DE10202496A1 - Method and tool for mounting a capillary line in an evaporator board and evaporator board produced therewith - Google Patents

Abstract

The invention relates to a splaying tool for mounting a capillary tube (7) in a plate-type evaporator (1), said tool comprising an inner pin (12) and an outer pin (11) which is guided in a sliding manner in a channel (13) of the inner pin (12). During the mounting of a capillary line (7) in a plate-type evaporator (1), the inner pin (12) is guided into a section (2) of a connecting line of the plate-type evaporator (1), and the outer pin (11) is guided via the channel (13) of the inner pin (12) into a capillary channel (6) of the plate-type evaporator (1), in order to splay the same. Both pins (11, 12) are flattened on one side in order to distribute the pressure acting on one of the two plates of the plate-type evaporator during the expansion of the same, as widely as possible over the surface of said plate, thus avoiding any deformation of said plate. The capillary line (7) is guided into the splayed capillary channel (6), and said capillary channel (6) is embossed with the capillary line (7) guided therein.

Description

The present invention relates to the assembly of a capillary in a Evaporator board, a tool suitable for this purpose and one with the method and / or evaporator board manufactured with the tool.

Evaporator boards for refrigeration devices, in particular so-called coldwall evaporators, are traditionally made by using two sheets of different thickness to be attached to each other over a large area, although those areas of the metal sheets which should form a refrigerant line of the evaporator, remain disconnected. By Pressing a fluid between the two plates becomes the unconnected areas spread apart from each other and so opened the refrigerant line, the result of different thicknesses of the two sheets practically the stronger of the two sheets remains undeformed. The fact that the thicker sheet remains flat is essential for the practical usability of the Evaporator of great importance, because in order to achieve effective cooling, this sheet is glued to the entire outside of a refrigerator inner container can be. Bumps in the sheet would cause between it and air chambers are enclosed in the inner container. These would Interference with the heat exchange between the interior of the refrigerator and the evaporator and thus lead to an increased power consumption of the refrigerator.

A supply line and a suction line for the refrigerant must be connected to the evaporator. Conventionally, the supply line is a capillary line, which is led inside the suction line before entering the evaporator in order to achieve a pre-cooling of the liquefied refrigerant supplied in the capillary line by thermal contact with the evacuated, evaporated refrigerant. In order to connect these two lines, a connecting line section 2 is usually provided on an evaporator 1, as shown in a perspective view in FIG. 1, which extends from a side edge into the interior of the evaporator 1 and whose cross section is dimensioned such that a suction line 4 is therein can be inserted and hermetically sealed. At the inner end of the connecting line section 2 , a conical section 3 adjoins in a straight line continuation, which finally merges into a capillary channel 6 , the cross section of which is adapted to insert and fasten the capillary supply line 7 guided through the suction line 4 therein. Beyond the capillary channel 6 , the cross section of the refrigerant line 5 of the evaporator 1 widens again. It extends in a meandering manner over the entire surface of the evaporator 1 and finally meets the connecting line section 2 at the transition to the conical section 3 .

Simply by injecting a fluid, the clear width of the connecting line section 2 and the capillary channel 6 , which is necessary for inserting the suction line 4 or the supply line 7 , cannot be achieved. In order to achieve the required clear width, expanding mandrels are known to be used, which are inserted from the outside into the connecting line section 2 in order to expand this or the capillary channel 6 to the desired cross section.

In the case of the conventional expanding mandrels, it cannot be ruled out that the expansion also leads to a deformation of the thicker plate 8 under the two plates 8 , 9 of the evaporator 1 . The consequence of such a deformation is that the evaporator 1 can no longer be glued to the entire surface of an inner container of the refrigerator; this must be avoided. Since this is not possible reliably to the conventional expansion plugs, is conventionally engraved a recess prior to expansion in the increased plate 8 in the region of the connection pipe portion 2 and the capillary channel 6, whose depth is conventionally approximately 0.8 mm, which is greater than one at the Widening of the connecting line section 2 or of the capillary channel 6 bulging of the thicker plate 8 to be expected. This ensures that the bulge does not protrude beyond the non-embossed part of the surface of the plate 8 , so that the plate 8 can be largely glued over the entire surface despite the deformation.

