KR101322358B1 - Electricity generating apparatus coupled directly with engine of vehicle - Google Patents

Abstract

PURPOSE: An electricity generating apparatus coupled directly with an engine of a vehicle is provided to reduce loss of dynamic power, by connecting a generator between the engine and a gearbox of the vehicle directly. CONSTITUTION: An external housing is formed with a hollow type cylindrical body. A stator assembly (120) is formed with a stator housing and a plurality of stator coil bundles. A rotor assembly (130) is rotatably installed in the inside of the stator assembly. A transmission side coupler (150) relieves the axle load. The axle load is generated between the power generator and the gearbox.

Description

Power generating apparatus coupled directly with engine of vehicle

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an engine direct generator of a vehicle, and more particularly, to an engine direct generator of a vehicle that is directly coupled between an engine and a transmission of a vehicle to produce electricity using the engine as a driving mechanism.

As is well known, a vehicle is provided with a battery and a generator for supplying power to various electrical appliances provided in the vehicle. The battery is mainly used to start the vehicle while the vehicle is stopped or to operate an audio device. In this jammed state, the engine is used as a prime mover to produce electricity, which is then used to supply various electrical components of the vehicle. The generator of such a vehicle is called a generator in general terms, and more specifically, an alternator which means an alternator.

1 is a block diagram illustrating a power generation system of a conventional vehicle. As shown in FIG. 1, a power generation system of a conventional vehicle is key-coupled to a connecting shaft of a generator 60, an engine 10, and a transmission 20 including a rotor 64 and a stator 62, and rotates with them. Drive driven pulley 30, driven by the rotor shaft 66 of the generator 60, the driven pulley 40 to rotate with the generator rotor 64, drive pulley 30 and driven pulley 40 The battery 50 may be connected to the belt 50 to connect and the stator 62 of the generator 60 to charge the electricity produced by the generator 60.

In the above-described configuration, when the output shaft of the engine 10 rotates, its rotational force is transmitted to the transmission 20, and also to the belt 50 through the driving pulley 30, so that the shaft is driven by the driven pulley 40 and the key. The rotor 64 of the combined generator 60 is rotated together, so that electricity is generated in the coil of the stator 62 by the rotating magnetic field. The electricity is converted into DC power through a rectifier (not shown), and then various electric devices of the vehicle are operated to charge the battery.

However, the conventional vehicle generator as described above simply generates the minimum power required to drive the vehicle electronics during operation of the vehicle engine, for example, a small amount of electric power of about 1 to 2 kW. Various electrical equipments outside the vehicle such as leisure or emergency relief cannot be operated smoothly. As a result, in order to operate the electrical equipment outside the vehicle, such as leisure or emergency relief in the open air, there was a hassle to carry an independent generator operating on the fossil raw material in the vehicle.

On the other hand, Japanese Patent Laid-Open No. 2000-309226 discloses a power generation device which is directly connected between an engine and a transmission of a vehicle and has a function of an alternator and a starter of a conventional vehicle, but this is also used for operating the electrical equipment inside the vehicle. Since it has been proposed, there is a problem that the generated power is too small to operate the electrical equipment outside the vehicle, such as for recreation or emergency relief.

The present invention has been made to solve the above-described problems, and is directly coupled between the engine and the transmission of the vehicle separately from the existing vehicle alternator engine direct-connected power generation device of the vehicle to produce electricity by using the engine as a driving mechanism For the purpose of providing it.

In order to achieve the above object, an engine-directed power generation apparatus of a vehicle of the present invention is applied to a vehicle in which an alternator for supplying driving power to a vehicle electronics is connected in parallel between an engine and a transmission, and has a hollow cylinder having a horizontal shape. An outer housing; A stator assembly composed of a hollow cylinder having a horizontal shape, and comprising a stator housing inserted into an interior of the outer housing while supporting a plurality of stator coils, and a plurality of stator coil bundles fixedly installed along an inner circumferential surface of the stator housing. ; A rotor assembly comprising a rotor core formed of a cylindrical body having a rotor shaft at a center thereof, and a plurality of magnets fixedly installed along an outer circumferential surface of the rotor core to be rotatably installed inside the stator assembly; An engine side coupler interposed so as to perturb back and forth between the engine side end of the rotor shaft and the output end of the engine, and between the transmission side end of the rotor shaft and the input end of the transmission to mitigate axial load generated between the power generator and the engine. And a transmission-side coupler interposed therebetween to mitigate the celebration occurring between the power generation device and the transmission.

In the above-described configuration, the outer housing includes a coolant inlet and a coolant outlet for circulation of coolant for cooling the stator assembly, and an outer circumferential surface of the stator housing is formed of a groove having a spiral shape surrounding the outer circumferential surface a plurality of times. Cooling water circulation groove is formed so that the outer peripheral surface of the stator housing is in close contact with the inner peripheral surface of the outer housing characterized in that the cooling water circulation groove to function as a cooling water circulation path.

