JPH0526248Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) This invention is an engine exhaust heat recovery device that recovers exhaust heat by installing a heat exchanger that exchanges heat between engine exhaust gas and water. Regarding.

(Prior Art) In a device that recovers engine exhaust heat and uses it as a heat source for heating or a heat pump circuit, a heat exchanger for exhaust heat recovery is used, for example, as disclosed in Japanese Patent Application Laid-Open No. 135313/1983. An exhaust heat recovery device for an engine is known, and the heat exchanger has a core portion through which exhaust gas passes, and an outer case forming a cooling water passage between the core portion and the core portion. It is structured as follows.

(Purpose of the invention) The present invention relates to the improvement of the heat exchanger as described above, and its purpose is to improve the heat recovery efficiency and to facilitate the layout and maintenance work of the cooling water piping.

(Structure of the invention) In order to achieve the above object, the present invention provides a cooling water intake in the outer case of the heat exchanger on the upstream side of the exhaust gas flow, and also provides cooling water taken in from the cooling water intake. A cooling water introduction passage is provided in the outer case to directly introduce the cooling water to the downstream side of the exhaust gas flow of the core portion of the heat exchanger.

(Effect of the invention) According to the invention, the cooling water taken in from the cooling water intake of the heat exchanger flows in the core from the downstream side to the upstream side of the exhaust gas flow, so that the exhaust gas and the cooling water are separated. flow in opposite directions, thus increasing the heat exchange efficiency between the exhaust gas flow and the cooling water flow and improving the heat recovery efficiency of engine exhaust heat.

Further, according to the present invention, there is an effect that the arrangement of the cooling water piping becomes easy. In other words, this type of exhaust heat recovery device is generally used as a heat source on the heat pump circuit side of a heat pump device configured to drive a refrigerant pressurizing compressor by the output shaft of the engine. A heat exchanger equipped with the heat exchanger is arranged as a main heat exchanger on the side of the engine on the compressor side, and further, on the side of the exhaust manifold side adjacent to the compressor side,
An exhaust manifold heat exchanger configured by surrounding the outer periphery of the exhaust manifold with cooling water is connected in series with the main heat exchanger on the upstream side of the exhaust gas flow and in order to recover heat dissipated from the exhaust manifold. The exhaust manifold heat exchanger supplies cooling water that has passed through both heat exchangers to the water pump and heat pump device of the engine. Therefore, as in the present invention, by providing the cooling water inlet at a position corresponding to the upstream end of the exhaust gas flow in the main heat exchanger, the cooling water inlet and outlet can be placed on one side of the engine. Since it can be concentrated, the layout and maintenance work of the cooling water piping is facilitated.

(Embodiments) Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

First, referring to FIG. 9, the entire system of a heat pump device to which the engine exhaust heat recovery device according to the present invention is applied will be explained.The heat pump unit side system A includes a refrigerant pressurizing compressor 1.
, indoor heat exchanger 2 , four-way valve 3 , and expansion valve 4
A heat pump refrigerant circuit 6 consisting of a heat exchanger 5 and an outdoor heat exchanger (heat load) 5 is provided, and a heat radiation fan 7 for the outdoor heat exchanger 5 and a heat exchanger 10 described later is provided. On the other hand, the engine side system B is provided with an engine 8 equipped with an output shaft 8a that drives the compressor 1, and recovers exhaust heat from the engine 8, and radiates the recovered heat in a heat exchanger 10. , and a cooling passage 9 for cooling the engine 8.

This cooling water passage 9 connects a heat exchanger 10 and a circulating water pump 11 that exchange heat with the outdoor heat exchanger 5 of the heat pump unit side system A, and a circulating water pump 11 that exchanges heat with the outdoor heat exchanger 5 of the heat pump unit side system A, and the exhaust gas of the engine 8 as a heat medium in the engine side system B. An engine exhaust passage heat exchanger consisting of a main heat exchanger 12 that exchanges heat with cooling water and recovers exhaust heat, and an exhaust manifold heat exchanger 13 configured by surrounding the outer periphery of the exhaust manifold with a cooling water passage; The water pump 14 inside,
It is formed by connecting the thermostat 15 in series. In addition, heat exchangers 12 and 1
A bypass passage 16 is formed to directly supply the cooling water heated to a high temperature by the engine exhaust passage heat exchanger 3 to the heat exchanger 10 of the heat pump unit side system A. The main heat exchanger 12 is arranged in a space above the output shaft 8a on the side surface of the engine 8 on the compressor 1 side. In addition, in FIG. 9, 8b is a housing that accommodates fly oil that is rotated by the engine output.

