DE20310064U1 - Filter assembly for coolant liquid has housing with insert of smaller diameter than housing inner surface increasing fluid access surface - Google Patents

Abstract

A liquid coolant filter has an airtight housing (20) with an inlet (21) and an outlet (22) with two interior perforated plates (40, 54) either side of filter pads (30, 53) located astride a filter insert (50). The insert holds a quantity of filter drying grains (52). The stacked inner components are held in place by a coiled spring (60). The insert outer wall diameter is less than the housing (20) inner wall diameter, creating a side-channel through which the coolant has access to the filter chamber. The insert (50) has a cylindrical recess (51). Alternatively, the coolant inlet and outlet are located on the same side of the housing.

Description

Coolant filter device

This invention relates primarily to increasing the space for coolant flow in a coolant filter device. The engineering design of this device is intended to help increase the flow rate of coolant in the filter while extending the life of the filter.

The technology of a conventional filter system is illustrated in Figures 1 and 2. In an airtight vessel 10 there is a coolant inlet 11 and an outlet 12. Inside the vessel there are two iron grids 14 lined with a filter cloth 13, which divide the filter space in such a way that a desiccant 15 can be added between the two iron grids. Since the first iron grid 14 together with the filter cloth 13 completely separates the interior of the filter space in one plane, the coolant can only enter the filter directly through the filter cloth 13. This can easily lead to impurities remaining on the filter cloth 13 and preventing the coolant from flowing through unhindered. As a result

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the flow rate can decrease very quickly. The filter cloth must then be replaced very quickly, so its service life is very short; in addition, if the filter becomes blocked and the flow rate is insufficient, the entire circulation system can be damaged if the filter cloth 13 is not replaced quickly enough. This in turn would lead to further unnecessary damage and losses.

The main aim of the invention is to provide a system that increases the space for the inflow of the coolant and thus reduces the clogging of the filter space in order to extend the service life, i.e. the service life, of the entire filter. The aim of the invention is also to create a larger inflow and outflow for the coolant and, furthermore, to increase the circulation rate and the flow rate so that the entire circulation system has a better utilization rate.

Fig. 1: a perspective view of a conventional filter.

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Fig. 2: Cross-sectional view of a conventional filter. Fig. 3: A perspective, exploded view of the device according to the invention

Fig. 4: a cross-sectional view of the device according to the invention and

Fig. 5: a cross-sectional view of a second embodiment of the device according to the invention.

In Fig. 3, an airtight vessel 20 with a coolant inlet 21 and outlet 22 is shown. Directly connected to the outlet 22 is an iron grid 40, on the edge of which is a ring 41. This ring 41 serves to fix the iron grid 40 to the inner wall of the airtight vessel 20. In the middle of the iron grid 40 there are holes 42. The filter cloth 30 is followed by a filter pan 50, which has an opening on one side and is smaller in diameter than the airtight vessel 20. This filter pan 50 forms a flow path A with the inner wall of the airtight vessel 20. The desiccant 52 can be added to this filter pan behind an inner wall in the lower part, then on the second

Opening another filter cloth 53 with an iron grid 54, which closes off the filter pan. These in turn are connected to an elastic spiral 60. This in turn forms a solid unit with the hermetically sealed inlet 21. In addition, at the lower end of the filter pan 50 facing the filter cloth 30 there is a cylindrical cavity 51 recessed in the bottom of the filter pan 50 in the direction of the filter cloth. Due to the shape of the cavity 51 (see Fig. 3), the area through which the coolant can escape is larger. In Fig. 4 you can see the flow path A, which runs between the filter barrel and the inner wall of the vessel 20. After entering through the inlet 21 of the vessel 20, as symbolized by the arrow drawn in, the coolant can pass through the iron grid 547, which lies together with the filter cloth on the opening of the filter pan 50, into this filter pan 50 and the desiccant 52 stored therein.

At the same time, however, it can also flow along the flow path A and then penetrate through the side holes of the filter pan 50 and come into contact with the desiccant 52. This increases the flow rate at which the coolant penetrates into the filter chamber. At the same time, the speed at which

the coolant to exit again through the cavity 51. In addition, the coolant must first flow through the iron grid 40 together with the filter cloth 30, which are located at the lower end, before it can completely exit through the outlet 22 of the vessel 20. With the above-described technique of this invention, both the speed at which the coolant flows into the filter chamber and the speed at which the coolant flows out can be increased, and thereby the overall flow rate at which the coolant flows through the filter is increased. This makes the entire cooling circulation system more efficient and thus prevents machine failure. In addition, the housing path A increases the space through which the coolant can penetrate into the filter pan 50. As a result, the deposits on the filter cloth 53, which is located above the upper part of the flow pan 50, are significantly reduced, thereby extending the service life of the filter.

In Fig. 5, the second embodiment of the device according to the invention is also shown in cross section. Here, a reflux chamber 25 is located in the lower part of the airtight vessel 20 and under the iron grid 40. The coolant enters the interior through the

Inlet 21, from which a pipe 23, which is surrounded and controlled by a spiral 60, leads into the interior of the vessel. There is also another pipe 24 which leads from the reflux chamber 25 through the filter pan 50 and the iron grid 40 to the outlet 22. Once the coolant has penetrated into the vessel, it can penetrate into the filter chamber through the iron grid 54 and the associated filter cloth 53, which are located on the filter pan 50. But it can also penetrate into the filter chamber here via the flow path A and then through the side holes of the filter pan 50. In addition, the coolant can then escape through the cavity 51 at the bottom of the filter pan 50. Due to the shape of the cavity 51, the area through which the coolant can escape is larger. The coolant then penetrates the iron grid 40 together with the associated filter cloth 30 before it reaches the return flow chamber 25 and from there flows out through the outlet pipe 24 to the outlet 22.

Claims (3)

1. A coolant filter device comprising an airtight vessel ( 20 ) with an inlet ( 21 ) and an outlet ( 22 ), wherein two iron grids ( 40 ), ( 54 ) are provided, each covered with a filter cloth ( 30 ), ( 53 ), and which divide the filter space in such a way that a desiccant ( 52 ) can be filled in between, wherein a spiral ( 60 ) is further provided which fixes the system, wherein the diameter of the filter pan ( 50 ) is smaller than that of the airtight vessel ( 20 ), so that a flow path (A) is created between the filter pan ( 50 ) and the inner wall of the airtight vessel ( 20 ), whereby the area through which the coolant can penetrate into the filter space is increased. 2. Coolant filter device according to claim 1, characterized in that a cylindrical cavity ( 51 ) recessed towards the filter cloth ( 53 ) is formed at the lower end of the filter pan ( 50 ) facing the filter cloth ( 30 ). 3. Coolant filter device according to one of claims 1 or 2, characterized in that a return flow space ( 25 ) is provided between the bottom of the airtight vessel ( 20 ) and the iron grid ( 40 ), wherein an inlet pipe ( 23 ) is arranged inside at the inlet ( 21 ), wherein there is also an outlet pipe ( 24 ) which extends between the return flow space ( 25 ) under the iron grid ( 40 ) and the outlet ( 22 ) through the filter pan ( 50 ), so that the coolant, after it has flowed through the filter pan ( 50 ), exits again from the return flow space ( 25 ) through the outlet pipe ( 24 ), so that the inlet and outlet are located on the same side of the coolant device.