公开(公告)号：US10859305B1

公开(公告)日：2020-12-08

申请号：US16528511

申请日：2019-07-31

Applicant: Daniel Scott Ellis ,  William Grant Moon ,  Steven Victor Boyce ,  Steven Joseph Parkinson

Inventor： Daniel Scott Ellis ,  William Grant Moon ,  Steven Victor Boyce ,  Steven Joseph Parkinson

IPC: F25D21/04 ,  F25D3/10 ,  F25B19/00 ,  F25D29/00

Abstract: The present invention is a high-performance ultra-low temperature chest freezer capable of reaching temperatures as low as −160° C. within several hours with the capability to automatically and continually defrost and dehumidify its payload bay before, during, and after a door open event without needing to cease freezing operations or raise the setpoint.

公开(公告)号：US20200332958A1

公开(公告)日：2020-10-22

申请号：US16387340

申请日：2019-04-17

Applicant: KURT EDWARD DIETRICH ,  THOMAS F. AMBROSE ,  ERIC C. GINGRICH ,  TIMOTHY RICHARD BARBOUR

Inventor： KURT EDWARD DIETRICH ,  THOMAS F. AMBROSE ,  ERIC C. GINGRICH ,  TIMOTHY RICHARD BARBOUR

IPC: F17C1/00 ,  F25D3/10

Abstract: A sealed container having gloves attached thereto is provided as part of a physical properties measuring system (PPMS). The PPMS includes a sealed pressurized portion that is pressurized with a gas to purge out air from inside the sealed pressurized portion to reduce water vapor inside the sealed pressurized portion below a water vapor threshold. The system further includes a cryogenic tank having a cryostat disposed therein. The cryogenic tank contains a cryogenic liquid cooled to a cryogenic temperature. Test samples are placed inside the sealed pressurized portion in preparation of measuring physical properties of the test samples. One of the test samples is immersed in the cryogenic liquid to measure the physical properties. The test sample is removed from the cryogenic liquid and is exchanged for another test sample inside the sealed pressurized portion to prevent ice formation inside the cryostat.

公开(公告)号：US10780999B1

公开(公告)日：2020-09-22

申请号：US16405910

申请日：2019-05-07

Applicant: Charl E. Janeke

Inventor： Charl E. Janeke

IPC: B64G1/62 ,  F42B10/38 ,  F42B15/34 ,  F25D3/10

Abstract: A nosecone apparatus for hypersonic aircraft, rocket or missiles using a method for the mitigation of the created the shock front of a rocket or aerospace plane flying at hypersonic speeds by using nosecone splines to create both centripetal and isentropic airflows in conjunction with regeneratively cooling the nosecone structure.

公开(公告)号：US10772320B2

公开(公告)日：2020-09-15

申请号：US16010072

申请日：2018-06-15

Applicant: LICONIC AG

Inventor： Cosmas Malin

IPC: F25D25/00 ,  A01N1/02 ,  F25D13/06 ,  F25D31/00 ,  F25D3/10 ,  G05B19/416

Abstract: The blood bank comprises a cooled storage area with a plurality of stationary storage racks. Further, it comprises a buffer storage, which holds a number of movable storage racks. A robot is provided for moving blood products between the stationary storage racks and the movable storage racks. A product access door is arranged close to the buffer storage for manual access to the blood products within the movable storage racks.

公开(公告)号：US10736772B2

公开(公告)日：2020-08-11

申请号：US15410075

申请日：2017-01-19

Applicant: CRYOTECH NORDIC OU

Inventor： Juha Tapani Yliollitervo ,  Jan Eklund ,  Jean-Patric Martins

IPC: A61F7/00 ,  F25D3/10

Abstract: The invention concerns a fluid circulation and mixing system (100) for a cryocabin arrangement used in a whole-body cryotherapy treatment and a related cryocabin arrangement (120), including a system (100) and a cabin (101) for accommodating a patient. The fluid circulation system (100) includes appliances for effective mixing of cryogenic liquid with ambient air and/or for preventing the cryogenic liquid from settling down on the bottom of evaporator. The cryocabin arrangement (120) further includes appliances for generating and maintaining a fluidic whirl (vortex) within the patient cabin, thus enhancing an overall efficiency of the cryotherapy treatment in general and improving beneficial effects of each individual cryotherapy treatment session.

公开(公告)号：US10724780B2

公开(公告)日：2020-07-28

申请号：US15882518

申请日：2018-01-29

Applicant: Advanced Research Systems, Inc.