Next, the configuration of the engine side system B will be explained with reference to FIGS. 1 to 3. The main heat exchanger 12
is arranged above the output shaft 8a on the rear surface of the engine 8 main body, that is, the side surface on the compressor side,
In addition, the exhaust manifold heat exchanger 13 is connected to the engine 8
It is provided above the side surface of the main body on the exhaust manifold side, that is, on the upstream side of the exhaust gas flow of the main heat exchanger 12. The main heat exchanger 12 is provided at a position lower than the height of the exhaust manifold heat exchanger 13, and a cooling water intake port 12a is provided at the upstream end of the main heat exchanger 12 in the exhaust gas flow. Further, it is connected to the exhaust manifold heat exchanger 13 by a connecting portion 12b, and this main heat exchanger 1
The downstream side of the exhaust gas flow in No. 2 is sloped downward.
At the top of the inclined lower end of the main heat exchanger 12,
An exhaust outlet 12c to which an exhaust pipe and a silencer (not shown) are connected is provided, and a condensed water drain 12d is provided at the bottom.

4 to 6 schematically show a cross-sectional configuration of the main heat exchanger 12, which includes a core portion 20 through which exhaust gas is passed, and a cooling water passage 2 between the core portion 20 and the core portion 20.
1 and an outer case 22 forming the main body. Note that, since the configuration of the core section 20 is well known, detailed illustrations and explanations thereof will be omitted. And as mentioned above, the cooling water intake port 12
A is provided at the upstream end of the exhaust gas flow, and the cooling water taken in from this cooling water intake is passed through the core part 2.
A cooling water introduction passage 23 is formed in the outer case 22 in parallel with the cooling water passage 21 to directly lead the exhaust gas flow to the downstream side.

By configuring the main heat exchanger 12 in this way, the cooling water taken in from the cooling water intake port 12a passes directly through the cooling water introduction passage 23 to the outer case 2.
The cooling water is guided to a portion 12e corresponding to the exhaust outlet 12c side in the cooling water outlet portion 12, and flows from this portion 12e toward the upstream side of the exhaust gas flow inside the core portion 20 to reach the cooling water outlet portion 12.
f, and during this time heat exchange takes place between the exhaust gas and the exhaust gas. Since the exhaust gas flow and the cooling water flow in opposite directions to each other, so-called counter-flows, the heat exchange efficiency can be improved.

The cooling water that has reached the cooling water outlet portion 12f flows into the exhaust manifold heat exchanger 13 through the connection portion 12b with the exhaust manifold heat exchanger 13.
As shown in FIGS. 7 and 8, this exhaust manifold heat exchanger 13 has a cylindrical shape that collects exhaust gas discharged from the four exhaust ports 26 of the cylinder head 25 through the inside of the exhaust manifold 27. It consists of a gathering chamber 28 and an outer case 31 forming a cooling water passage 30 around the chamber wall 29 of the gathering chamber 28. As is clear from FIG. 7, the centers of the openings 32 of each exhaust manifold 27 to the collecting chamber 28 are aligned on the horizontal line _l1 , but the cylindrical collecting chamber 28 has its axis _l2 It is formed to be inclined so that the downstream side of the exhaust gas flow, that is, the main heat exchanger 12 side is lower. Therefore, the bottom 28a of the collecting chamber 28 is also inclined with respect to the horizontal line _l1 so that the downstream side of the exhaust gas is lower, and furthermore, this bottom 28a is lower than the opening 32 of the exhaust manifold 27 to the collecting chamber 28. It is formed to be located at.

With this configuration, highly acidic condensed water generated in the collection chamber 28 due to cooling of moisture in the exhaust gas flows to the main heat exchanger 12 side, and the condensed water of the main heat exchanger 12 Since the condensed water is discharged from the drain 12d, there is no fear that the chamber wall 29 of the gathering chamber 28 will be corroded by the acidity of the condensed water. Furthermore, even if a hole due to corrosion or a crack due to heat occurs in the chamber wall 29 of the gathering chamber 28 and cooling water leaks into the gathering chamber 28, this cooling water will be transferred to the main heat exchanger 12.
Since the cooling water is discharged from the drain 12d of the exhaust manifold 27, there is no risk of the cooling water flowing back into the combustion chamber in the engine 8 and damaging the engine 8.

On the other hand, the cooling water that has passed through the main heat exchanger 12 flows from the connection part 12b into the cooling water passage 30 in the exhaust manifold heat exchanger 13, where heat exchange is also performed. In order to extract the heat from the upper and lower parts of the heat exchanger 13 to the outside, an upper outlet 13a and a lower outlet 1 are provided in the outer case 31 at positions corresponding to the upstream ends of the exhaust gas flow.
3b is provided. The cooling water made into high-temperature hot water by the exhaust gas is then transferred to the upper outlet 13a.
The relatively low temperature cooling water is taken out from the bottom outlet 1.
3b. Further, the upper outlet 13a is connected to the heat exchanger 10 of the heat pump unit side system A through a bypass passage 16 in FIG. 9, and the lower outlet 13b is connected to the water pump 14 of the engine 8.
Therefore, the high-temperature cooling water taken out from the upper outlet 13a is directly supplied to the heat exchanger 10 through the bypass passage 16, whereas the relatively low-temperature cooling water taken out from the lower outlet 13b is supplied to the water pump 1.
4, then passes through the water jacket in the main body of the engine 8, further passes through the thermostat 15, and then joins with the cooling water flowing out through the bypass passage 16, and is supplied to the heat exchanger 10. .

