DE202019001710U1 - Centrifuge with temperature control - Google Patents

Abstract

Centrifuge (10), in particular laboratory centrifuge, with a centrifuge container (30) in which a centrifuge rotor (28) can be accommodated, a centrifuge motor (26) for driving the centrifuge rotor (28), a housing (12) with a base (20) and lateral side walls (16, 17, 18), the centrifuge container (30), the centrifuge rotor (28) and the centrifuge motor (26) being accommodated in the housing (20), and a temperature control device for controlling the temperature of the centrifuge rotor (28), characterized that the temperature control device has air guiding means (38) which are adapted to suck air (160) in a lower region (151, 152) into the centrifuge container (30).

Description

The present invention relates to a centrifuge with temperature control according to the preamble of claim 1.

Centrifuges, in particular laboratory centrifuges, are used to separate the components of the samples centrifuged therein by taking advantage of the inertia. Increasingly higher rotation speeds are used to achieve high segregation rates. Laboratory centrifuges are centrifuges whose centrifuge rotors work at preferably at least 3,000, preferably at least 10,000, in particular at least 15,000 revolutions per minute and are mostly placed on tables. In order to be able to place them on a work table, they have in particular a form factor of less than 1 m x 1 m x 1 m, so their installation space is limited. The device depth is preferably limited to max. Limited to 70 cm.

The samples to be centrifuged are stored in sample containers and these sample containers are driven to rotate by means of a centrifuge rotor. Usually there are fixed-angle rotors and swing-bucket rotors that are used depending on the application. The sample containers can contain the samples directly, or separate sample containers containing the sample are used in the sample container, so that a large number of samples can be centrifuged simultaneously in one sample container.

Mostly it is provided that the samples are centrifuged at certain temperatures. For example, samples containing proteins and the like. Organic substances must not be overheated, so that the upper limit for the temperature control of such samples is usually in the range of 40 ° C. On the other hand, certain samples are cooled by default in the + 4 ° C range (the anomaly of the water starts at 3.98 ° C).

In addition to such predetermined maximum temperatures of, for example, approx. + 40 ° C and standard test temperatures such as 4 ° C, other standard test temperatures are also provided, such as 11 ° C, in order to check at this temperature whether the refrigeration system of the centrifuge is running under room temperature. On the other hand, for reasons of occupational safety, it is necessary to prevent touching elements that have a temperature of greater than or equal to 60 ° C. Comparative values are in the DIN EN 61010-1: 2011-07 , Table 19.

In principle, active and passive systems can be used for temperature control. Active cooling systems have a refrigerant circuit that regulates the temperature of the centrifuge container (centrifuge vessel), which indirectly cools the centrifuge rotor and the sample containers held in it.

Passive systems are based on exhaust air-assisted cooling or ventilation. This air is guided directly past the centrifuge rotor and thus also past the sample containers contained therein, whereby temperature control takes place. The air is fed into the centrifuge container from above, with the suction taking place automatically through the rotation of the centrifuge rotor.

The disadvantage of this passive temperature control is that it is not very effective.

In addition, centrifuge components need to be cooled in order to prevent the heat generated there from being radiated onto the samples. Additional cooling equipment is required for this.

It is therefore the object of the present invention to provide a laboratory centrifuge with a temperature control that works more effectively. In particular, this temperature control should also enable the centrifuge components to be cooled at the same time. The temperature control should preferably also function in the presence of a safety container (safety boiler, armored boiler) around the centrifuge container.

When a “temperature control of the centrifuge rotor” is mentioned in the context of the present invention, then a temperature control of the material received in the centrifuge rotor, ie in particular the sample container and samples received therein, is also meant. In addition, "temperature control" means not only cooling, but also heating.

This object is achieved with the centrifuge according to the invention according to claim 1. Advantageous developments are specified in the dependent claims and the following description, also in connection with the figures.

The inventors have recognized that this object can be achieved particularly easily and efficiently if the air is sucked into the centrifuge container in a lower area of the centrifuge container.

As a result, the air now enters the centrifuge container below the centrifuge rotor. This increases the cooling effect because a natural air flow is now supported by the fact that the air enters the centrifuge container at the bottom in a cool state and, after being heated by the centrifuge rotor, can exit the centrifuge container warm.

