Fuel vapor processing device

What is claimed is: 1. A fuel vapor processing device configured to recover fuel vapor generated in a fuel tank that stores fuel of an internal combustion engine, the fuel vapor processing device comprising: a canister that includes an absorbent configured to absorb fuel vapor generated in the fuel tank; a fuel vapor path member that forms a fuel vapor path that communicatively connects the canister and the fuel tank; a canister path member that forms a canister path that communicates with the canister; an atmosphere path member that forms an atmosphere path that communicates with an atmosphere; a pressure detection path member that forms a pressure detection path configured to communicate with the canister path; a first switching valve configured to switch between communication between the canister path and the pressure detection path and communication between the canister path and the atmosphere path; a pressurizing/depressurizing unit configured to depressurize or pressurize an inside of the canister when the first switching valve communicatively connects the canister path and the pressure detection path; a bypass path member that forms a switching valve bypass path that bypasses the first switching valve, and communicatively connects the canister path and the pressure detection path; a narrowing portion disposed in the bypass path member; a differential pressure detection path connected to the fuel vapor path member and the pressure detection path member to conduct pressure in the fuel vapor path and pressure in the pressure detection path; a differential pressure detection unit provided to the differential pressure detection path and configured to detect a difference between a pressure inside the fuel tank or an atmospheric pressure and a pressure of the pressure detection path, and output a signal indicating the difference; a sealing valve disposed in the fuel vapor path member or the canister path member, and configured to isolate the fuel tank from the canister, or isolate the canister from the pressurizing/depressurizing unit; and a control unit that electrically connects with the first switching valve, the pressurizing/depressurizing unit, the sealing valve, and the differential pressure detection unit, and is configured to determine presence or absence of a fuel vapor leak while controlling operations of the first switching valve, the pressurizing/depressurizing unit, and the sealing valve, based on a signal output from the differential pressure detection unit. 2. The fuel vapor processing device according to claim 1 , wherein the control unit is configured to calculate the pressure inside the fuel tank, based on a signal output from the differential pressure detection unit when the pressure of the pressure detection path is the atmospheric pressure. 3. The fuel vapor processing device according to claim 1 , wherein: the control unit is configured to calculate a base difference value, based on a signal output from the differential pressure detection unit when isolation between the fuel tank and the canister via the sealing valve, and communication between the canister path and the atmosphere path via the first switching valve are both achieved in a stopping state of the pressurizing/depressurizing unit, the control unit is configured to calculate a reference difference value based on a signal output from the differential pressure detection unit when isolation between the fuel tank and the canister via the sealing valve, and communication between the canister path and the atmosphere path via the first switching valve are both achieved in an operating state of the pressurizing/depressurizing unit, the control unit is configured to calculate a determination difference value based on a signal output from the differential pressure detection unit when isolation between the fuel tank and the canister via the sealing valve, and communication between the canister path and the pressure detection path via the first switching valve are both achieved in the operating state of the pressurizing/depressurizing unit, and the control unit is configured to determine presence or absence of a leak from the canister based on a magnitude relationship between a reference value that is a difference between the reference difference value and the base difference value, and a determination value that is a difference between the determination difference value and the base difference value. 4. The fuel vapor processing device according to claim 3 , wherein: the control unit calculates an end value that is a pressure inside the fuel tank before determination of presence or absence of a leak from the canister based on the magnitude relationship between the reference value and the determination value, and the control unit compares the base difference value and the end value. 5. The fuel vapor processing device according to claim 1 , wherein: the control unit is configured to calculate a base difference value based on a signal output from the differential pressure detection unit when isolation between the fuel tank and the canister via the sealing valve, and communication between the canister path and the atmosphere path via the first switching valve are both achieved in a stopping state of the pressurizing/depressurizing unit, the control unit is configured to calculate a reference difference value based on a signal output from the differential pressure detection unit when isolation between the fuel tank and the canister via the sealing valve, and communication between the canister path and the atmosphere path via the first switching valve are both achieved in an operating state of the pressurizing/depressurizing unit, the control unit is configured to calculate a differential maximum value based on a signal output from the differential pressure detection unit when the pressurizing/depressurizing unit is stopped after sequential achievement of communication between the fuel tank and the canister via the sealing valve, isolation between the fuel tank and the canister via the sealing valve, and communication between the canister path and the atmosphere path via the first switching valve after the isolation between the fuel tank and the canister via the sealing valve in the operating state of the pressurizing/depressurizing unit, and the control unit is configured to determine presence or absence of a fuel vapor leak based on a magnitude relationship between a reference value that is a difference between the reference difference value and the base difference value, and the differential maximum value. 6. The fuel vapor processing device according to claim 1 , further comprising a purge valve disposed between an intake system of the internal combustion engine and the canister, electrically connected to the control unit, and configured to isolate the intake system from the canister, wherein the control unit is configured to control an operation of the purge valve, and the control unit is configured to determine states of the purge valve and the sealing valve based on a signal output from the differential pressure detection unit. 7. The fuel vapor processing device according to claim 1 , wherein the control unit controls opening and closing of the sealing valve, based on a signal output from the differential pressure detection unit during refueling of the fuel tank. 8. The fuel vapor processing device according to claim 7 , wherein the control unit causes the sealing valve to close when a difference that is a difference between a pressure of the fuel vapor path and a pressure of the pressure detection path and that is calculated based on a signal output from the differential pressure detection unit falls within a predetermined range including “0”.