With this technology there is an efficient heat exchange between the evaporator and the interior of a refrigerator, but the technology has become one other, unexpected reasons, were found to be not entirely satisfactory. Because there the depression created by embossing on the evaporator even after the Evaporator usually open to the edge, moisture can enter the recess penetrate and condense in it. Every time the vaporizer is operated the moisture freezes and the resulting ice spreads the evaporator away from it Refrigerator inner container. This increases the volume in which Moisture can penetrate over time, which eventually results in a large area Detachment of the evaporator from the inner container and thus to a bad one Cooling performance.

Another problem with the flaring of the connecting line section 32 and the capillary channel 6 is that the risk of damage, e.g. B. in the form of an opening of one of the two plates 8 , 9 , which makes the entire evaporator unusable.

Burrs that may arise during thinning disturb the flow of the coolant and cause unwanted noise.

The object of the present invention is a method for assembling a capillary line in an evaporator, a tool for this purpose and an evaporator board to indicate the degree of unevenness on the thicker plate of the Evaporator, which ensures thermal contact between this plate and a refrigerator Inner containers can degrade, minimizing the reject rate over the course of the Assembly and to minimize the noise during operation of the evaporator.

These objects are achieved by a method with the feature of claim 1. a tool with the features of claim 11 and an evaporator board with the Features of claim 14.

By, when inserting the mandrel, its flat side surface in contact with a first Plate of the evaporator is guided, the force acting on insertion is achieved is distributed on this first plate over the entire surface of the flat side surface, while the surface on which the force acts on the opposite second plate has a vanishing width. The pressure applied to the contact surface of the tool the second plate acts, is therefore much larger than on the contact surface of the first Plate, so that the resulting deformation on the first plate is negligible.

Two different tools can be used, which are introduced one after the other and be pulled out again to the connection line cut and the Widen capillary channel. The order in which these tools are used is arbitrary.

With the help of a combined tool in particular, simultaneous expansion is also possible connection lead and capillary channel possible. Such a tool can be formed in one piece, with one starting from the tip of the first mandrel second thorn.

In a preferred embodiment of the tool, the second mandrel is displaceable in guided a channel of the first mandrel. With such a tool it is possible first to widen the connection line section and then without the first mandrel pull out, through the channel insert the second mandrel into the capillary channel. The channel of the first mandrel ensures exact guidance of the second, which is the Risk of the second mandrel breaking out, leading to excessive deformation, Burr formation or destruction of a plate could be minimized.

The capillary channel is stamped with the capillary line inserted into it preferably with the aid of a pair of punch and die, the die having two grooves embossed on both sides of the capillary line in the flat plate of the evaporator.

To ensure a material connection between the capillary line and the Manufacture evaporator, the stamping is preferably under the action of heat and / or Ultrasound performed.

Further features and advantages of the invention result from the following Description of exemplary embodiments with reference to the accompanying figures. Show it:

Figure 1, already discussed, is a perspective view of a roll bond evaporator plate.

FIG. 2 is a perspective view of a set of expansion tools for mounting a capillary line and a suction line on the evaporator of FIG. 1;

Fig. 3 is a one-piece combined expansion tool;

Fig. 4 is a combined expansion tool with mutually displaceable mandrels;

Figure 5 is a schematic section through the evaporator embossed in the region of the capillary channel as well as by a punch and a die for performing the embossing.

Fig. 6 is a perspective view of a modified expansion tool; and

Fig. 7 is a section through the connecting region of a machined with the tool of FIG. 6 evaporator plate.

Fig. 2 shows a perspective view of a set of two expansion tools with spikes 11 and 12 , which can be inserted into a connecting line section or a capillary channel of an evaporator board in order to expand it appropriately for receiving a suction line or a capillary line.

The first mandrel 11 is a rigid metal pin with a tapered tip 16 and a body of essentially cylindrical shape, into which a flat side surface 17 is milled on one side. The side surface 17 extends up to a shoulder 18 over a length which corresponds to the desired depth of penetration of the mandrel 11 into the connecting line section 2 of the evaporator 1 . The shape of the second mandrel 12 is largely analog, an essentially cylindrical body with a conical tip 14 and a flat side surface 15 . Its diameter is approximately 2 mm. These two mandrels are provided in order to be successively introduced into the connecting line section 2 of the evaporator shown in FIG. 1 and thus to widen the connecting line section 2 and the capillary channel 6 in two steps.

