In one aspect, 3D printing systems for fabricating 3D soap objects are described herein. Such systems can form 3D soap objects from a particulate material and a fluid binder material based on design data, such as digital design data. In some cases, a 3D printing system comprises a build chamber comprising a build bed, a particulate material distribution device, and a fluid binder material dispenser. The particulate material distribution device can be configured to distribute successive layers of the particulate material on the build bed. The fluid binder material dispenser can be configured to selectively apply the fluid binder material to portions of the successive layers of particulate material in an amount sufficient to consolidate the portions to define cross-sectional portions of the object. In addition, the particulate material comprises a soap component in an amount of about 10 to 100% by weight.

In one aspect, 3D printing systems for fabricating 3D soap objects are described herein. Such systems can form 3D soap objects from a particulate material and a fluid binder material based on design data, such as digital design data. In some cases, a 3D printing system comprises a build chamber comprising a build bed, a particulate material distribution device, and a fluid binder material dispenser. The particulate material distribution device can be configured to distribute successive layers of the particulate material on the build bed. The fluid binder material dispenser can be configured to selectively apply the fluid binder material to portions of the successive layers of particulate material in an amount sufficient to consolidate the portions to define cross-sectional portions of the object. In addition, the particulate material comprises a soap component in an amount of about 10 to 100% by weight.

A bar of soap is made so as to be more easily held without slipping by providing one or more finger-width slots along a side of the bar of soap.

A bar of soap is made so as to be more easily held without slipping by providing one or more finger-width slots along a side of the bar of soap.

The present invention relates to a solid concentrate composition comprising: (a) from 5% to 25% by weight of zinc pyrithione (ZPT); (b) from 8% to 85% by weight of at least one surfactant, preferably, wherein the solid concentrate composition has a penetration hardness of between 20 N and 50 N according to the test method as disclosed herein.

The present invention relates to a solid concentrate composition comprising: (a) from 5% to 25% by weight of zinc pyrithione (ZPT); (b) from 8% to 85% by weight of at least one surfactant, preferably, wherein the solid concentrate composition has a penetration hardness of between 20 N and 50 N according to the test method as disclosed herein.

The present invention relates to a solid concentrate composition comprising: (a) from 5% to 25% by weight of zinc pyrithione (ZPT); (b) from 8% to 85% by weight of at least one surfactant, preferably, wherein the solid concentrate composition has a penetration hardness of between 20 N and 50 N according to the test method as disclosed herein.

The present invention relates to a solid concentrate composition comprising: (a) from 5% to 25% by weight of zinc pyrithione (ZPT); (b) from 8% to 85% by weight of at least one surfactant, preferably, wherein the solid concentrate composition has a penetration hardness of between 20 N and 50 N according to the test method as disclosed herein.

Methods and systems for making artificial flowers are disclosed. The method can include wrapping a first flower wrapper having between 1 and 5 petals around a foam core to form a first flower construct, or bud. The method can include wrapping a second flower wrapper having between 1 and 5 petals around the first flower construct, or bud. The method can include wrapping a third flower wrapper having between 1 and 5 petals around the second flower construct. The method can include wrapping additional layers of flower wrappers around flower constructs, including, but not limited to, 3 more layers of flower wrappers. Wrapping a flower wrapper around a core or a flower construct may be done manually or in an automated fashion. Wrapping a flower wrapper around a core or a flower construct may be done petal by petal or all petals simultaneously.

Methods and systems for making artificial flowers are disclosed. The method can include wrapping a first flower wrapper having between 1 and 5 petals around a foam core to form a first flower construct, or bud. The method can include wrapping a second flower wrapper having between 1 and 5 petals around the first flower construct, or bud. The method can include wrapping a third flower wrapper having between 1 and 5 petals around the second flower construct. The method can include wrapping additional layers of flower wrappers around flower constructs, including, but not limited to, 3 more layers of flower wrappers. Wrapping a flower wrapper around a core or a flower construct may be done manually or in an automated fashion. Wrapping a flower wrapper around a core or a flower construct may be done petal by petal or all petals simultaneously.