CN207715222U - Engineering truck dual cycle cooling system - Google Patents

Abstract

The utility model belongs to the technical field of vehicle cooling and heat dissipation, and relates to a dual-circulation cooling system for engineering vehicles, which overcomes the problems of low heat dissipation efficiency, large structure size, and high heat dissipation and energy consumption in the prior art, and is composed of a high-temperature circulation cooling system and a low-temperature circulation cooling system , the high temperature circulating cooling system is composed of engine, engine water pump, liquid-liquid radiator a and high-temperature radiator; , low-temperature circulation pump, water-cooled intercooler and liquid-liquid radiator c; the low-temperature circulating coolant passes through the low-temperature radiator, and then flows through the water-cooled intercooler, liquid-liquid radiator c; the cooling air first flows through the low-temperature radiator The utility model then flows through the high-temperature radiator to realize the heat exchange between the heat of each system of the vehicle and the air; the utility model reduces the structural size of the radiator, improves the heat dissipation efficiency of the cooling air, and reduces the energy consumption of the vehicle cooling system.

Description

Engineering vehicle double cycle cooling system

technical field

The utility model belongs to the technical field of vehicle cooling and heat dissipation, and relates to a dual-circulation cooling system for an engineering vehicle, which is suitable for a multi-heat source system of an engineering vehicle and a high-efficiency heat dissipation mode required for large heat dissipation.

Background technique

Engineering vehicles must meet various functional requirements such as driving and operation. The vehicle system has many heat sources, such as the heat source of the engine water cooling system, the heat source of the engine pressurized air, the heat source of the vehicle transmission system, the heat source of the hydraulic system of the vehicle operating device, and the heat source of the engine fuel supply system. The heat source of the condenser of the air-conditioning system, etc., depends on the configuration of the host system, and the heat source of the vehicle is slightly different. The vehicle cooling system is the key to ensure the temperature requirements of the engine cooling system coolant temperature in the vehicle system, the engine charge air cooling temperature requirements, the transmission oil temperature requirements of the vehicle transmission system, the hydraulic oil temperature requirements of the hydraulic system of the vehicle operating device, and the temperature requirements of other vehicle systems system. With the continuous development of vehicle system energy-saving technology and stricter vehicle emission regulations, the application of various new technologies has increased the heat load of the vehicle cooling system. Vehicle cooling and heat dissipation technology is the key technology of modern vehicles, which determines the high efficiency, energy saving, clean emission and reliable operation of vehicles. However, the traditional heat dissipation method combined with fans and multiple radiators is limited by the fan size characteristics, driving characteristics, and noise limitations, limited by the combination of multiple radiators, and limited by the space form of the power cabin. It is difficult to efficiently and reliably balance the vehicle Operating temperature requirements of each system.

Contents of the invention

The technical problem to be solved by the utility model is to overcome the problems of low heat dissipation efficiency, large structural size, and high heat dissipation energy consumption of the engineering vehicle cooling system in the prior art, and provide a dual-circulation cooling system for engineering vehicles, which is suitable for multiple heat sources of vehicles Efficient heat dissipation requirements of the system.

In order to solve the problems of the technologies described above, the utility model is realized by adopting the following technical solutions:

A dual-cycle cooling system for an engineering vehicle is composed of a high-temperature cycle cooling system and a low-temperature cycle cooling system, and the high-temperature cycle cooling system is mainly composed of an engine 1, an engine water pump 2, a liquid-liquid radiator a4, and a high-temperature radiator 6;

The engine water pump 2 drives the coolant in the high-temperature circulating cooling system to flow;

In the high-temperature circulating cooling system, the coolant sequentially flows through the internal cooling cavity of the engine 1 to obtain the heat of the engine cooling system, and flows through the liquid-liquid radiator a4 to obtain the heat of the vehicle transmission system;

In the high-temperature circulating cooling system, the heat of the coolant is exchanged with the flowing cooling air in the high-temperature radiator 6;

The low-temperature circulating cooling system is mainly composed of a low-temperature radiator 7, a low-temperature circulating pump 8, a water-cooled intercooler 9 and a liquid-liquid radiator c10;

The low-temperature circulating coolant is driven to flow by the low-temperature circulating pump 8 .

In the low-temperature circulating cooling system, the coolant passes through the low-temperature radiator 7, then flows through the water-cooled intercooler 9 to obtain the heat of the engine pressurized air, and flows through the liquid-liquid radiator c10 to obtain the heat of the hydraulic system of the vehicle operating device;

In the low-temperature circulating cooling system, the heat of the coolant is exchanged with the flowing cooling air in the low-temperature radiator 7 .

