Soft robotic actuators

What is claimed is: 1. A soft body robotic device, comprising: a flexible molded body having a plurality of interconnected chambers disposed within the molded body, wherein a portion of the molded body is comprised of an elastically extensible material and a portion of the molded body is strain limiting relative to the elastically extensible material, and wherein the thickness of the molded body is at least 1 mm; and a pressurizing inlet that is configured to receive fluid for the plurality of interconnected chambers, wherein the molded body is configured to preferentially expand when the plurality of interconnected chambers are pressurized by the fluid, causing a bending motion around the strain limiting portion of the molded body; and wherein the strain limiting portion has a wall thickness greater than other portions of the flexible molded body. 2. The soft robotic device of claim 1 , wherein the device is free of a rigid weight-bearing skeleton. 3. The soft robotic device of claim 1 , wherein the strain limiting portion or member is formed using a material with higher elastic modulus compared to that of a material forming other portions of the flexible molded body. 4. The soft robotic device of claim 1 , wherein the molded body comprises a reinforcing material to increase toughness and resistance to damage. 5. The soft robotic device of claim 1 , wherein the flexible molded body and the plurality of interconnected chambers each have a longitudinal axis, and wherein the longitudinal axes of the plurality of interconnected chambers are positioned and arranged at an angle with respect to the longitudinal axis of the flexible molded body, wherein the angle is between zero and 90 degrees. 6. The soft robotic device of claim 1 , wherein a thickness of the flexible molded body is in the range of about 5 mm and 5 cm. 7. The soft robotic device of claim 1 , wherein the flexible molded body further includes a functional feature disposed on a surface of the flexible molded body. 8. The soft robotic device of claim 7 , wherein the functional feature is one or more features selected from the group consisting of a traction layer, a bidirectional fabric layer, a camouflage layer, a self-healing layer, suction cups and magnets. 9. The soft robotic device of claim 8 , wherein the self-healing layer comprises a self-sealing layer disposed on a portion of the flexible molded body, wherein the self-sealing layer includes a material of lower elastic modulus compared to that of a material forming the flexible molded body. 10. The soft robotic device of claim 8 , wherein the camouflaging layer includes a plurality of fluid chambers and a plurality of fluid inlets, wherein each of the plurality of fluid chambers is in fluid communication with one of the plurality of fluid inlets. 11. A method of camouflaging a soft robotic device, the method comprising: providing a soft robot according to claim 10 ; and providing fluid of a first characteristic to a first of the plurality of fluid inlets. 12. The method of claim 11 , wherein the fluid of the first characteristic includes a pigment. 13. The method of claim 11 , wherein the fluid of the first characteristic includes a fluorescence material. 14. The method of claim 11 , wherein the fluid of the first characteristic includes a phosphorescence material. 15. The method of claim 11 , further comprising providing fluid of a second characteristic to a second of the plurality of fluid inlets, wherein the second characteristic is different from the first characteristic. 16. The soft robotic device of claim 1 , further comprising a pressure source configured to be in fluid communication with the pressurizing inlet, wherein the pressure source is configured to provide the fluid. 17. The soft robotic device of claim 16 , wherein the pressure source includes a microcompressor or a water electrolyzer. 18. A gripping device comprising a plurality of actuatable arms, wherein each of the plurality of actuatable arms includes a soft robotic device of claim 1 , wherein the plurality of actuatable arms are configured to bend from a first resting position to a second actuated position upon pressurization. 19. The gripping device of claim 18 , wherein the gripping device is configured to lift loads in a range of greater than 80 g and/or of a size that is greater than 1 cm. 20. A method of gripping comprising: providing a gripping device according to claim 18 ; and initiating a series pressurizations and depressurizations that bring the gripping device in gripping contact with a target object. 21. A method of actuation comprising: providing a soft robotic device according to claim 1 ; and providing sufficient pressure to the soft robotic device or the gripping device or the soft robot or the pressurizable network or the soft machine to cause a less stiff wall to expand preferentially, thereby causing the soft robotic device or the gripping device or the soft robot or the pressurizable network or the soft machine to bend around a strain limiting member of the soft robotic device or the gripping device or the soft robot or the pressurizable network or the soft machine. 22. A soft robotic device, comprising: a flexible molded body comprising a plurality of interconnected pleated chambers, the flexible molded body being comprised of a flexible material and affixed to a strain limiting member in such a manner that the strain limiting member forms a wall of the plurality of interconnected pleated chamber, wherein a thickness of the molded body is at least 1 mm; and a pressurizing inlet that is configured to receive fluid for the plurality of interconnected pleated chamber, wherein the plurality of interconnected pleated chambers are configured to preferentially unfold when the flexible molded body is pressurized through the pressurizing inlet, causing bending motion around the strain limiting member; and wherein the strain limiting member has a wall thickness greater than other portions of the flexible molded body. 23. A soft robotic device capable of extension, comprising: a flexible molded body having a plurality of interconnected chambers disposed within the molded body; and a sealing member in a facing relationship with the flexible molded body, wherein the flexible molded body and the sealing member together define a plurality of channels, said channel defined by upper, lower and side walls, and wherein the sealing member is in a state of compression in its resting state and a pressurizing inlet in fluid communication with the plurality of channels, the plurality of channels positioned and arranged such that the soft body robotic device expands to relieve the strain in the sealing member when the soft body robotic device is pressurized through the inlet. 24. The soft robotic device of claim 23 , wherein the sealing member comprises a strain limiting member and the molded body comprises a plurality of interconnected chambers in facing and sealing relationship with the strain limiting member, wherein the strain limiting member forms a wall of a chamber. 25. The soft robotic device of claim 24 , wherein the soft robotic device further comprises a second plurality of interconnected chambers in facing and sealing relationship with the strain limiting member on a face opposite to the first plurality of interconnected chambers. 26. The soft robotic device of claim 23 , wherein the seali