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The footing is below grade, so shaping the top of the spread footing to shed water is foolish. Box the concrete in from above down there to avoid problems. Uplift from pressure on that cap then becomes an additional problem.

ACI 347 prescribes formwork design for concrete placement. For your short little columns, you just use hydrostatic pressure for design. 2'-5" tall implies (150psf)(2.5ft) = 375 psf pressure. Over a 22.5" width (call it 2'-0), that's a force at both ends of your bottom boards of 0.5(2ft)(5")(1ft/12")(375psf) = 160#. The NDS specifies that screws and nails into end grain have zero strength, so that connection down there is a definite problem, especially if you'll be doing internal vibration (with a concrete vibrator submerged in the concrete).

A cap on the free surface down there should cross the joint and provide sufficient reinforcement for its top edge. For the bottom edge, I would put dirt back around the form and hand tamp it to get a layer of soil all the way to the top of that 5" edge.

Another option is to construct each footing with a cold shut at the interface between footing and pier. I assume that there's rebar already spec'ed at the interface.

Moving up to the pier's base, the 13" width combines with a 300 psf pressure to provide 0.5(13")(1ft/12")(6")(1ft/12")(300psf) = 81# at the end of each side. The center fasteners get the same load, 0.5(13")(1ft/12")(12")(1ft/12")(150psf) = 81#. 3" long #8 screws have a withdrawal strength of about 125# and a lateral strength of about 80#. For combined loading from the pressure on both sides, that's a strength of (125#)(80#)/[(1/2)(125#) + (1/2)(80#)] = 100#. The demand is [(81#)² + (81#)²]^1/2 = 115#. The #8 screws, then, are a little out of their league with only 3 fasteners. That's with Spruce-Pine-Fir lumber, though. For Douglas Fir or Southern Pine, just 3 of those fasteners is sufficient.

Isherwood's strapping is a wise detail to avoid withdrawal load on the fasteners, so duplex nails become feasible without a mess of them. Technically, duplex nails have a withdrawal strength when installed into an edge like you have detailed, but it's only something like 40# each.

And theoretically, the capped spread footing generates 700# of uplift, [(22.5")² - (13")²](1sf/144si)(300psf), so your footings would typically be staked down (or constructed with that cold shut). To save a buck on concrete delivery, I might place just the bottom 6" or 7" at each location, vibrate, and then cycle back to the start and place the remainder, taking it easy with the vibration down low to avoid activating much of that 700#. I'd still use at least 2 stakes per form, though.

The footing is below grade, so shaping the top of the spread footing to shed water is foolish. Box the concrete in from above down there to avoid problems. Uplift from pressure on that cap then becomes an additional problem.

ACI 347 prescribes formwork design for concrete placement. For your short little columns, you just use hydrostatic pressure for design. 2'-5" tall implies (150psf)(2.5ft) = 375 psf pressure. Over a 22.5" width (call it 2'-0), that's a force at both ends of your bottom boards of 0.5(2ft)(5")(1ft/12")(375psf) = 160#. The NDS specifies that screws and nails into end grain have zero withdrawal strength, so that connection down there is a definite problem, especially if you'll be doing internal vibration (with a concrete vibrator submerged in the concrete).

A cap on the free surface down there should cross the joint and provide sufficient reinforcement for its top edge. For the bottom edge, I would put dirt back around the form and hand tamp it to get a layer of soil all the way to the top of that 5" edge.

Another option is to construct each footing with a cold joint at the interface between footing and pier. I assume that there's rebar already spec'ed at the interface.

Moving up to the pier's base, the 13" width combines with a 300 psf pressure to provide 0.5(13")(1ft/12")(6")(1ft/12")(300psf) = 81# at the end of each side. The center fasteners get the same load, 0.5(13")(1ft/12")(12")(1ft/12")(150psf) = 81#. 3" long #8 screws have a withdrawal strength of about 125# and a lateral strength of about 80#. For combined loading from the pressure on both sides, that's a strength of (125#)(80#)/[(1/2)(125#) + (1/2)(80#)] = 100#. The demand is [(81#)² + (81#)²]^1/2 = 115#. The #8 screws, then, are a little out of their league with only 3 fasteners. That's with Spruce-Pine-Fir lumber, though. For Douglas Fir or Southern Pine, just 3 of those fasteners is sufficient.

Isherwood's strapping is a wise detail to avoid withdrawal load on the fasteners, so duplex nails become feasible without a mess of them. Technically, duplex nails have a withdrawal strength when installed into an edge like you have detailed, but it's only something like 40# each.

