End cell heater assembly and fuel cell stack having the same

What is claimed is: 1. An end cell heater assembly, comprising: a case which has a first surface joined to an end plate of a fuel cell stack; a planar heating element installed in an accommodating groove formed in a second surface of the case; a terminal plate which is stacked and interposed between the planar heating element and an end cell of the fuel cell stack, joined and electrically connected to the end cell, and transferring heat generated by the planar heating element to the end cell; and a terminal which is formed integrally with the terminal plate and configured to output electrical energy generated by the fuel cell stack to an outside, wherein the planar heating element performs a heating operation by being supplied with electric power from a power source, wherein the power source is the fuel cell stack, and performs the heating operation by being supplied with electric power generated by the fuel cell stack, wherein the terminal penetrates the planar heating element, wherein the planar heating element is not exposed to outside the case, and wherein the electric power generated by the fuel cell stack is supplied to the planar heating element through a connector installed in the case. 2. The end cell heater assembly of claim 1 , wherein bypass flow paths, which communicate with an air inlet manifold or a hydrogen inlet manifold of the fuel cell stack, are formed in the case, and the bypass flow paths respectively communicate with the air outlet manifold or the hydrogen outlet manifold of the fuel cell stack, and are provided to discharge air or hydrogen passing through the interior of the bypass flow paths to respective outlet manifolds. 3. The end cell heater assembly of claim 1 , wherein, in the case, an air inlet manifold hole communicating with an air inlet manifold of the fuel cell stack, or a hydrogen inlet manifold hole communicating with a hydrogen inlet manifold of the fuel cell stack, is provided, an air outlet manifold hole communicating with an air outlet manifold of the fuel cell stack, or a hydrogen outlet manifold hole communicating with a hydrogen outlet manifold of the fuel cell stack, is provided, and an air bypass flow path connecting the air inlet manifold hole and the air outlet manifold hole, or a hydrogen bypass flow path connecting the hydrogen inlet manifold hole and the hydrogen outlet manifold hole, is provided. 4. The end cell heater assembly of claim 1 , wherein the case comprises an electrically non-conductive material. 5. The end cell heater assembly of claim 1 , wherein the case comprises an electrically and thermally non-conductive material. 6. The end cell heater assembly of claim 1 , further comprising: a thermal insulation pad which is stacked and interposed between the planar heating element and an inner surface of the accommodating groove of the case. 7. The end cell heater assembly of claim 1 , wherein the planar heating element includes: a heating element which performs a-the heating operation by being supplied with electric power from a-the power source; and a sheath which covers the heating element so as to electrically insulate the heating element from the outside. 8. The end cell heater assembly of claim 1 , wherein the terminal penetrates the case and the end plate from the terminal plate. 9. The end cell heater assembly of claim 1 , wherein a temperature sensor is installed on the planar heating element, and a controller receives a signal from the temperature sensor and controls an operation of the planar heating element. 10. The end cell heater assembly of claim 1 , wherein the planar heating element is a heating element using a Positive Temperature Coefficient (PTC) element. 11. A fuel cell stack comprising: a plurality of fuel cells which is provided by being stacked, and generates electrical energy through an electrochemical reaction by being supplied with reactant gases; end plates which are stacked at both end positions of the fuel cell stack outside the stacked fuel cells; and an end cell heater assembly stacked and interposed between end cells positioned at both ends among the stacked fuel cells, and end plates at both ends of the fuel cell stack so as to provide heat to the respective end cells to increase a temperature of the end cells, and having a bypass flow path so that at least one gas of air and hydrogen supplied to the fuel cell stack as reactant gases is distributed to and passes through the bypass flow path, wherein the end cell heater assembly uses a power source which is generated from the fuel cell stack, wherein the end cell heater assembly includes: a case having a first surface joined to the end plate; a planar heating element installed in an accommodating groove formed in a second surface of the case; a terminal plate which is stacked and interposed between the planar heating element and one of the end cells, joined and electrically connected to the one of the end cells, and transferring heat generated by the planar heating element to the one of the end cells; and a terminal which is formed integrally with the terminal plate and configured to output electrical energy generated by the fuel cells including the one of the end cells to an outside, wherein the terminal penetrates the planar heating element, wherein the planar heating element is not exposed to outside the case, and wherein the electrical energy generated by the fuel cells is supplied to the planar heating element through a connector installed in the case. 12. The fuel cell stack of claim 11 , wherein bypass flow paths communicating with an air inlet manifold or a hydrogen inlet manifold of the fuel cell stack so that air or hydrogen from the air inlet manifold or the hydrogen inlet manifold is distributed to and passes through the bypass flow paths, are formed in the case, and the respective bypass flow paths communicate with an air outlet manifold or a hydrogen outlet manifold of the fuel cell stack, and are provided to discharge air or hydrogen passing through the interior of the bypass flow paths to respective outlet manifolds. 13. The fuel cell stack of claim 11 , wherein, in the case, an air inlet manifold hole communicating with an air inlet manifold of the fuel cell stack, or a hydrogen inlet manifold hole communicating with a hydrogen inlet manifold of the fuel cell stack, is provided, an air outlet manifold hole communicating with an air outlet manifold of the fuel cell stack, or a hydrogen outlet manifold hole communicating with a hydrogen outlet manifold of the fuel cell stack, is provided, and an air bypass flow path connecting the air inlet manifold hole and the air outlet manifold hole, or a hydrogen bypass flow path connecting the hydrogen inlet manifold hole and the hydrogen outlet manifold hole, is provided. 14. The fuel cell stack of claim 11 , wherein the case is made of an electrically non-conductive material. 15. The fuel cell stack of claim 11 , wherein the case is made of an electrically and thermally non-conductive material. 16. The fuel cell stack of claim 11 , further comprising: a thermal insulation pad which is stacked and interposed between the planar heating element and an inner surface of the accommodating groove of the case. 17. The fuel cell stack of claim 11 , wherein the planar heating element includes: a heating element which performs a heating operation by being supplied with electric power; and a sheath which covers the heating element so as to electrically insulate the heating element from the outside. 18. The fuel cell stack of cla