The rotor assembly rotates together with the rotor core on a rotor core having a plurality of storage pockets formed along a circumference, a permanent magnet stored in each storage pocket of the rotor core and fixed to an inner circumferential surface of the rotor core. It comprises a rotor shaft coupled to, wherein the rotor shaft is a rotor core insertion portion consisting of an outer circumferential surface into which the rotor core is inserted, integrally with the rotor core insertion portion on the left side of the rotor core insertion portion An engine side key gear portion formed on the outer circumferential surface thereof, and a transmission side key gear portion formed on the right end of the central shaft that crosses the center of the rotor core inserting portion, and a key coupling gear formed on the outer circumferential surface thereof. Characterized in that made.

According to the engine direct-type power generation apparatus of the vehicle of the present invention, by connecting the generator in series between the engine and the transmission of the vehicle separately from the alternator provided in the vehicle, the idling of the vehicle without causing a large power loss when driving the vehicle In the state, it is possible to supply a relatively large power of about 10 kW to the outside of the vehicle for leisure or emergency relief, etc., thereby eliminating the inconvenience of having to carry a fossil fuel generator separately.

1 is a block diagram illustrating a power generation system of a conventional vehicle.
2 is a block diagram illustrating a power generation system of a vehicle provided with an engine direct type power generation apparatus according to the present invention.
3A and 3B are respectively a perspective view of the engine direct-connected power generation device of the vehicle of the present invention viewed from the engine side coupler and the transmission side coupler directions.
4A, 4B and 4C are respectively a front view, a left side view and a right side view of an engine direct type generator of the vehicle of the present invention.
5 is an exploded perspective view of an engine direct generator of the vehicle of the present invention.
6 is a longitudinal cross-sectional view taken along line AA in FIG. 4A;
Figure 7 is a schematic cross-sectional view showing a state in which the engine direct-connected power generation device of the vehicle of the present invention coupled to the engine and the transmission.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the engine direct type generator of the vehicle of the present invention.

FIG. 2 is a block diagram illustrating a power generation system of a vehicle having an engine-directed generator according to the present invention. The same configuration as that in FIG. 1 is given the same reference numeral, and detailed description thereof will be omitted. As shown in FIG. 2, according to the engine direct-type power generation apparatus of the present invention, a power which is relatively larger than that of the conventional alternator between the connecting shaft of the engine 10 and the transmission 20, separately from the alternator of the conventional vehicle, For example, the generator 100 for producing a large power of about 10 kW, preferably an alternator is directly coupled.

As a result, according to the present invention, the engine 10, the generator 100, and the transmission 20 are connected in series, and when the vehicle runs, power generated in the generator 100 is not normally used, and an idle state of the engine, In other words, the power generated by the generator 100 in the idling state is used (which may be used during driving, of course). When the generator 100 is operated at no load as the vehicle is running as described above, even if the generator 100 is interposed between the engine 10 and the transmission 20, power generated in the engine 10 is almost lost. Is transmitted to the transmission 20 without.

3A and 3B are perspective views of an engine direct type generator of the vehicle of the present invention as viewed from an engine side coupler and a transmission side coupler, respectively, and FIGS. 4A, 4B, and 4C are respectively an engine direct type generator of a vehicle of the present invention; Front, left and right side views of the device. 5 is an exploded perspective view of an engine direct generator of the vehicle of the present invention, and FIG. 6 is a longitudinal cross-sectional view taken along line A-A of FIG. 4A.

As shown in Figures 3 to 6, the engine direct type generator of the vehicle of the present invention includes an outer housing 110 made of a hollow cylindrical body of a horizontally laid shape; It is made of a hollow cylinder of the horizontally laid shape and a plurality of stator housing 122 and the stator housing 122 is fixedly installed along the inner circumferential surface of the stator housing 122 is inserted into the outer housing 110 while supporting a plurality of stator coils A stator assembly (120) consisting of a stator coil bundle (124); Stator assembly consisting of a rotor core 132 consisting of a cylindrical body having a rotor shaft 134 at the center and a plurality of magnets 136, for example permanent magnets, which are fixedly fixed along the outer circumferential surface of the rotor core 132. A rotor assembly 130 rotatably installed inside the 120; An engine side coupler 140 and a rotor shaft interposed between the engine side end of the rotor shaft 134 and the output end of the engine 10 to mitigate axial load occurring between the generator 100 and the engine 10 ( And a transmission-side coupler 150 interposed between the transmission-side end of the transmission 134 and the input end of the transmission 20 to mitigate congestion occurring between the generator 100 and the transmission 20.

