Inkjet recording device and manufacturing method for same

The invention claimed is: 1. An inkjet recording device comprising: at least one inkjet head having a pressure chamber that communicates with a nozzle and being configured to eject ink from the nozzle, the ink communicating with the pressure chamber; a first pressure source configured to adjust energy per unit volume of the ink so that the ink generates “energy per unit volume” P1(Pa), relative to static ink at an atmospheric pressure at a position having a height of an opening of the nozzle; a second pressure source configured to adjust energy per unit volume of the ink so that the ink generates “energy per unit volume” P2(Pa), relative to static ink at an atmospheric pressure at the position having the height of the opening of the nozzle; and a hardware processor, wherein the first pressure source, the pressure chamber, and the second pressure source are connected in this order by a flow path, assuming that a pressure loss occurring from the first pressure source to the nozzle due to a circulation flow rate is ΔPa, a constant of proportionality of a differential pressure (P1−P2) and ΔPa is “a”, and an appropriate pressure that is generated in a vicinity of the opening of the nozzle is Pn, the hardware processor is configured to control pressure so that a relation P2={Pn−(1−a)P1}/a is established. 2. The inkjet recording device according to claim 1 , wherein, assuming that a limit value of P1 at which the ink overflows from the nozzle during non-circulation due to the differential pressure (P1−P2) being 0(Pa) is P11, and a limit value of P1 at which the ink overflows from the nozzle during circulation due to the differential pressure (P1−P2) being any value other than 0 is P12, a relation ΔPa=|P12−P11| is established. 3. The inkjet recording device according to claim 1 , wherein, assuming that a pressure loss occurring at the time of ejecting the ink from the nozzle is ΔPb, a diameter of the nozzle is “d”, and a surface tension of the ink is σ, Pn is a value less than 0(Pa) and greater than a value obtained from −(4σ/d−a(P1−P2)−ΔPb). 4. The inkjet recording device according to claim 3 , wherein, assuming that a limit value of P1 at which air bubbles are caught from the nozzle at the time of non-ejection during circulation is P13, and a limit value of P1 at which air bubbles are caught from the nozzle at the time of ejection during circulation is P14, a relation ΔPb=|P14−P13| is established. 5. A method for manufacturing an inkjet recording device, the inkjet recording device comprising: at least one inkjet head having a pressure chamber that communicates with a nozzle and being configured to eject ink from the nozzle, the ink communicating with the pressure chamber; a first pressure source configured to adjust energy per unit volume of the ink so that the ink generates “energy per unit volume” P1(Pa), relative to static ink at an atmospheric pressure at a position having a height of an opening of the nozzle; and a second pressure source configured to adjust energy per unit volume of the ink so that the ink generates “energy per unit volume” P2(Pa), relative to static ink at an atmospheric pressure at the position having the height of the opening of the nozzle, the first pressure source, the pressure chamber, and the second pressure source being connected in this order by a flow path, the method comprising: assuming that a pressure loss occurring from the first pressure source to the nozzle due to a circulation flow rate is ΔPa, calculating a constant of proportionality “a” of a differential pressure (P1−P2) and ΔPa; and assuming that an appropriate pressure that is generated in a vicinity of the opening of the nozzle is Pn, designing so that a relation P2={Pn−(1−a)P1}/a is established. 6. The method for manufacturing the inkjet recording device according to claim 5 , further comprising: assuming that a limit value of P1 at which the ink overflows from the nozzle during non-circulation due to the differential pressure (P1−P2) being 0(Pa) is P11, and a limit value of P1 at which the ink overflows from the nozzle during circulation due to the differential pressure (P1−P2) being any value other than 0 is P12, determining P11 and P12 by varying the values P1 and P2 while maintaining the differential pressure (P1−P2) at any value; calculating ΔPa from a relation ΔPa=|P12−P11|; and calculating “a” from a correlation of the differential pressure (P1−P2) and ΔPa. 7. The method for manufacturing the inkjet recording device according to claim 5 , further comprising, assuming that a pressure loss occurring at the time of ejecting the ink from the nozzle is ΔPb, a diameter of the nozzle is “d”, and a surface tension of the ink is σ, setting Pn at a value less than 0(Pa) and greater than a value obtained from −(4σ/d−a(P1−P2)−ΔPb). 8. The method for manufacturing the inkjet recording device according to claim 7 , further comprising: assuming that a limit value of P1 at which air bubbles are caught from the nozzle at the time of non-ejection during circulation is P13, and a limit value of P1 at which air bubbles are caught from the nozzle at the time of ejection during circulation is P14, determining P13 and P14 by varying the values P1 and P2 while maintaining the differential pressure (P1−P2) at any value other than 0; and calculating ΔPb from a relation ΔPb=|P14−P13|.