And theoretically, the capped spread footing generates 700# of uplift, [(22.5")² - (13")²](1sf/144si)(300psf), so your footings would typically be staked down (or constructed with that cold joint). To save a buck on concrete delivery, I might place just the bottom 6" or 7" at each location, vibrate, and then cycle back to the start and place the remainder, taking it easy with the vibration down low to avoid activating much of that 700#. I'd still use at least 2 stakes per form, though.

The footing is below grade, so shaping the top of the spread footing to shed water is foolish. Box the concrete in from above down there to avoid problems.

ACI 347 prescribes formwork design for concrete placement. For your short little columns, you just use hydrostatic pressure for design. 2'-5" tall implies (150psf)(2.5ft) = 375 psf pressure. Over a 22.5" width (call it 2'-0), that's a force at both ends of your bottom boards of 0.5(2ft)(5")(1ft/12")(375psi) = 160#. The NDS specifies that screws and nails into end grain have zero strength, so that connection down there is a definite problem, especially if you'll be doing internal vibration (with a concrete vibrator submerged in the concrete).

A cap on the free surface down there should cross the joint and provide sufficient reinforcement for its top edge. For the bottom edge, I would put dirt back around the form and hand tamp it to get a layer of soil all the way to the top of that 5" edge.

Another option is to construct each footing with a cold shut at the interface between footing and pier. I assume that there's rebar already spec'ed at the interface.

Moving up to the pier's base, the 13" width combines with a 300 psf pressure to provide 0.5(13")(1ft/12")(6")(1ft/12")(300psf) = 81# at the end of each side. The center fasteners get the same load, 0.5(13")(1ft/12")(12")(1ft/12")(150psf) = 81#. 3" long #8 screws have a withdrawal strength of about 125# and a lateral strength of about 80#. For combined loading from the pressure on both sides, that's a strength of (125#)(80#)/[(1/2)(125#) + (1/2)(80#)] = 100#. The demand is [(81#)² + (81#)²]^1/2 = 115#. The #8 screws, then, are a little out of their league with only 3 fasteners.

Isherwood's strapping is a wise detail to avoid withdrawal load on the fasteners, so duplex nails become feasible without a mess of them. Technically, duplex nails have a withdrawal strength when installed into an edge like you have detailed, but it's only something like 40# each.

And theoretically, the capped spread footing generates 700# of uplift, [(22.5")² - (13")²](1sf/144si)(300psf), so your footings would typically be staked down (or constructed with that cold shut). To save a buck on concrete delivery, I might place just the bottom 6" or 7" at each location, vibrate, and then cycle back to the start and place the remainder, taking it easy with the vibration down low to avoid activating much of that 700#. I'd still use at least 2 stakes per form, though.

The footing is below grade, so shaping the top of the spread footing to shed water is foolish. Box the concrete in from above down there to avoid problems. Uplift from pressure on that cap then becomes an additional problem.

ACI 347 prescribes formwork design for concrete placement. For your short little columns, you just use hydrostatic pressure for design. 2'-5" tall implies (150psf)(2.5ft) = 375 psf pressure. Over a 22.5" width (call it 2'-0), that's a force at both ends of your bottom boards of 0.5(2ft)(5")(1ft/12")(375psf) = 160#. The NDS specifies that screws and nails into end grain have zero strength, so that connection down there is a definite problem, especially if you'll be doing internal vibration (with a concrete vibrator submerged in the concrete).

A cap on the free surface down there should cross the joint and provide sufficient reinforcement for its top edge. For the bottom edge, I would put dirt back around the form and hand tamp it to get a layer of soil all the way to the top of that 5" edge.

Another option is to construct each footing with a cold shut at the interface between footing and pier. I assume that there's rebar already spec'ed at the interface.

Moving up to the pier's base, the 13" width combines with a 300 psf pressure to provide 0.5(13")(1ft/12")(6")(1ft/12")(300psf) = 81# at the end of each side. The center fasteners get the same load, 0.5(13")(1ft/12")(12")(1ft/12")(150psf) = 81#. 3" long #8 screws have a withdrawal strength of about 125# and a lateral strength of about 80#. For combined loading from the pressure on both sides, that's a strength of (125#)(80#)/[(1/2)(125#) + (1/2)(80#)] = 100#. The demand is [(81#)² + (81#)²]^1/2 = 115#. The #8 screws, then, are a little out of their league with only 3 fasteners. That's with Spruce-Pine-Fir lumber, though. For Douglas Fir or Southern Pine, just 3 of those fasteners is sufficient.

Isherwood's strapping is a wise detail to avoid withdrawal load on the fasteners, so duplex nails become feasible without a mess of them. Technically, duplex nails have a withdrawal strength when installed into an edge like you have detailed, but it's only something like 40# each.