The cooling air described in the technical solution flows under the drive of the cooling fan. The cooling air first flows through the low-temperature radiator 7 in the low-temperature circulating cooling system, and then flows through the high-temperature radiator 6 in the high-temperature circulating cooling system, respectively cooling the low-temperature circulating cooling system. The heat of the coolant in the system exchanges heat with the cooling air, and the heat of the coolant in the high-temperature circulating cooling system exchanges heat with the cooling air.

The cooling of the engine charge air described in the technical solution is realized in the water-cooled intercooler 9 in the low-temperature circulating cooling system; in the low-temperature cooling circulating cooling system, the coolant flows through the water-cooled intercooler 9 after passing through the low-temperature radiator 7, Cool the temperature of the boosted air, reduce the pressure loss of the boosted air, and ensure the state requirements of the engine's boosted air entering the combustion chamber.

The high-temperature circulating cooling system also includes a liquid-liquid radiator b5;

In the high-temperature circulating cooling system, the coolant flows through the engine 1 inner cooling cavity, the liquid-liquid radiator a4, and the liquid-liquid radiator b5 in sequence;

The low-temperature circulating cooling system also includes a liquid-liquid radiator d11;

In the low-temperature circulating cooling system, the coolant passes through the low-temperature radiator 7, and then flows through the water-cooled intercooler 9, the liquid-liquid radiator c10, and the liquid-liquid radiator d11.

The liquid-liquid radiator a4, liquid-liquid radiator b5, liquid-liquid radiator c10, and liquid-liquid radiator d11 are respectively placed in the high-temperature circulating cooling system or low-temperature cooling system according to the working temperature requirements of the corresponding vehicle heat source system. In the circulating cooling system, according to the requirements of high-efficiency heat exchange, series or parallel combination is adopted in turn.

Compared with the prior art, the beneficial effects of the utility model are:

The dual-cycle cooling system of engineering vehicles coordinates the cooling requirements of each heat source in the vehicle system, and only realizes heat exchange with the cooling air in the high-temperature radiator and low-temperature radiator, which reduces the structural size of the radiator, improves the heat dissipation efficiency of the cooling air, and reduces Vehicle cooling system energy consumption.

The cooling of the engine charge air in the water-cooled intercooler reduces the volume of the charge air radiator, reduces the flow resistance of the charge air, increases the pressure of the charge air, improves the combustion effect of the engine, improves the performance of the vehicle, and reduces the emission indicators.

The liquid-liquid cooling device of each monomer in the dual-circulation cooling system of engineering vehicles has a small structural size, which improves the flexibility of installation on the vehicle system, facilitates the effective control of the temperature of the corresponding heat source system of the vehicle, and correspondingly improves the performance of the vehicle system.

Description of drawings

Below in conjunction with accompanying drawing, the utility model is further described:

Fig. 1 is the dual cycle cooling system diagram of the engineering vehicle described in the utility model;

Fig. 2 is a diagram of an embodiment of the engineering vehicle dual-circulation cooling system described in the utility model;

In the figure: 1. engine, 2. engine water pump, 3. engine thermostat, 4. liquid-liquid radiator a, 5. liquid-liquid radiator b, 6. high-temperature radiator, 7. low-temperature radiator, 8 , low-temperature circulating pump, 9, water-cooled intercooler, 10, liquid-liquid radiator c, 11, liquid-liquid radiator d;

A indicates hot liquid in and out; B indicates pressurized air in and out; C indicates cold air flow; D indicates hot air flow.

Detailed ways

Below in conjunction with accompanying drawing, the utility model is described in detail:

The dual-circulation cooling system for engineering vehicles of the utility model is composed of a high-temperature circulation cooling system and a low-temperature circulation cooling system, and transfers heat from the heat source of the corresponding system of the vehicle to the high-temperature circulation cooling liquid and the low-temperature circulation cooling liquid in the water-cooling heat dissipation device of the corresponding system, respectively. The cooling air first flows through the low-temperature radiator in the low-temperature circulating cooling system, and then flows through the high-temperature radiator in the high-temperature circulating cooling system to realize the heat exchange between each heat source of the vehicle and the cooling air.

The dual-circulation cooling system for engineering vehicles of the utility model is composed of a high-temperature circulation cooling system and a low-temperature circulation cooling system.