In the above-described configuration, the outer housing 110 may be manufactured by a casting or die casting method using a metal material, for example aluminum, in place a coolant inlet 112 for circulation of coolant to cool the stator assembly 120. ) And a cooling water outlet (not shown) are provided. The outer housing 110 also has a terminal for outputting three-phase alternating current generated from the stator assembly 120 and a resolver installed inside the outer housing 110 to sense a rotation angle (rotation speed) of the rotor assembly 130. A terminal box 114 is provided which integrates a sensor output terminal for outputting a sensing value of.

Next, the stator housing 122 may also be manufactured by casting or die-casting a metal material, for example, aluminum, and a coolant circulation groove 122a having a groove shaped to surround the outer circumferential surface a plurality of times in a spiral shape is formed on the outer circumferential surface thereof. Formed. In this structure, the outer circumferential surface of the stator housing 122 is tightly coupled to the inner circumferential surface of the outer housing 110 such that the cooling water circulation groove 122a functions as a cooling water circulation path. The coolant inlet 112 and the coolant outlet of the outer housing 110 communicate with one end and the other end of the coolant circulation groove 122a of the stator housing 122, respectively.

A plurality of stator coil bundles 124 are fixedly installed in the stator housing 122 along its inner circumferential surface. Each of the stator coil bundles 124 is fixed to the stator core with the coil wound around the bobbin.

Next, the rotor assembly 130 includes a rotor core 132 in which a plurality of storage pockets are formed along a circumference, a permanent magnet 136 and a rotor accommodated and fixed in each storage pocket of the rotor core 132. An inner circumferential surface of the core 132 includes a rotor shaft 134 that is coupled, for example keyed, to rotate with the rotor core 132.

The rotor shaft 134 is integrated with the rotor core inserting portion 134a on the left side of the rotor core inserting portion 134a and the rotor core inserting portion 134a formed of an outer circumferential surface into which the rotor core 132 is inserted. It is formed in the outer peripheral surface is formed on the right end of the central axis across the center of the engine side key gear portion (134b) and the rotor core inserting portion (134a), the key coupling gear is formed, the outer peripheral surface is formed with a key coupling gear And a transmission side key gear portion 134c.

The rotor core inserting portion 134a has a cylindrical body with the left side closed and the right side open, and a center axis for forming the transmission-side key gear portion 134c crosses in the center as described above. In the space formed between the electronic core inserting portions 134a, a bearing, for example, a ball bearing 138, is installed to couple the rotor assembly 130 without friction to the outer housing 110.

On the other hand, the engine side coupler 140 for connecting the output shaft of the engine 10 to the rotor assembly 130 of the generator 100 has a hollow coupling cylindrical portion 142 is formed with a gear 142a on the inner circumferential surface; One end of the coupling cylindrical portion 142, that is, the left end is integrally formed so as to face the outside so that the engine side coupler 140 rotates together with the rotor assembly 130. It may be made of a bracket 144 fixed to 130. Although the engine side coupler gear 142a formed on the inner circumferential surface of the coupling cylindrical portion 142 is physically formed in the same shape and the same structure, it is functionally keyed to the engine side key gear portion 134b of the rotor shaft 134. It may be divided into a spline coupling gear portion is splined to the key coupling gear portion is coupled to the output shaft of the engine 10.

By the above-described configuration, the engine side coupler 140 is fixed to the rotor assembly 130 with the key coupling gear portion keyed to the engine side key gear portion 134b of the rotor shaft 134. Meanwhile, the spline coupling gear of the engine side coupler 140 is splined to the output shaft of the engine 10 so that the engine side coupler 140 fixed to the rotor assembly 130 has an output shaft of the engine 10. Can be perturbed back and forth, resulting in absorbing axial loads that can be exerted on the rotor shaft 134 of the generator 100 according to assembly tolerances. As a result, the left and right lengths of the spline coupling gear portion should be larger than the assembly tolerance.

Next, the transmission side coupler 150 is formed of a hollow cylindrical body, and an inner circumferential surface of the key coupling bore 152 in which a key coupling gear is keyed to the transmission side key gear portion 134c of the rotor shaft 134. And an elastic plate 154 which is fixedly coupled to, for example, bolted to, the right end of the key coupling bore 152.

In the above-described configuration, the elastic plate 154 is preferably implemented by a metal plate having a very high elastic force so as to perform the function of the leaf spring. The outer circumferential edge of the elastic plate 154 has a strength of the elastic plate 154. Vertical rim 154a for reinforcing is formed. In the drawing, reference numeral 154b denotes a bolt through hole for fixing the transmission side input shaft and the elastic plate 154. In order for the elastic plate 154 to have greater elasticity, such a bolt through hole is attached to the elastic plate 154. It is desirable to form it closer to the vertical rim than to the central axis.