FIG. 3 shows a combined expansion tool which can be regarded as a rigid connection between the two mandrels 11 and 12 , the narrower second mandrel 12 extending in the same direction as the latter, starting from the tip of the wider mandrel. This tool allows the connection line section 2 and the capillary channel 6 to be widened in one operation. The length of the second mandrel 12 and that of the connecting line section determine whether the capillary channel 6 , first the connecting line section 2 or both are expanded at the same time.

The combined expansion tool shown in a perspective view in FIG. 4 comprises an inner mandrel 12 which is provided for expanding the capillary channel 6 of the evaporator plate and which is displaceably guided in a channel 13 of an outer mandrel 11 .

Details of the mandrels 11 , 12 , which are also based on the exemplary embodiments of FIGS. 2 and 3 are realized, are designated in FIG. 4 with the same reference numerals and are not described again. The inner mandrel 12 is guided in a bore in the outer mandrel 11 , which merges into an open-ended channel 13 on the side surface 17 . The side surface 15 of the inner mandrel 12 lies in this channel 13 in one plane with the side surface 17 of the outer mandrel 11 .

In order to assemble the suction line 4 and the capillary line 7 with the aid of this tool, the outer mandrel 11 is first inserted into the connecting line section 2, which has already been partially expanded by injecting fluid. The mandrel 11 is oriented such that its flat side surface 17 rests on the thicker plate 8 of the evaporator, which is not to be deformed. The force exerted by the mandrel 11 when expanding onto the two plates 8 , 9 is thus distributed on the side facing the thicker plate 8 over the entire extent of the side surface 15 , so that a significantly smaller pressure acts on the plate 8 than on the opposite one. weaker plate 9 , which touches the round outside of the mandrel 12 only tangentially. In this way, the flatness of the plate 8 is retained during the widening, without first having to emboss a recess, as was previously the case.

As soon as the shoulder 18 , which forms the end of the side surface 17 of the outer mandrel 11 , abuts the edge of the connecting line section 2 , the outer mandrel 11 has reached the required depth of penetration. Now the inner mandrel 12 is driven through the channel 13 of the outer mandrel 11 , which in this way is guided directly into the capillary channel 6 . During the expansion of the capillary channel 6 , the outer mandrel 11 remains in its position in the suction connection 2 . In this way, it is impossible for the inner mandrel 12 to break out sideways in the connecting line section 2 under the action of a longitudinal driving force, thereby bending and piercing or otherwise damaging one of the plates 8 or 9 of the evaporator 1 .

After the expansion, the supply line 7 and the suction line 8 are inserted into the capillary channel 6 and the connecting line section 2 and fastened therein. The supply line is attached by stamping using a stamp and a die; in the suction line 8 it can, for. B. done by soldering.

FIG. 5 shows a perspective sectional view of this stamp 20 and the die 21 in the course of a movement apart after stamping, as well as a section through the evaporator board 1 at the level of the stamped capillary channel 6 . The punch 20 and / or die 21 are equipped with a heating device (not shown) which serves to melt an aluminum layer between the plates 8 , 9 and the capillary line 7 and to connect the latter so tightly to the plates 8 , 9 . Instead of the heating device, a sonotrode for ultrasonic welding can also be provided. The punch 20 has an elongated groove 22 of essentially semi-cylindrical shape, parallel to which two ribs 23 extend over the surface of the die 21 . The shape of the groove 22 and the ribs 23 are determined such that after the stamping the two plates 8 , 9 tightly enclose the supply line 7 over its entire circumference. The two sharp-edged ribs 23 already press two parallel shafts 25 into the thicker plate 8 in an early phase of the stamping process, which fix the position of the supply line 7 and prevent undesired deformation of its cross section during stamping.

The resulting recesses 24 on the outer surface of the plate 8 do not affect the behavior and the stability of the evaporator 1 , because their surface is too small to impair the heat exchange between the evaporator and an internal refrigerator with which the evaporator sticks is, and since they do not extend to the edge of the evaporator board, no moisture can penetrate into it, which could lead to detachment of the evaporator 1 .

