Method for hydrogen production by pressure swing adsorption

The invention claimed is: 1. A method for hydrogen production by pressure swing adsorption, comprising: providing four adsorption columns for generating a product gas from a feed gas containing a hydrogen component and a flammable component other than the hydrogen component by causing an adsorption target component other than the hydrogen component to be adsorbed onto an adsorbent, and an off-gas tank into which an off-gas discharged from the adsorption columns is recovered and from which the recovered off-gas is supplied to a combustion device; performing an adsorption step for a unit processing period in one of the four adsorption columns, performing a pressure-equalization discharge step for the unit processing period in the adsorption column in which the step subsequent to the adsorption step is performed, performing a desorption step for the unit processing period in the adsorption column in which the step subsequent to the pressure-equalization discharge step is performed, performing a pressure-restoring step as a pre-step of the adsorption step for the unit processing period in the adsorption column in which the step subsequent to the desorption step is performed, and recovering the off-gas discharged from the adsorption column in which the desorption step is performed into the off-gas tank; providing a vacuum pump for supplying the off-gas suctioned from the adsorption column to the combustion device, the vacuum pump being switchable between an adsorption column-operated state in which the vacuum pump performs suctioning with respect to the adsorption column and a tank-operated state in which the vacuum pump performs suctioning with respect to a vacuum tank; wherein the vacuum tank is provided so as to be switchable between a communication state in which the vacuum tank is in communication with the adsorption column and a blocked state in which the communication with the adsorption column is blocked, wherein with respect to the pressure-equalization discharge step, in an initial stage of the unit processing period, an upstream discharge step of supplying a gas inside the adsorption column in the pressure-equalization discharge step to the adsorption column in the pressure-restoring step is performed, and in a final stage of the unit processing period, a downstream discharge step of supplying the gas inside the adsorption column in the pressure-equalization discharge step to the adsorption column in the desorption step is performed, wherein in the final stage of the unit processing period, suctioning of the vacuum tank switched to the blocked state is performed using the vacuum pump switched to the tank-operated state, thereby discharging the off-gas in the vacuum tank and adjusting the vacuum tank to a negative pressure state, wherein with respect to the desorption step, in the initial stage of the unit processing period, a pressure-reducing step of discharging a gas inside the adsorption column in the desorption step into the off-gas tank as the off-gas is performed, in an intermediate stage of the unit processing period, a tank suction step of switching the vacuum tank adjusted to the negative pressure state to the communication state and suctioning the gas inside the adsorption column in the desorption step into the vacuum tank and a pump suction step of switching the vacuum tank to the blocked state and performing suctioning of the adsorption column in the desorption step using the vacuum pump switched to the adsorption column-operated state are performed successively, and in the final stage of the unit processing period, a downstream receiving step of receiving the gas supplied from the adsorption column in the pressure-equalization discharge step by the downstream discharge step into the adsorption column in the desorption step is performed, and wherein with respect to the pressure-restoring step, in the initial stage of the unit processing period, an upstream receiving step of receiving the gas supplied from the adsorption column in the pressure-equalization discharge step by the upstream discharge step into the adsorption column in the pressure-restoring step is performed, and then a pressure-increasing step of receiving a portion of the product gas generated in the adsorption column in the adsorption step into the adsorption column in the pressure-restoring step is performed. 2. The method for hydrogen production by pressure swing adsorption according to claim 1 , wherein a first tank and a second tank are provided as the off-gas tank, and wherein as the pressure-reducing step, a first pressure-reducing step in which the adsorption column in the desorption step and the first tank are allowed to communicate with each other and a second pressure-reducing step in which the adsorption column in the desorption step and the second tank are allowed to communicate with each other are performed successively, and the tank suction step is subsequently performed. 3. The method for hydrogen production by pressure swing adsorption according to claim 2 , wherein the vacuum pump is configured to supply the off-gas to the second tank. 4. The method for hydrogen production by pressure swing adsorption according to claim 2 , wherein when the first pressure-reducing step is performed, suctioning of the vacuum tank in the blocked state is performed using the vacuum pump switched to the tank-operated state. 5. The method for hydrogen production by pressure swing adsorption according to claim 1 , wherein an internal pressure of the adsorption column in the desorption step is reduced from an initial pressure at the start of the desorption step to a pressure between 40 and 60% of the initial pressure by the pressure-reducing step, and wherein the tank suction step is performed subsequently to the pressure-reducing step. 6. The method for hydrogen production by pressure swing adsorption according to claim 5 , wherein when the pressure-reducing step is performed, suctioning of the vacuum tank in the blocked state is performed using the vacuum pump switched to the tank-operated state. 7. The method for hydrogen production by pressure swing adsorption according to claim 5 , wherein a first tank that, in the pressure-reducing step, is connected to the adsorption column in the desorption step and a second tank are provided as the off-gas tank, and wherein the vacuum pump is configured to supply the off-gas to the second tank. 8. The method for hydrogen production by pressure swing adsorption according claim 1 , wherein the vacuum tank is packed with an off-gas adsorbent that adsorbs the off-gas discharged from the adsorption column. 9. The method for hydrogen production by pressure swing adsorption according to claim 8 , wherein the feed gas is generated by reforming a gas to be processed containing methane as a main component so that the feed gas contains a hydrogen component as well as methane as a flammable component other than the hydrogen component, carbon monoxide, nitrogen, carbon dioxide, and moisture, wherein the adsorbent packed in the adsorption columns is configured to contain zeolite that adsorbs carbon monoxide and nitrogen, a carbon molecular sieve that adsorbs methane and carbon dioxide, and activated alumina that adsorbs moisture, and wherein the off-gas adsorbent is a carbon molecular sieve that adsorbs methane and carbon dioxide. 10. The method for hydrogen production by pressure swing adsorption according to claim 3 , wherein when the first pressure-reducing step is performed, suctioning of the vacuum tank in the blocked state is performed using the vacuum pump switched to the tank-operated state. 11. The method for hydrogen production by pressure swing adsorption accord