JP6176151B2 - Oil strainer - Google Patents

Description

  The present invention relates to an oil strainer.

In the internal combustion engine disclosed in Patent Document 1, when the oil pump is driven, the oil in the oil pan is sucked into the oil pump via the oil strainer connected to the pump. The oil strainer is formed with a channel through which the sucked oil flows. The oil strainer flow path is provided with a filter for removing foreign matter from the oil flowing through the flow path.

JP 2012-163075 A

  By the way, when the condensed water contained in the oil of the engine becomes ice while the internal combustion engine is stopped in a cold region or the like, the ice contained in the oil accumulates in the filter after the operation of the internal combustion engine starts, thereby clogging the filter. This may make it difficult for oil to flow.

  An object of the present invention is to provide an oil strainer that can prevent a filter provided in a flow path for flowing sucked oil from being clogged by ice.

Hereinafter, means for solving the above-described problems and the effects thereof will be described.
An oil strainer that solves the above problems is provided with a filter in a flow path through which the sucked oil flows. A bent portion is formed in the upstream portion of the filter in the flow path by curving that portion. In addition, a separation net that captures foreign matter in the oil strainer so as to prevent foreign matter in the oil from flowing downstream separates the outer portion of the bent portion from the inner portion of the bend. Is provided. When the oil flowing through the flow path contains ice, when the oil passes through the bent portion of the flow path, the ice in the oil gathers in the bent outer portion of the bent portion by centrifugal force, while the bent portion Oil that does not contain ice flows toward the downstream in the inner part of the bend. Since the ice collected in the bent outer portion of the bent portion is accumulated in the separation net and is prevented from flowing downstream, the ice is prevented from flowing to the filter downstream of the bent portion together with oil. Therefore, the filter can be prevented from being clogged with ice in the oil.

Schematic showing oil strainer. The expanded sectional view which shows the collection net | network of an oil strainer. The schematic which shows the accumulation state of the ice in the flow path of an oil strainer. The expanded sectional view which shows the collection net | network of the state which accumulated ice. The schematic diagram which shows the accumulation state of the ice in the flow path of an oil strainer when a collection net | network is not provided. The schematic diagram which shows the other example of the collection net | network and suction inlet in an oil strainer. Schematic which shows the other example of the collection net | network in an oil strainer.

Hereinafter, an embodiment of an oil strainer will be described with reference to FIGS.
As shown in FIG. 1, the oil strainer 1 is connected to an oil pump 2 of an internal combustion engine. The upstream end of the oil strainer 1 is formed with a suction port 1a that increases in diameter toward the upstream end (lower end in the figure). The suction port 1 a is located in the oil pan 3 of the internal combustion engine and communicates with a flow path 4 formed in the oil strainer 1.

  When the oil pump 2 is driven, the oil in the oil pan 3 is sucked into the flow path 4 in the oil strainer 1 from the suction port 1a, and then passes through the flow path 4 to the downstream side (oil pump 2 side). ). The oil pump 2 discharges the oil sucked from the oil strainer 1 toward various parts of the internal combustion engine. The oil discharged from the oil pump 2 is sent to various parts of the internal combustion engine and lubricated, and then returns to the oil pan 3.

  The oil strainer 1 includes a bent portion 5 formed by bending the flow path 4 and a filter 7 provided downstream of the bent portion 5 in the flow path 4. The filter 7 is for removing foreign substances from the oil flowing through the flow path 4. In addition, the oil strainer 1 is provided with a collection net 6 as a separation net that separates the bent outer portion and the bent inner portion of the bent portion 5. The collection net 6 approaches the inner wall of the bent outer portion of the bent portion 5 toward the downstream of the flow path 4, and is connected to the inner wall in the vicinity of the filter 7 in the flow path 4. The collection net 6 captures foreign matter in the oil so that the foreign matter in the oil does not flow downstream.

  FIG. 2 is an enlarged cross-sectional view of the collection net 6. As can be seen from this figure, the bent outer side (right side in FIG. 2) and the inner bent side (left side in FIG. 2) of the bent part 5 in FIG. The plurality of holes 8 are communicated with each other. The inner diameter Da of the open end 8a of the bent portion 5 on the outer side (right side in FIG. 2) of the bent portion 8 is smaller than the inner diameter Db of the open end 8b of the bent inner portion (left side in FIG. 2). Has been. For this reason, the opening area of the opening end 8a is smaller than the opening area of the opening end 8b. In addition, the part between the opening end 8a and the opening end 8b in the internal peripheral surface of the hole 8 is formed in the taper shape which spreads so that it goes to the opening end 8b from the opening end 8a.