The centrifuge according to the invention, in particular laboratory centrifuge, with a centrifuge container in which a centrifuge rotor can be accommodated, a centrifuge motor for driving the centrifuge rotor, a housing with a bottom and side walls, the centrifuge container, the centrifuge rotor and the centrifuge motor being accommodated in the housing, and a temperature control device for controlling the temperature of the centrifuge rotor is therefore characterized in that the temperature control device has air guide means which are adapted to suck air into the centrifuge container in a lower region of the centrifuge container. This suction is preferably carried out by rotating the centrifuge rotor; as an alternative or in addition, separate ventilation means could also be used.

In an advantageous further development, these air guiding means have one or more openings in the bottom area of the centrifuge container. This makes the centrifuge particularly simple.

In an advantageous development, the air guiding means are set up to suck in supply air through the floor and / or at least one side wall of the centrifuge housing, this supply air preferably being passed directly from the centrifuge housing to the centrifuge container without heat-emitting elements of the centrifuge, in particular the centrifuge motor and / or electronic Components of the centrifuge to come into contact. As a result, very short air flow paths are achieved before the air enters the centrifuge container and the cooling performance is improved because the supply air cannot be heated by components that emit heat from the centrifuge. In this context, side walls are not only side walls, but also the front and rear of the housing.

In an advantageous development, the air guiding means are set up to guide exhaust air from the centrifuge container past the centrifuge motor and / or past electronic components of the centrifuge, the exhaust air preferably being guided first past the centrifuge motor and then past the electronic components. As a result, in addition to temperature control of the centrifuge container, the further centrifuge components can also be cooled at the same time, whereby the temperature control performance is further improved.

In an advantageous development, the air guiding means are set up to guide exhaust air from the centrifuge container along the outside of the centrifuge container. This makes the use of the cooling effect of the supply air particularly effective.

In an advantageous development, the centrifuge furthermore has a safety container which at least partially encloses the centrifuge container, the air guiding means preferably being set up to guide exhaust air from the centrifuge container between the centrifuge container and the safety container. As a result, the centrifuge meets the highest safety standards, and yet the temperature control is very efficient and the cooling device is kept very compact.

In an advantageous further development, the safety container has one or more openings for the supply air in its bottom area. The air duct is then particularly short and, moreover, this design does not reduce safety, because the centrifuge motor is usually arranged in the bottom area of the safety container, which is used to absorb energy in the event of a crash (the centrifuge rotor crashes according to DIN EN 61010-2-020: 2017-12 ) cares.

In an advantageous development, the air guiding means are designed to be thermally insulated at least in some areas and / or the centrifuge container is provided with thermal insulation on its outside in the area of the air duct. Then the temperature control is particularly efficient, whereby thermal bridges and thermal short circuits are avoided.

In an advantageous development, the air guiding means are designed as a molded part, in particular a molded foam part, preferably made of polypropylene or polyurethane. The air guiding means can then be produced particularly simply and inexpensively.

In an advantageous development, at least one soundproof foam element, preferably made of polyurethane, is used for soundproofing. Noise development caused by the air duct can then be effectively dampened towards a user.

In an advantageous development, the air guiding means are in several pieces, preferably consisting of a lower part for supplying the supply air to the centrifuge container and for discharging the exhaust air to the centrifuge motor and / or to the electronic components and an upper part for discharging the exhaust air from the centrifuge container into the space between the centrifuge container and containment. Then the centrifuge is particularly easy to assemble.

In an advantageous development, the lower part is formed from two horizontally separated pieces, it is preferably provided that a piece between the bottom of the housing and the Security container is arranged and the other piece is arranged between the security container and the centrifuge container. This improves the mountability in the case of a security container.

In an advantageous further development, the air guide means are adapted to guide the supply air into the centrifuge container in the direction of rotation of the centrifuge rotor and / or to introduce the supply air into the centrifuge container close to the axis of rotation. The guidance in the direction of rotation means that the air is routed particularly efficiently. Due to the supply air close to the axis, a centrifuge rotor effect is created, which increases the air flow.

In an advantageous development, the air guiding means are adapted to collect the exhaust air and guide it past the centrifuge motor and / or the electronic components. This results in particularly effective cooling of the other centrifuge components.

In an advantageous further development, the air guiding means are adapted to extract the air moved in the centrifuge container by the centrifuge rotor at the edge of the centrifuge container. This supports the spinning wheel effect.

In an advantageous development, the air guiding means have a rough surface, at least in some areas. As a result, local turbulences occur, which overall lead to a reduction in the flow resistance.