By providing the upper outlet 13a and the lower outlet 13b in the outer case 31 of the exhaust manifold heat exchanger 13 in this manner, the heat exchange efficiency in the heat pump unit side system A can be improved. In addition, stagnation of cooling water inside the outer case 31 is prevented, and air bubbles are prevented from stagnating at the upper outlet 1.
3a, it is also possible to prevent the exhaust manifold 27 and the collecting chamber wall 29 from cracking due to local boiling of the cooling water.

Next, the operation of the heat pump device shown in FIG. 9 will be explained. When the engine 8 is operated, the compressor 1 is driven via the output shaft 8a, the heat pump refrigerant circuit 6 is operated, and the indoor heat exchanger 2 is operated. When the condenser and outdoor heat exchanger 5 act as an evaporator, indoor heating can be performed, and by switching the four-way valve 3, the indoor heat exchanger 2 acts as an evaporator and an outdoor heat exchanger. When 5 acts as a condenser, the indoor side can be cooled. On the other hand, regarding cooling water, the circulating water pump 11 in the heat pump unit side system A operates even when the engine 8 is stopped, and the cooling water is passed from the main heat exchanger 12 to the exhaust manifold heat exchanger 13 to the heat exchanger. 10 is adapted to circulate at a constant flow rate. Further, while the engine 8 is operating, the water pump 14 in the engine 8 sucks cooling water through the lower outlet 13b of the exhaust manifold heat exchanger 13, and this cooling water is supplied to the engine 8.
Engine 8
to cool down.

Therefore, the cooling water and the exhaust gas exchange heat in the main heat exchanger 12 and the exhaust manifold heat exchanger 13, and the exhaust heat is efficiently recovered.
This recovered exhaust heat is heat-exchanged by the heat exchanger 10 to the outdoor heat exchanger 5 on the heat pump circuit side,
When the heat pump refrigerant circuit 6 performs indoor heating operation, waste heat is effectively utilized.

In the present invention, the cooling water taken in from the cooling water intake port 12a of the main heat exchanger 12 is introduced from the introduction passage 23 to the downstream end of the exhaust gas flow, and is directed from the downstream side to the upstream side of the exhaust gas flow. Since the exhaust gas and the cooling water flow inside the core part 20, the exhaust gas and the cooling water become counter-flows, and the heat exchange efficiency in the main heat exchanger 12 can be increased. 12a is provided on the upstream side of the exhaust gas flow, that is, close to the connecting portion 12b with the exhaust manifold heat exchanger 13, so that the cooling water intake port 12a and the cooling water outlet from the exhaust manifold heat exchanger 13 are connected to each other. 13a,
13b is concentrated on one side of the engine 8, which has the effect of facilitating the layout and maintenance work of the cooling water piping.

[Brief explanation of the drawing]

Fig. 1 is a rear view of an engine in which the exhaust heat recovery device according to the present invention is implemented, Fig. 2 is a plan view of the same, Fig. 3 is a side view of the same, and Fig. 4 is a view of the main heat exchanger in the exhaust heat recovery device. 5 is a longitudinal sectional view of the same, FIG. 6 is a longitudinal sectional view taken along the - line in FIG. 5, FIG. 7 is a longitudinal sectional view of the exhaust manifold heat exchanger, and FIG. 7 is a longitudinal sectional view taken along the line -, and FIG. 9 is a schematic diagram showing the overall configuration of the engine-driven heat pump device. 1...Compressor, 8...Engine, 12...
... Main heat exchanger, 13 ... Exhaust manifold heat exchanger, 20 ... Core section, 22, 31 ... Outer case, 23 ... Cooling water introduction passage, 27 ... Exhaust manifold, 28 ... Collection room.

Claims (1)

[Scope of Claim for Utility Model Registration] A heat exchanger consisting of a core portion through which exhaust gas passes and an outer case forming a cooling water passage between this core portion is disposed in the exhaust gas passage. In an engine exhaust heat recovery device, a cooling water intake in the outer case of the heat exchanger is provided on the upstream side of the exhaust gas flow, and the cooling water taken in from the cooling water intake is transferred to the exhaust gas flow in the core. An exhaust heat recovery device for an engine, characterized in that a cooling water introduction passage is provided in the outer case to directly lead the cooling water to the downstream side of the engine.