On the other hand, when the vehicle is started, the torque converter of the transmission 20 decreases and increases in the axial direction, and the rotor shaft 134 of the generator 100 is congratulated according to the axial displacement. Heavy may be applied to damage the generator 100. In the present invention, such an axial load is absorbed by the elastic plate 154 of the transmission side coupler 150 to the rotor shaft 134 of the generator 100. It is possible to prevent the axial load from being applied.

 FIG. 7 is a schematic cross-sectional view illustrating a state in which an engine direct-type generator of the vehicle is coupled to an engine and a transmission. FIG. As shown in FIG. 7, according to the engine direct type power generation apparatus of the vehicle of the present invention, the spline coupling gear portion of the engine side coupler 140 is splined to the output shaft (es) of the engine 10 to rotate the rotor. The engine side coupler 140 fixed to the assembly 130 is capable of perturbing back and forth with respect to the output shaft es of the engine 10 and consequently the rotor shaft 134 of the generator 100 in accordance with assembly tolerances. It absorbs axial loads that can be exerted on them.

In addition, since the transmission side input shaft ts is coupled to the elastic plate 154 of the transmission side coupler 150, the leaf spring of the elastic plate 154 even though an axial load is applied by the torque converter of the transmission 20. This axial load is absorbed by the action, and as a result, this axial load is not applied to the rotor shaft 134 of the generator 100.

As mentioned above, although the preferred embodiment of the engine direct type generator of the vehicle of the present invention was described in detail with reference to the accompanying drawings, this is only an illustration, and various modifications and changes can be made within the scope of the technical idea of the present invention. Accordingly, the scope of the present invention should be determined by the following claims.

10: engine, 20: gearbox,
30: driven pulley, 40: driven pulley,
50: belt, 60: generator,
62: stator, 64: rotor,
70: battery, 100: generator,
110: outer housing, 112: coolant inlet,
114: terminal box, 120: stator assembly,
122: stator housing, 122a: cooling water circulation groove,
124: bundle of stator coils, 130: rotor assembly,
132: rotor core, 134: rotor shaft,
134a: rotor core insertion part, 134b: engine side key gear part,
134c: transmission gear unit, 136: permanent magnet,
138: ball bearing, 140: engine side coupler,
142: cylindrical portion for engagement, 142a: gear,
144: bracket, 150: transmission side coupler,
152: bore, 154: elastic plate,
154a: vertical rim, 154b: bolt through hole

Claims (3)

delete An alternator that supplies drive power to the vehicle's electronics is applied to vehicles connected in parallel between the engine and the transmission,
An outer housing made of a hollow cylindrical body having a horizontally laid shape;
A stator assembly composed of a hollow cylinder having a horizontal shape, and comprising a stator housing inserted into an interior of the outer housing while supporting a plurality of stator coils, and a plurality of stator coil bundles fixedly installed along an inner circumferential surface of the stator housing. ;
A rotor assembly comprising a rotor core formed of a cylindrical body having a rotor shaft at a center thereof, and a plurality of magnets fixedly installed along an outer circumferential surface of the rotor core to be rotatably installed inside the stator assembly;
An engine-side coupler interposed between the engine-side end of the rotor shaft and the output end of the engine so as to perturb back and forth to alleviate the celebration occurring between the power generator and the engine;
A transmission side coupler interposed between the transmission side end of the rotor shaft and the input end of the transmission to mitigate celebrating occurring between the power generation device and the transmission,
The outer housing has a coolant inlet and a coolant outlet for circulation of coolant for cooling the stator assembly,
Cooling water circulation groove is formed on the outer circumferential surface of the stator housing is formed of a groove of a shape that surrounds the outer circumferential surface a plurality of times in a spiral manner, but the outer circumferential surface of the stator housing is in close contact with the inner circumferential surface of the outer housing is the cooling water circulation groove Engine direct-connected power generation device, characterized in that to function as. 3. The method of claim 2,
The rotor assembly may include a rotor core having a plurality of storage pockets formed along a circumference thereof, a permanent magnet accommodated in and fixed to each of the storage pockets of the rotor core, and the rotor core on an inner circumferential surface of the rotor core. Comprising a rotor shaft coupled to rotate together,
The rotor shaft is formed of a rotor core insertion portion consisting of an outer circumferential surface into which the rotor core is inserted, integrally with the rotor core inserting portion on the left side of the rotor core inserting portion, and a key coupling gear is formed on the outer circumferential surface thereof. An engine direct type power generation unit comprising a transmission side key gear unit formed at a right end portion of a central shaft that crosses the center of the engine side key gear unit and the rotor core insertion unit, and a key coupling gear formed at an outer circumferential surface thereof. Device.

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