Heat storage composition, heat storage member, electronic device, and manufacturing method of heat storage member

What is claimed is: 1. A heat storage composition comprising: a heat storage material; and a flame retardant, wherein Condition A is satisfied, Condition A: a gas generation temperature Tr of the flame retardant obtained by Measuring Method A1 is lower than a gas generation temperature Ta of a specific composition obtained by Measuring Method A2, Measuring Method A1: a type and a content of the flame retardant contained in the heat storage composition are identified, a weight change of the flame retardant due to heating is measured by using a thermogravimeter-differential thermal analyzer, and a relational expression, which is represented by Expression (A1), between a temperature T (° C.) and a weight reduction ratio Δma(T) of the flame retardant is derived based on a measurement result, Δ ma ( T )=( ma 0 −ma ( T ))/( ma 0 )  (A1) in Expression (A1), ma(T) represents a weight of the flame retardant at the temperature T (° C.) and ma 0 represents a weight of the flame retardant before heating, a temperature at which the weight reduction ratio Δma(T) of the flame retardant reaches 2% by mass is obtained by using Expression (A1), and the obtained temperature is defined as the gas generation temperature Tr (° C.) of the flame retardant, Measuring Method A2: a weight change of the heat storage composition due to heating is measured by using the thermogravimeter-differential thermal analyzer, and a relational expression, which is represented by Expression (A2), between the temperature T (° C.) and a weight reduction ratio Δm1(T) of the heat storage composition is derived based on a measurement result, Δ m 1( T )=( m 1 0 −m 1( T ))/( m 1 0 )  (A2) in Expression (A2), m1(T) represents a weight of the heat storage composition at the temperature T (° C.) and m1 0 represents a weight of the heat storage composition before heating, further, a type and a content of a solvent, which is contained in the heat storage composition and has a boiling point of 100° C. or lower, are identified; as a result of measurement, in a case in which the heat storage composition contains the solvent, a weight change of the solvent due to heating is measured by using the thermogravimeter-differential thermal analyzer, and a relational expression, which is represented by Expression (A3), between the temperature T (° C.) and a weight reduction ratio Δmb(T) of the solvent is derived based on a measurement result, Δ mb ( T )=( mb 0 −mb ( T ))/( mb 0 )  (A3) in Expression (A3), mb(T) represents a weight of the solvent at the temperature T (° C.) and mb 0 represents a weight of the solvent before heating, a relational expression, which is represented by Expression (A4), between the temperature T (° C.) and a weight reduction ratio Δmx(T) of the specific composition obtained by removing the flame retardant and the solvent from the heat storage composition is derived, Δ mx ( T )=(100*Δ m 1( T )− a*Δma ( T )− b*Δmb ( T ))/(100− a−b )  (A4) in Expression (A4), a represents a ratio (% by mass) of the content of the flame retardant to a total mass of the heat storage composition, b represents a ratio (% by mass) of the content of the solvent to the total mass of the heat storage composition, and Δma(T) represents the weight reduction ratio of the flame retardant obtained by Measuring Method A1, a temperature at which the weight reduction ratio Δmx(T) of the specific composition reaches 2% by mass is obtained by using Expression (A4), and the obtained temperature is defined as the gas generation temperature Ta (° C.) of the specific composition. 2. The heat storage composition according to claim 1 , wherein the heat storage material contains paraffin. 3. The heat storage composition according to claim 1 , wherein a content of the heat storage material to the total mass of the heat storage composition is 70% by mass or more. 4. The heat storage composition according to claim 1 , wherein the content of the flame retardant to a content of the heat storage material is 0.1% by mass or more. 5. The heat storage composition according to claim 1 , wherein the flame retardant contains at least one selected from the group consisting of diammonium hydrogen phosphate, ammonium dihydrogen phosphate, and trimethyl phosphate. 6. The heat storage composition according to claim 1 , wherein the flame retardant contains at least one selected from the group consisting of diammonium hydrogen phosphate and ammonium dihydrogen phosphate. 7. The heat storage composition according to claim 1 , wherein the gas generation temperature Tr of the flame retardant is 100° C. or higher. 8. The heat storage composition according to claim 1 , wherein the heat storage composition is sheet-shaped. 9. A heat storage member comprising: a heat storage material; and a flame retardant, wherein Condition C is satisfied, Condition C: a gas generation temperature Tr of the flame retardant obtained by Measuring Method C1 is lower than a gas generation temperature Tc of a specific member obtained by Measuring Method C2, Measuring Method C1: a type and a content of the flame retardant contained in the heat storage member are identified, a weight change of the flame retardant due to heating is measured by using a thermogravimeter-differential thermal analyzer, and a relational expression, which is represented by Expression (C1), between a temperature T (° C.) and a weight reduction ratio Δma(T) of the flame retardant is derived based on a measurement result, Δ ma ( T )=( ma 0 −ma ( T ))/( ma 0 )  (C1) in Expression (C1), ma(T) represents a weight of the flame retardant at the temperature T (° C.) and ma 0 represents a weight of the flame retardant before heating, a temperature at which the weight reduction ratio Δma(T) of the flame retardant reaches 2% by mass is obtained by using Expression (C1), and the obtained temperature is defined as the gas generation temperature Tr (° C.) of the flame retardant, Measuring Method C2: a weight change of the heat storage member due to heating is measured by using the thermogravimeter-differential thermal analyzer, and a relational expression, which is represented by Expression (C2), between the temperature T (° C.) and a weight reduction ratio Δm3(T) of the heat storage member is derived based on a measurement result, Δ m 3( T )=( m 3 0 −m 3( T ))/( m 3 0 )  (C2) in Expression (C2), m3(T) represents a weight of the heat storage member at the temperature T (° C.) and m3 0 represents a weight of the heat storage member before heating, further, a type and a content of a solvent, which is contained in the heat storage member and has a boiling point of 100° C. or lower, are identified; as a result of measurement, in a case in which the heat storage member contains the solvent, a weight change of the solvent due to heating is measured by using the thermogravimeter-differential thermal analyzer, and a relational expression, which is represented by Expression (C3), between the temperature T (° C.) and a weight reduction ratio Δmb(T) of the solvent is derived based on a measurement result, Δ mb ( T )=( mb 0 −mb ( T ))/( mb 0 )  (C3) in Expression (C3), mb(T) represents a weight of the solvent at the temperature T (° C.) and mb 0 represents a weight of the solvent before heating, a relational expression, which is represented by Expression (C4), between the temperature T (° C.) and a weight reduction ratio Δmz(T) of the specific member obtained by removing the flame retardant and the solvent from the heat storage member is derived, Δ mz ( T )=(100*Δ m 3( T )− a*Δma ( T )− b*Δmb ( T ))/(100− a−b )  (C4) in Expression (C4), a represents a ratio (% by mass) of the content of the flame retard