In an advantageous development, the air guide means have at least one optionally closable air guide. As a result, the start of the centrifuge rotor when the centrifuge is started or the braking of the centrifuge rotor when the centrifuge is stopped can be supported by reducing or completely eliminating the supply air when the centrifuge is started and increasing the supply air when the centrifuge is stopped. The closure can, for example, be provided by a closable and openable flap.

In an advantageous development, the air guide means at least partially surround the centrifuge motor horizontally. Preferably there is a complete horizontal enclosure between the housing base and the safety container or centrifuge container except for at least one exhaust air inlet and at least one exhaust air outlet. Then there is a specially defined air flow and thus a cooling effect on the centrifuge motor.

• 1 die erfindungsgemäße Zentrifuge in einer perspektivischen Ansicht,
• 2 die erfindungsgemäße Zentrifuge nach 1 in einer vertikalen Schnittansicht,
• 3 die erfindungsgemäße Zentrifuge nach 1 in einer ersten horizontalen Schnittansicht x-x,
• 4 die erfindungsgemäße Zentrifuge nach 1 in einer zweiten horizontalen Schnittansicht y-y,
• 5 das eine Stück des unteren Teils der Luftführungsmittel der erfindungsgemäßen Zentrifuge nach 1 in einer perspektivischen Ansicht von oben,
• 6 das eine Stück nach 5 in einer perspektivischen Ansicht von unten,
• 7 das andere Stück des unteren Teils der Luftführungsmittel der erfindungsgemäßen Zentrifuge nach 1 in einer perspektivischen Ansicht von oben,
• 8 das andere Stück nach 7 in einer perspektivischen Ansicht von unten,
• 9 den oberen Teil der Luftführungsmittel der erfindungsgemäßen Zentrifuge nach 1 in einer perspektivischen Ansicht von oben,
• 10 den oberen Teil nach 9 in einer perspektivischen Ansicht von unten,
• 11 eine Ansicht in den Sicherheitsbehälter der erfindungsgemäßen Zentrifuge nach 1 in einer perspektivischen Ansicht von oben in einer Teildarstellung
• 12 eine Ansicht auf den Zentrifugenbehälter der erfindungsgemäßen Zentrifuge nach 1 in einer perspektivischen Ansicht von oben in einer Teildarstellung.

The characteristics and further advantages of the present invention will become clear in the following on the basis of the description of a preferred exemplary embodiment in connection with the figures. It shows purely schematically:

• 1 the centrifuge according to the invention in a perspective view,
• 2 the centrifuge according to the invention 1 in a vertical sectional view,
• 3 the centrifuge according to the invention 1 in a first horizontal sectional view xx,
• 4th the centrifuge according to the invention 1 in a second horizontal sectional view yy,
• 5 one piece of the lower part of the air guiding means of the centrifuge according to the invention 1 in a perspective view from above,
• 6th the one piece after 5 in a perspective view from below,
• 7th the other piece of the lower part of the air guide means of the centrifuge according to the invention 1 in a perspective view from above,
• 8th the other piece after 7th in a perspective view from below,
• 9 the upper part of the air guiding means of the centrifuge according to the invention 1 in a perspective view from above,
• 10 the upper part after 9 in a perspective view from below,
• 11 a view into the safety container of the centrifuge according to the invention 1 in a perspective view from above in a partial representation
• 12 a view of the centrifuge container of the centrifuge according to the invention 1 in a perspective view from above in a partial representation.

In the 1 to 12 are the centrifuge according to the invention 10 , as well as their most important components shown in numerous views.

It can be seen that the centrifuge according to the invention is a laboratory centrifuge 10 acts according to 1 a centrifuge housing 12 with a centrifuge lid 14th , Side walls 16 , a back wall 17th , a front 18th and a floor 20th having. In the front 18th is a control unit 22nd integrated in the usual way. The side walls 16 and also the back wall 17th have ventilation openings (not shown), in the form of slots, through which air enters the centrifuge housing 12 can get in and out of it.

In the 2 to 4th can be seen that the laboratory centrifuge 10 a centrifuge motor 26th having a centrifuge rotor 28 , which is removable, drives with the appropriate control. In the centrifuge rotor 28 sample receptacles for sample vessels (both not shown) are arranged in the usual manner, and samples taken up in the sample vessels can then be centrifuged.