And theoretically, the capped spread footing generates 700# of uplift, [(22.5")² - (13")²](1sf/144si)(300psf), so your footings would typically be staked down (or constructed with that cold shut). To save a buck on concrete delivery, I might place just the bottom 6" or 7" at each location, vibrate, and then cycle back to the start and place the remainder, taking it easy with the vibration down low to avoid activating much of that 700#. I'd still use at least 2 stakes per form, though.

The footing is below grade, so shaping the top of the spread footing to shed water is foolish. Box the concrete in from above down there to avoid problems.

ACI 347 prescribes formwork design for concrete placement. For your short little columns, you just use hydrostatic pressure for design. 2'-5" tall implies (150psf)(2.5ft) = 375 psf pressure. Over a 22.5" width (call it 2'-0), that's a force at both ends of your bottom boards of 0.5(2ft)(5")(1ft/12")(375psi) = 160#. The NDS specifies that screws and nails into end grain have zero strength, so that connection down there is a definite problem, especially if you'll be doing internal vibration (with a concrete vibrator submerged in the concrete).

A cap on the free surface down there should cross the joint and provide sufficient reinforcement for its top edge. For the bottom edge, I would put dirt back around the form and hand tamp it to get a layer of soil all the way to the top of that 5" edge.

Another option is to construct each footing with a cold shut at the interface between footing and pier. I assume that there's rebar already spec'ed at the interface.

Moving up to the pier's base, the 13" width combines with a 300 psf pressure to provide 0.5(13")(1ft/12")(6")(1ft/12")(300psf) = 81# at the end of each side. The center fasteners get the same load, 0.5(13")(1ft/12")(12")(1ft/12")(150psf) = 81#. 3" long #8 screws have a withdrawal strength of about 125# and a lateral strength of about 80#. For combined loading from the pressure on both sides, that's a strength of (125#)(80#)/[(1/2)(125#) + (1/2)(80#)] = 100#. The demand is [(81#)² + (81#)²]^1/2 = 115#. The #8 screws, then, are a little out of their league with only 3 fasteners.

Isherwood's strapping is a wise detail to avoid withdrawal load on the fasteners, so duplex nails become feasible without a mess of them. Technically, duplex nails have a withdrawal strength when installed into an edge like you have detailed, but it's only something like 40# each.

And theoretically, the capped spread footing generates 700# of uplift, [(22.5")² - (13")²](1sf/144si)(300psf), so your footings would typically be staked down (or constructed with that cold shut).

The footing is below grade, so shaping the top of the spread footing to shed water is foolish. Box the concrete in from above down there to avoid problems.

ACI 347 prescribes formwork design for concrete placement. For your short little columns, you just use hydrostatic pressure for design. 2'-5" tall implies (150psf)(2.5ft) = 375 psf pressure. Over a 22.5" width (call it 2'-0), that's a force at both ends of your bottom boards of 0.5(2ft)(5")(1ft/12")(375psi) = 160#. The NDS specifies that screws and nails into end grain have zero strength, so that connection down there is a definite problem, especially if you'll be doing internal vibration (with a concrete vibrator submerged in the concrete).

A cap on the free surface down there should cross the joint and provide sufficient reinforcement for its top edge. For the bottom edge, I would put dirt back around the form and hand tamp it to get a layer of soil all the way to the top of that 5" edge.

Another option is to construct each footing with a cold shut at the interface between footing and pier. I assume that there's rebar already spec'ed at the interface.

Moving up to the pier's base, the 13" width combines with a 300 psf pressure to provide 0.5(13")(1ft/12")(6")(1ft/12")(300psf) = 81# at the end of each side. The center fasteners get the same load, 0.5(13")(1ft/12")(12")(1ft/12")(150psf) = 81#. 3" long #8 screws have a withdrawal strength of about 125# and a lateral strength of about 80#. For combined loading from the pressure on both sides, that's a strength of (125#)(80#)/[(1/2)(125#) + (1/2)(80#)] = 100#. The demand is [(81#)² + (81#)²]^1/2 = 115#. The #8 screws, then, are a little out of their league with only 3 fasteners.

Isherwood's strapping is a wise detail to avoid withdrawal load on the fasteners, so duplex nails become feasible without a mess of them. Technically, duplex nails have a withdrawal strength when installed into an edge like you have detailed, but it's only something like 40# each.

And theoretically, the capped spread footing generates 700# of uplift, [(22.5")² - (13")²](1sf/144si)(300psf), so your footings would typically be staked down (or constructed with that cold shut). To save a buck on concrete delivery, I might place just the bottom 6" or 7" at each location, vibrate, and then cycle back to the start and place the remainder, taking it easy with the vibration down low to avoid activating much of that 700#. I'd still use at least 2 stakes per form, though.