FIG. 6 shows a perspective view of an expansion tool, which represents a modified embodiment of the tool from FIG. 4. The outer mandrel 11 has between its tapered tip 16 and a conical shoulder 27 a cylindrical section 28 , the diameter of which is smaller than the outside diameter of the suction line 4 to be mounted in the connecting line section 2 . The diameter of the section 28 can even be so small that it can be inserted into the connecting line section which is widened solely by injecting fluid, without additionally deforming it. The shape of the conical tip 16 corresponds to that of the conical line section 3 . When this modified tool is introduced, the connecting line section 2 is not expanded over its entire length, but, as shown in FIG. 7, a shoulder 29 complementary to the shoulder 27 is created in the connecting line section 22 . This serves as a stop for the suction line 4 . This can therefore be pushed into the connecting line section 2 without having to measure its penetration depth up to the stop formed by the shoulder 29 , without there being the risk that the suction line 4 enters the connecting line section 2 between the shoulder 29 and the conical section 3 outflow refrigerant line 5 blocked.

Claims (14)

1. A method for mounting a capillary line ( 7 ) in an evaporator board ( 1 ), comprising the steps: a) inserting a first mandrel ( 11 ) into a connecting line section ( 2 ) of the evaporator board ( 1 ); b) inserting a second mandrel ( 12 ) through the connecting line section ( 2 ) into a capillary channel ( 6 ) of the evaporator board ( 1 ) c) widening the capillary channel ( 6 ) with the aid of the second mandrel ( 12 ); d) inserting the capillary line ( 7 ) into the expanded capillary channel ( 6 ); e) stamping the capillary channel ( 6 ); characterized in that in step a) and / or b) the mandrel ( 11 , 12 ) has a flat side surface ( 17 , 15 ), and in that the flat side surface ( 17 , 15 ) in contact with a flat plate ( 8 ) of the Evaporator ( 1 ) is performed. 2. The method according to claim 1, characterized in that step b) before Step a) is carried out. 3. The method according to claim 2, characterized in that the second mandrel ( 12 ) is removed from the connecting line section ( 2 ) before performing step a). 4. The method according to claim 1, characterized in that steps a) and b) be carried out at the same time. 5. The method according to claim 1, characterized in that step a) before step b) is carried out. 6. The method according to claim 5, characterized in that the first mandrel ( 11 ) is removed from the connecting line section ( 2 ) before performing step b).
Method according to claim 3 or 4, characterized in that step b) is carried out by passing the second mandrel ( 12 ) through a channel ( 13 ) of the first mandrel ( 11 ). 7. The method according to any one of the preceding claims, characterized in that the connecting line section ( 2 ) is expanded with the aid of the first mandrel ( 11 ). 8. The method according to any one of the preceding claims, characterized in that the stamping is carried out with the aid of a pair of punches ( 20 ) and die ( 21 ), the die ( 21 ) having two groove-shaped depressions ( 26 ) on both sides of the capillary line ( 7 ) into the flat plate ( 8 ) of the evaporator ( 1 ). 9. The method according to any one of the preceding claims, characterized in that that embossing under the influence of heat and / or ultrasound is carried out. 10. expansion tool for the assembly of a capillary line ( 7 ) in an evaporator board ( 1 ), in particular according to a method according to one of the preceding claims, with at least one mandrel ( 11 , 12 ) for insertion into the evaporator board ( 1 ), characterized in that the mandrel ( 11 , 12 ) has a cross section in the form of a segment of a circle. 11. Expansion tool according to claim 10, characterized in that it further comprises a further mandrel ( 12 , 11 ), the narrower of the two mandrels ( 12 ) starting from the tip of the wider mandrel ( 11 ). 12. Expansion tool according to claim 10, characterized in that it further comprises a further mandrel ( 12 , 11 ), wherein a first ( 11 ) of the two mandrels has a channel ( 13 ) in which the second mandrel ( 12 ) is slidably guided , 13. Expansion tool according to one of claims 10 to 12, characterized in that the channel ( 13 ) runs on a flat surface ( 17 ) of the first mandrel ( 11 ). 14. Evaporator board, produced by the method according to one of claims 1 to 9 or using the tool according to one of claims 10 to 13, with a flat plate ( 8 ) and a plate ( 9 ) in which the capillary channel ( 6 ) and a refrigerant pipe are formed.