Next, the operation of the oil strainer 1 will be described.
As shown in FIG. 3, when the oil pump 2 is driven, the oil in the oil pan 3 is sucked into the oil strainer 1 from the suction port 1a. Thereafter, the oil flows through the flow path 4 in the oil strainer 1 to the downstream side. When this oil contains ice A, when the oil passes through the bent portion 5 of the flow path 4, the ice A in the oil gathers at the outer portion of the bent portion 5 due to centrifugal force. Oil that does not contain ice A flows toward the downstream in the portion inside the bend in the portion 5. Since the ice A collected in the bent outer portion of the bent portion 5 accumulates in the collection net 6 and is prevented from flowing downstream, the ice A is prevented from flowing to the filter 7 downstream of the bent portion 5 together with oil. The

  FIG. 4 shows a state where ice A has accumulated in the collection net 6. In the hole 8 of the collection net 6, the inner diameter Db of the opening end 8 b opposite to the opening end 8 a is larger than the inner diameter Da of the opening end 8 a on which the ice A is accumulated. For this reason, the opening area of the opening end 8b becomes larger than the opening area of the opening end 8a, and the oil easily flows from the opening end 8a side of the hole 8 in the collection net 6 to the opening end 8b side. Further, since the inner peripheral surface of the hole 8 is formed in a tapered state that expands from the opening end 8a side toward the opening end 8b side, the oil flows smoothly from the opening end 8a side to the opening end 8b side. It also becomes. As a result, while the ice A in the oil is captured by the collection network 6, the oil can flow downstream from the portion of the collection network 6 where the ice A accumulates through the hole 8.

  FIG. 5 shows an accumulation state of ice A in the flow path 4 of the oil strainer 1 when the collection net 6 is not provided. In this case, ice A accumulates in the entire filter 7 provided in the flow path 4 of the oil strainer 1, and the filter 7 is clogged by the accumulated ice A, thereby preventing the oil flow in the flow path 4. However, by providing the above-described collection network 6 in the bent portion 5 upstream of the filter 7 in the flow path 4, the collection network 6 can capture the ice A in the oil and prevent it from flowing downstream. it can. For this reason, the ice A does not collect on the filter 7.

According to the embodiment described in detail above, the following effects can be obtained.
(1) When the condensed water contained in the oil of the engine becomes ice while the internal combustion engine is stopped in a cold region or the like, the oil in the oil pan 3 enters the oil strainer 1 together with the ice after the operation of the internal combustion engine is started. Inhaled. However, a trapping net 6 is provided in the bent portion 5 upstream of the filter 7 provided in the flow path 4 of the oil strainer 1, and the ice in the oil is captured by the trapping net 6 and flows downstream. Therefore, it is possible to prevent clogging due to accumulation of ice in the filter 7.

  (2) Since the opening area of the opening end 8b in the hole 8 of the collection net 6 is larger than the opening area of the opening end 8a, oil is transferred downstream from the portion where ice is accumulated in the collection net 6 through the hole 8. Can be made easier to flow.

  (3) Since the inner peripheral surface of the hole 8 is formed in a tapered state that expands from the opening end 8a side to the opening end 8b side, oil can smoothly flow from the opening end 8a side to the opening end 8b side. Can do.

In addition, the said embodiment can also be changed as follows, for example.
-About the inner peripheral surface of the hole 8 of the collection net | network 6, it is not necessary to make it the taper shape which expands toward the opening end 8b from the opening end 8a.

In the hole 8 of the collection net 6, the inner diameter Db of the opening end 8b is not necessarily larger than the inner diameter Da of the opening end 8a.
The filter 7 of the flow path 4 is not necessarily provided so as to be in contact with the downstream end of the collection network 6, and may be provided away from the downstream end of the collection network 6 toward the downstream side.