Inventor： Shenghong Yao ,  Tim Schilling

IPC: F25D3/10 ,  F25D25/00 ,  F25D19/00

Abstract: The present disclosure relates to a cryocooling system and method. The system includes a sample well and a sample chamber, each of which having an interior that is sized and shaped to hold a cryocooling gas at cryogenic temperatures and a pressure below 1 atm. The sample chamber is also sized and shaped to hold a sample substance to be cryocooled. An impedance tube connects the interior of the sample well to the interior of the sample chamber to allow cryocooling gas to move from the sample well to the sample chamber. A vacuum tube is connected to the interior of the sample chamber on one side and to a vacuum pump via a vacuum port on the other. The vacuum tube is sized and shaped to allow cryocooling gas within the sample chamber to be pumped out of the sample chamber by the vacuum pump.

公开(公告)号：US10704735B2

公开(公告)日：2020-07-07

申请号：US14787913

申请日：2014-04-25

Applicant: CRYOSTAR SAS

Inventor： Philippe Fauvel ,  Philippe Heisch

IPC: F17C5/00 ,  F17C7/00 ,  F17C7/04 ,  F17C9/02 ,  F25D3/10 ,  F17C5/02 ,  F17C13/02 ,  F17C9/00

Abstract: A method for replenishing the supply of cryogenic liquid from a storage tank (2) includes: pressurizing a container (14) with cryogenic gas at a first pressure, said container having passing through it a first cryogenic fluid flow line referred to as the cold line and a second cryogenic fluid flow line referred to as the hot line, passing cryogenic liquid at a second pressure through the cold line (12), and supplying the container (14) with cryogenic gas at least partially from cryogenic liquid pumped from the storage tank (2) and vaporized. A device is also provided for the method hereinabove.

公开(公告)号：US10661990B2

公开(公告)日：2020-05-26

申请号：US16422507

申请日：2019-05-24

Applicant: Brooks Automation, Inc.

Inventor： Robert T. Caveney ,  Frank Hunt ,  Lingchen Sun ,  Julian D. Warhurst ,  Bruce S. Zandi ,  Anthony C. Bonora

IPC: B65G1/04 ,  F25D3/11 ,  B65G1/06 ,  B65G1/10 ,  F25D3/10 ,  F25D21/02 ,  F25D21/04 ,  F25D25/02 ,  F25D29/00 ,  F25D25/04

Abstract: An automated cryogenic storage system includes a freezer and an automation system to provide automated transfer of samples to and from the freezer. The freezer includes a bearing and a drive shaft though the freezer, the drive shaft being coupled to a rack carrier inside the freezer and adapted to be coupled to a motor. The automation module includes a rack puller that is automatically positioned above an access port of the freezer. The rack puller engages with a sample rack within the freezer, and elevates the rack into an insulating sleeve external to the freezer. From the insulating sleeve, samples can be added to and removed from the sample rack before it is returned to the freezer.

公开(公告)号：US10660328B2

公开(公告)日：2020-05-26

申请号：US16112658

申请日：2018-08-25

Applicant: Bao Tran

Inventor： William G. Moon ,  William J. Hancock ,  Steven V. Boyce ,  Steven J. Parkinson

IPC: A01N1/02 ,  F25D3/10 ,  F25D17/06 ,  F25D29/00

Abstract: A freezer includes a plurality of shelves in an insulated payload bay; a plurality of evaporators coupled to the payload bay with a multiplicity of coolant tubes in each evaporator, wherein each tube enters and then exits the payload bay, further comprising one or more cryogenic valves coupled to the coolant tubes; a pump to force coolant flowing through the evaporators with a pressure of at least 90 psi to supply the coolant at each evaporator with at least 80 gallons per hour of coolant; and a plurality of fans to circulate cooled air in the payload bay.

公开(公告)号：US20200088453A1

公开(公告)日：2020-03-19

申请号：US16689524

申请日：2019-11-20

Applicant: Michael D. Newman

Inventor： Michael D. Newman

IPC: F25D3/10 ,  F25D3/11 ,  A23L3/375

Abstract: An apparatus for providing a liquid-gas entrained cryogen mixture onto a food product includes a first pipe through which is provided a flow of liquid cryogen; a second pipe through which is provided a flow of gaseous cryogen, the second pipe in fluid communication with the first pipe at a mixing region; and a pulsing valve disposed at an interior of the second pipe upstream of the mixing region, the pulsing valve adapted for releasing the gaseous cryogen into the liquid cryogen at select intervals of time to provide a pulsating flow of the liquid-gas entrained cryogen mixture downstream of the mixing region for contacting the food product. A related method is also provided.