Referring to Fig. 1, the high-temperature circulating cooling system is mainly composed of an engine 1, an engine water pump 2, an engine thermostat 3, a liquid-liquid radiator a4, and a high-temperature radiator 6, and the high-temperature circulating coolant is driven by the engine water pump 2 to flow, Flowing through the cooling cavity inside the engine and the corresponding radiator in turn, the high-temperature circulating coolant obtains heat, and realizes heat exchange with the cooling air in the high-temperature radiator 6 .

The low-temperature circulation cooling system is mainly composed of a low-temperature radiator 7, a low-temperature circulation pump 8, a water-cooled intercooler 9, and a liquid-liquid radiator c10. The low-temperature circulation pump 8 is driven by engine mechanical energy or electric energy, and the low-temperature circulation coolant is composed of The low-temperature circulation pump 8 drives the flow, and flows through the corresponding radiators in sequence. The low-temperature circulating cooling liquid obtains heat, and realizes heat exchange with the cooling air in the low-temperature radiator 7 .

The cooling air flows under the drive of the cooling fan, etc., the cooling air first flows through the low-temperature radiator 7 in the low-temperature circulating cooling system, and then flows through the high-temperature radiator 6 in the high-temperature circulating cooling system, so that the vehicle heat source and the cooling air are realized. heat exchange.

In the low-temperature circulating cooling system, the coolant passes through the low-temperature radiator 7 and then flows through the water-cooled intercooler 9 to cool the temperature of the boosted air, reduce the pressure loss of the boosted air, and ensure that the engine's boosted air enters the combustion chamber. .

The liquid-liquid radiators described above are respectively placed in the high-temperature circulating cooling system or the low-temperature circulating cooling system according to the working temperature requirements of the corresponding vehicle heat source system, and can also be combined in series or in parallel according to the requirements of high-efficiency heat exchange. .

In view of the requirements of the multi-heat source systems of engineering vehicles on the operating temperature characteristics of their respective systems, in order to avoid the high temperature of each system from affecting the high efficiency, energy saving, clean emission, and reliable operation of the vehicle system, the utility model designs a set of dual-cycle cooling systems for engineering vehicles. Realize the efficient cooling and heat dissipation of the heat of each system of the vehicle. The vehicle dual-cycle cooling system consists of a high-temperature cycle cooling system and a low-temperature cycle cooling system.

Embodiment, referring to Fig. 2, engine 1, engine water pump 2, engine thermostat 3 in the high-temperature circulation cooling system are the functional components of the vehicle powertrain, plus high-temperature radiator 6, liquid-liquid radiator a4, liquid-liquid Liquid radiator b5 and other functional components form a high temperature circulation cooling system;

The engine water pump 2 is driven by the mechanical energy of the engine, and the engine water pump 2 drives the coolant flow in the high-temperature circulating cooling system;

In the high-temperature circulating cooling system, the coolant flows through the cooling chamber of the engine 1 to obtain the heat of the engine cooling system, flows through the liquid-liquid radiator a to obtain the heat of the vehicle transmission system, and flows through the liquid-liquid radiator b to obtain the relative operating temperature of the vehicle. High system heat, high temperature cooling liquid in the high temperature circulating cooling system has high temperature and large flow rate, the heat of the cooling liquid in the high temperature circulating cooling system realizes heat exchange with the flowing cooling air in the high temperature radiator 6 .

The low-temperature circulation cooling system is composed of low-temperature radiator 7, low-temperature circulation pump 8, water-cooled intercooler 9, liquid-liquid radiator c10, and liquid-liquid radiator d11;

The low-temperature circulation pump 8 is driven by the mechanical energy or electric energy of the engine, and the low-temperature circulation coolant is driven by the low-temperature circulation pump 8 to flow;

The low-temperature circulating coolant flows sequentially through the water-cooled intercooler 9 to obtain the heat of the engine pressurized air, flows through the liquid-liquid radiator c to obtain the heat of the hydraulic system of the vehicle operating device, and flows through the liquid-liquid radiator d to obtain the relative operating temperature of the vehicle Low system heat, the temperature of the coolant in the low-temperature circulating cooling system is relatively low, and the flow rate is small. In the low-temperature circulating cooling system, the heat of the coolant in the low-temperature circulating cooling system is exchanged with the flowing cooling air in the low-temperature radiator 7 .

The cooling air flows under the drive of the cooling fan, etc., and the cooling air first flows through the low-temperature radiator 7 in the low-temperature circulating cooling system, and then flows through the high-temperature radiator 6 in the high-temperature circulating cooling system, respectively dissipating the heat of the coolant in the low-temperature circulating cooling system. Realize heat exchange with cooling air, and heat exchange between coolant heat and cooling air in the high-temperature circulating cooling system.