  As shown in FIG. 6, a wall 9 for closing the portion corresponding to the inner portion of the bent portion 5 in the suction port 1a of the oil strainer 1 (the portion on the left side in the drawing) is formed. Moreover, the upstream end (lower end in the figure) of the collection network 6 is positioned in the vicinity of the wall 9 by extending the collection network 6 to the upstream side. Further, the downstream end of the collection network 6 is connected to the vicinity of the center of the filter 7.

  In this case, the ice A sucked into the oil strainer 1 from the suction port 1a together with the oil proceeds straight toward the outer side of the bent portion 5 of the bent portion 5 in the flow path 4, and passes through that portion to bend the bent portion of the filter 7. 5 is stored in a portion corresponding to the outer portion of the bend 5 and a downstream portion of the collection net 6 in contact with the portion. On the other hand, the ice A in the oil sucked into the oil strainer 1 from the suction port 1a is less likely to enter the inside of the bent portion 5 due to the wall 9 formed in the suction port 1a. For this reason, the portion of the filter 7 corresponding to the inner portion of the bent portion 5 becomes a portion that is not blocked by the accumulation of ice A, and the oil flows efficiently downstream as indicated by the arrow Y through the portion. be able to.

  In addition, about the wall 9 of the suction inlet 1a, you may apply to the oil strainer 1 of the said embodiment (FIG. 1 etc.). Further, with respect to the oil strainer 1, as shown in FIG. 6, the collection network 6 is extended upstream and the upstream end of the collection network 6 is positioned in the vicinity of the wall 9, or the collection network 6 shown in FIG. It is also possible to adopt the downstream end structure.

As shown in FIG. 7, the upstream end of the collection network 6 in the oil strainer 1 may be brought into contact with the inner wall of the bending inner portion of the bending portion 5 in the flow path 4.
In this case, the ice A in the oil sucked into the oil strainer 1 from the suction port 1a gathers in the bent outer portion of the bent portion 5 due to centrifugal force when flowing through the bent portion 5 of the flow channel 4, Without being flowed downstream of the collection net 6 in FIG. 3, the bend 5 is accumulated in the downstream portion of the collection net 6 in the portion outside the bend.

  Since the upper end of the collection net 6 is brought into contact with the inner wall of the bent inner portion of the bent portion 5, the amount of ice A that accumulates in the collection net 6 increases. It will not be blocked by. This is because the area of the trapping net 6 in the collection net 6 is larger than that of the filter 7 of the above-described embodiment (FIG. 1 and the like), and with the rise in the oil temperature after the start of the internal combustion engine. This is because the ice A collected in the collection net 6 is melted.

  In the oil strainer 1, the collection net 6 functions not only as a separation net for collecting ice across a bend outer portion and a bend inner portion of the bent portion 5, but also has a filter function. Accordingly, the filter 7 as shown in FIG. 1 can be omitted from the oil strainer 1.

  The upstream end of the collection network 6 in the oil strainer 1 shown in FIG. 1 may be brought into contact with the inner wall of the bent inner portion of the bent portion 5 like the upstream end of the collection network 6 shown in FIG. . In this case, the collection net 6 functions as a separation net that collects ice across the bent outer portion and the bent inner portion of the bent portion 5, and the filter 7 assumes the function as a filter.

  DESCRIPTION OF SYMBOLS 1 ... Oil strainer, 1a ... Suction port, 2 ... Oil pump, 3 ... Oil pan, 4 ... Channel, 5 ... Bending part, 6 ... Collection net, 7 ... Filter, 8 ... Hole, 8a ... Open end, 8b ... open end, 9 ... wall.

Claims (1)

A filter provided in the flow path for flowing the sucked oil;
A bent portion formed by curving the upstream portion of the filter in the flow path;
An oil strainer comprising: a separation net that is provided so as to separate a bent outer portion and a bent inner portion in the bent portion and captures the foreign matter in the oil so as not to flow downstream ;
The separation net includes a hole that communicates a bent outer portion and a bent inner portion of the bent portion;
The inner peripheral surface of the hole has a tapered shape that expands from the opening end of the hole that opens to the outer portion of the bending portion toward the opening end of the hole that opens to the inner portion of the bending portion. The hole is an oil in which the opening area of the opening end that opens to the outer portion of the bending portion is smaller than the opening area of the opening end that opens to the inner bending portion of the bending portion. Strainer .