FIG. The exothermic density of 8a) is higher than the exothermic density of the both-side access part 8b shown by range R2. Here, the winding pitch P1 of the heater wire 19 of the intermediate | middle part 8a shown by the range Rl in the defrost pipe heater 8 of the heater wire 19 of the both ends approaching part 8b which shows the range R2 is shown. By making it smaller than the winding pitch P2, the heat generation density of the middle part 8a in the defrost pipe heater 8 becomes higher than the heat generation density of the both-end access part 8b. The length of the middle part 8a of the defrost pipe heater 8 is such that the middle part 8a is present in the height part from the lower end (air flow direction upstream end) to one third of the total length of the evaporator 1. The length to say is preferable.

The left side plate 13 has a longitudinal through hole passing through the first end of the heat exchanger tube 4 and the left end of the straight tube portion 5 adjacent to the upper and lower sides connected by the first bent tube portion 6 ( 25 and the nodule 26 are formed by fitting the left end part of each straight pipe part 9 of the defrost pipe heater 8. Longitudinal through-hole passing through the right end part of the 1st bent pipe part 6 of the heat exchanger tube 4, and the up-and-down adjacent straight pipe part 5 connected by each 1st bent pipe part 6 to the right side plate 14. (25), a horizontally through hole 27 passing through the right end portion of the straight pipe portion 5 adjacent to the front and rear adjacently connected by the second curved tube portion 7 and the second curved tube portion 7 of the heat exchange tube 4, And the nodule 26 which penetrates the right end part of each straight pipe part 9 of the defrost pipe heater 8 is formed.

The evaporator 1 constitutes a refrigeration cycle with a compressor and a condenser. This refrigeration cycle is arranged in the adiabatic body of the refrigeration unit.

In the evaporator (1), the refrigerant flows into the heat pipe (4) at the lower rear side and flows through the heat exchange tube (4), and heat exchanges with air flowing from the bottom to the air as indicated by the arrow X in FIG. 4) It flows out from the front side straight pipe | tube part 5 of a lower end.

In each of the plate pins 2, implantation occurs in the vicinity of the peripheral portion of the through hole 15 through which the straight pipe portion 5 penetrates. The amount of frost attached to the plate fin 2 increases on the upstream side (lower side) in the air flow direction, and tends to decrease on the downstream side (upper side) in the air flow direction. However, since the heat generation density of the intermediate part 8a located in the air flow direction upstream in the defrost pipe heater 8 is higher than the heat generation density of the both end access parts 8b located in the air flow direction downstream, the amount of implantation The amount of heat generated from the middle portion 8a of the defrosting pipe heater 8 that is in contact with the plate fin 2 on the upstream side of many air flow directions is increased, and the plate on the air flow direction downstream side where the amount of implantation is small is equally small. The amount of heat generated from the both end access portions 8b in contact with the pin 2 can be reduced. Therefore, the defrost time of the frost attached to the plate fin 2 is shortened on the upstream side of the air flow direction, and the amount of heat generated from the both end access portions 8b of the defrost pipe heater 8 is suppressed. It is possible to reduce the amount of power consumed, or to prevent the defrost time of the frost attached to the plate fin 2 from extending upstream in the air flow direction, and the access portions 8b at both ends of the defrost pipe heater 8. The amount of heat generated from) can be reduced. As a result, the amount of power consumption is reduced in any case.

Furthermore, the amount of heat generated from the longitudinal ends of the defrost pipe heater 8 is damaged by the lead wire 23 near the connector connecting the heater wire 19 and the lead wire 23, and the heater wire 19 and the lead wire 23. The amount of heat generated can be set so as to prevent damage to the silicone rubber 24 disposed around the connector for connecting the connector.

In the said embodiment, although the pin pitch between the plate pins which the fin group of an air flow direction downstream (upper side) adjoins is smaller than the pin pitch of the fin group of an air flow direction upstream (lower side), it is limited to this. Instead, the pin pitches of all pin groups may be the same.

Industrial Applicability

The evaporator according to the present invention is suitably used for a refrigeration cycle used in refrigeration and refrigeration apparatus such as a refrigerator, a refrigerated showcase, a freezer, a refrigerated showcase and the like.

1: evaporator
2: plate pin
3: pin group
4: heat exchanger tube
5: straight pipe
6, 7: flexion tube
8: defrost pipe heater
9: straight pipe
11 12: Bend tube
19: heater wire
22: pipe
23: lead wire for power supply

Claims (5)

The heat exchanger tube and the plate fin which are connected to a plurality of plate fins and plate fins arranged in parallel shape and a plurality of straight pipe portions provided in a penetrating shape and two adjacent straight pipe portions, and which have one bent pipe portion smaller than the straight pipe portion. The defrost pipe heater which connects the several straight pipe | tube part which contacted and two adjacent straight pipe | tube parts, and consists of one bending pipe | tube part less than a straight pipe | tube part, and a defrost pipe heater is a pipe which accommodates a heater wire and a heater wire. And an evaporator having a feeder lead wire connected to both ends of the heater wire,
The evaporator in which the heat generation density which is the heat generation amount per unit area of the pipe outer peripheral surface in the defrost pipe heater differs in the longitudinal direction of the defrost pipe heater. The evaporator of Claim 1 in which the exothermic density of the defrost pipe heater is higher than the access part of both ends in the middle part of a longitudinal direction. The evaporator of Claim 1 in which the heater wire of a defrost pipe heater is coil shape, and the pitch of the part with high heat generation density is smaller than the pitch of the low part. The evaporator of claim 1, wherein an intermediate portion of the defrost pipe heater is disposed above the wind. The evaporator of Claim 1 in which a part of intermediate part of a defrost pipe heater is arrange | positioned upstream rather than the straight part of the heat exchanger tube located in the uppermost wind side.

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