In the low-temperature circulating cooling system, the coolant is cooled by the low-temperature radiator 7 and then flows through the water-cooled intercooler 9 to cool the temperature of the engine boost air, reduce the pressure loss of the boost air, and ensure the state requirements for the engine boost air to enter the combustion chamber. The cooling of the engine charge air takes place in the water-cooled intercooler 9 .

The liquid-liquid radiator a4, liquid-liquid radiator b5, liquid-liquid radiator c10, and liquid-liquid radiator d11 are the heat dissipation units of the corresponding systems of the vehicle. The number of liquid-liquid radiators is slightly different according to the configuration of the host system. Differences. Each liquid-liquid radiator is placed in the high-temperature circulating cooling system or the low-temperature circulating cooling system according to the working temperature requirements of the corresponding vehicle heat source system, and can also be combined in series or in parallel according to the high-efficiency heat exchange requirements.

Claims (5)

1. A dual-cycle cooling system for engineering vehicles, characterized in that: it is composed of a high-temperature cycle cooling system and a low-temperature cycle cooling system; The high-temperature circulating cooling system is mainly composed of an engine (1), an engine water pump (2), a liquid-liquid radiator a (4) and a high-temperature radiator (6); The engine water pump (2) drives the coolant in the high-temperature circulating cooling system to flow; In the high-temperature circulating cooling system, the coolant sequentially flows through the internal cooling cavity of the engine (1) to obtain the heat of the engine cooling system, and flows through the liquid-liquid radiator a (4) to obtain the heat of the vehicle transmission system; In the high-temperature circulating cooling system, the heat of the coolant is exchanged with the flowing cooling air in the high-temperature radiator (6); The low-temperature circulation cooling system is mainly composed of a low-temperature radiator (7), a low-temperature circulation pump (8), a water-cooled intercooler (9) and a liquid-liquid radiator c (10); The low-temperature circulating coolant is driven to flow by the low-temperature circulating pump (8); In the low-temperature circulating cooling system, the coolant passes through the low-temperature radiator (7), then flows through the water-cooled intercooler (9) to obtain the heat of the engine pressurized air, and flows through the liquid-liquid radiator c (10) to obtain the hydraulic system of the vehicle operating device heat; In the low-temperature circulating cooling system, the heat of the coolant is exchanged with the flowing cooling air in the low-temperature radiator (7). 2. A dual-circulation cooling system for engineering vehicles according to claim 1, characterized in that: The cooling air flows under the drive of the cooling fan, the cooling air first flows through the low-temperature radiator (7) in the low-temperature circulating cooling system, and then flows through the high-temperature radiator (6) in the high-temperature circulating cooling system, respectively circulating the low-temperature In the cooling system, the heat of the coolant is exchanged with the cooling air, and in the high-temperature circulating cooling system, the heat of the coolant is exchanged with the cooling air. 3. A dual-circulation cooling system for engineering vehicles according to claim 1, characterized in that: The cooling of the engine charge air is realized in the water-cooled intercooler (9) in the low-temperature circulating cooling system; in the low-temperature circulating cooling system, the coolant flows through the water-cooled intercooler (9) after the low-temperature radiator (7) ), cool the temperature of the boosted air, reduce the pressure loss of the boosted air, and ensure the state requirements of the engine's boosted air entering the combustion chamber. 4. A dual-circulation cooling system for engineering vehicles according to claim 1, characterized in that: The high-temperature circulating cooling system also includes a liquid-liquid radiator b (5); In the high-temperature circulating cooling system, the coolant flows through the engine (1) inner cooling cavity, liquid-liquid radiator a (4), and liquid-liquid radiator b (5); The low-temperature circulating cooling system also includes a liquid-liquid radiator d (11); After passing through the low-temperature radiator (7), the coolant in the low-temperature circulating cooling system flows through the water-cooled intercooler (9), the liquid-liquid radiator c (10), and the liquid-liquid radiator d (11) in sequence. 5. A dual-circulation cooling system for engineering vehicles according to claim 4, characterized in that: The liquid-liquid radiator a (4), liquid-liquid radiator b (5), liquid-liquid radiator c (10), and liquid-liquid radiator d (11) are based on the work of the corresponding vehicle heat source system The temperature requirements are respectively placed in the high-temperature circulating cooling system or the low-temperature circulating cooling system. According to the high-efficiency heat exchange requirements, series or parallel combinations are adopted in turn.