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An initiation block for connecting a detonator with a detonating cord has a body that includes opposing first and second faces and a first and a second chamber extending between the opposing faces. The first chamber is formed by a first bore serially arranged with a second bore, which is shaped to s

An initiation block for connecting a detonator with a detonating cord has a body that includes opposing first and second faces and a first and a second chamber extending between the opposing faces. The first chamber is formed by a first bore serially arranged with a second bore, which is shaped to seat the detonator adjacent to the second face. The second chamber is parallel with the first chamber and shaped complementary to the detonating cord. A passage provides communication between the first chamber and the second chamber. A booster is positioned in the first bore, proximate to the first face, and along the passage. The body further has an opening that provides communication between an exterior of the body and a portion of the chamber between the booster and the detonator.

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1. An apparatus for use in a wellbore, comprising: a work string;a downhole tool conveyed by the work string, the downhole tool having a fluid tight interior, a detonating cord, and a detonator; andan initiation block disposed inside the fluid tight interior, the initiation block comprising a body h

1. An apparatus for use in a wellbore, comprising: a work string;a downhole tool conveyed by the work string, the downhole tool having a fluid tight interior, a detonating cord, and a detonator; andan initiation block disposed inside the fluid tight interior, the initiation block comprising a body having: a first face;a second face opposing the first face;a first chamber extending between the opposing faces and through the body, the first chamber being formed by a first bore serially arranged with a second bore, the second bore seating the detonator adjacent to the second face;a second chamber extending between the opposing faces and through the body, the second chamber being parallel with the first chamber, the second chamber receiving the detonating cord;a passage formed in a wall separating the first chamber and the second chamber, the passage providing the only communication inside of the body between the first chamber and the second chamber;a booster positioned in the first bore and proximate to the first face, the booster positioned along the passage; andan opening formed in the body, the opening providing fluid communication between an exterior of the body and a portion of the first chamber between the booster and the detonator. 2. The apparatus of claim 1, wherein the detonating cord extends through the first face of the body and an end of the detonating cord projects out of the second face of the body. 3. The apparatus of claim 1, wherein the detonator is activated using an electric signal. 4. The apparatus of claim 1, wherein a gap separates the booster from the detonator, wherein the gap is configured to form a liquid column that separates the booster from the detonator using any liquid that flows through the opening. 5. The apparatus of claim 1, wherein the body is elongated. 6. An initiation block for connecting a detonator with a detonating cord, the initiating block comprising: a body having: a first face;a second face opposing the first face;a first chamber extending between the opposing faces and through the body, the first chamber being formed by a first bore serially arranged with a second bore, the second bore seating the detonator adjacent to the second face;a second chamber extending between the opposing faces and through the body, the second chamber being parallel with the first chamber, the second chamber receiving the detonating cord;a passage formed in a wall separating the first chamber and the second chamber, the passage providing the only communication inside of the body between the first chamber and the second chamber;a booster positioned in the first bore and proximate to the first face, the booster positioned along the passage; andan opening formed in the body, the opening providing fluid communication between an exterior of the body and a portion of the first chamber between the booster and the detonator. 7. The initiation block of claim 6, wherein the first and the second chambers are cylindrical bores that are geometrically parallel, and wherein the passage communicates energy in a direction transverse to the cylindrical bores. 8. The initiation block of claim 6, wherein a gap separating the booster and the detonator is configured to form a liquid column formed of liquid flowing through the opening. 9. The initiation block of claim 6, wherein the second chamber extends completely through the body. 10. The initiation block of claim 6, wherein the opening extends from an outer surface of the body and terminates at the first chamber. 11. A method for activating a downhole tool in a wellbore, comprising: forming a downhole tool to have at least a fluid tight interior, a detonating cord, and a detonator;disposing an initiation block inside the fluid tight interior, the initiating block comprising a body having: a first face;a second face opposing the first face;a first chamber extending between the opposing faces and through the body, the first chamber being formed by a first bore serially arranged with a second bore, the second bore seating the detonator adjacent to the second face;a second chamber extending between the opposing faces and through the body, the second chamber being parallel with the first chamber, the second chamber receiving the detonating cord;a passage formed in a wall separating the first chamber and the second chamber, the passage providing the only communication inside of the body between the first chamber and the second chamber;a booster positioned in the first bore and proximate to the first face, the booster positioned along the passage; andan opening formed in the body, the opening providing fluid communication between an exterior of the body and a portion of the first chamber between the booster and the detonator;connecting the downhole tool to the work string;conveying the downhole tool through the wellbore using the work string; andtransmitting an electric firing signal to the detonator.