The centrifuge rotor 28 runs in a centrifuge container 30th made of stainless steel by a containment 32 is surrounded, which in the event of a crash an outward penetration of rotor components from the centrifuge housing 12 prevented out. This security container 32 is designed to be reinforced accordingly. The centrifuge container 30th is in 11 shown in more detail and the security container 32 is in 12 shown in more detail.

The laboratory centrifuge 10 has electronic components 34 for operating and controlling the laboratory centrifuge 10 on how especially off 3 becomes clear. A cooling fin element is provided for improved heat radiation 36 provided, the cooling fins (not shown) extend horizontally.

In addition, there are air ducts 38 in the laboratory centrifuge 10 arranged in detail in the 5 to 10 are shown in more detail. This air guide means 38 are formed from an upper part 40 and a lower part 42 , with the lower part 42 turn into one piece 44 and another piece 46 subdivided.

The one piece 44 of the lower part 42 the air ducting means 38 according to the 5 and 6th an approximately bowl-shaped shape that extends upwards with a raised edge 48 opens. In the edge 48 are two laterally opposite recesses 50 intended.

In the middle of one piece 44 there is a central opening 54 that is to include the centrifuge motor 26th is determined.

It also has a piece 44 four first 56 and two second connection pieces 58 on, these connecting pieces each passages 60 , 62 through the one piece 44 exhibit. The passages 62 through the second connection nozzle 58 correspond to the respective recess 50 . Inside and outside in relation to the connecting pieces 56 , 58 there are circumferential projections 64 , 66 in the form of ribs with a first connection area between them 67 limit.

In 3 and 5 can be seen that the passages 60 parallel to the direction of rotation D. of the centrifuge rotor 28 run in a spiral in the direction of the axis of rotation A.

The other piece 46 of the lower part 42 the air ducting means 38 according to the 7th and 8th an approximately hoop-shaped shape with a central recess 68 for the spaced-apart horizontal housing of the centrifuge motor 26th is determined.

The other piece 46 has a partially circumferential edge 70 and internal second connection areas 72 , 74 that lead to the connecting pieces 56 , 58 corresponding four first 76 and two second wells 78 with appropriate passages 80 , 82 exhibit. These second connection areas 72 , 74 are in turn of circumferential projections 84 , 86 surrounded in the form of ribs, with a connecting projection 88 in the form of a rib between the circumferential projections 84 , 86 and a connection protrusion 90 in the form of a rib on the protrusion 86 are arranged.

The central recess 68 corresponds to an exhaust air supply line 92 and an exhaust air duct 94 and has three fillets 96 on, the fastening elements corresponding to the spaced housing 98 of the centrifuge motor 26th in the case back 20th are determined (cf. 3 ).

In the exhaust air supply line 92 there is a curved wedge 100 who made the two passages 82 of the two second wells 78 merges and towards the central recess 68 and the exhaust air discharge 96 directs. The passages 82 that are in the second indentations 78 with respect to the axis of rotation A of the centrifuge rotor 28 are exactly opposite, thus describe under the second connection areas 72 , 74 and the edge 70 each have a 90 ° bend, whereby, as in 3 can be seen from the depressions 78 coming first radially outwards into the edge 70 pass over and then in this edge 70 run around to the wedge 100 and the exhaust air supply 92 .

The two passages 82 are of a common lead 102 surrounded in the form of a rib. The four passages 80 open into two oppositely arranged third connection areas 104 , 106 with corresponding air supply connections 108 , which are also designed as projections. The connection areas 104 , 106 are in turn of circumferential projections 110 , 112 surround. The surrounding protrusions 110 , 112 and 102 are partially designed to overlap. There is also a connection protrusion 114 .

The one piece 44 of the lower part 42 the air ducting means 38 points out loud 5 also connecting projections 116 , 118 in the form of ribs on that the passages 60 , 62 Enclose areas, each with connections 120 , 122 are recessed. In addition, there are connecting protrusions 124 , 126 , 128 provided in the form of ribs.

In the 9 and 10 can be seen that the upper part 40 the air ducting means 38 Is formed like a hoop, the hoop having an inner circumferential collar 130 having. There are also formations 132 , 134 , 136 that of attaching and aligning the top part 40 opposite the containment 32 and the upper part 138 of the housing 12 serve. The axial projection 140 , which is designed as a continuous rib, is used to seal against the safety container 32 .

In 11 can be seen that the containment 32 in its bottom 142 Breakthroughs 144 , 146 for connection to the feedthroughs 80 , 82 of the other piece 46 of the lower part 42 the air ducting means 38 , Holes 148 for securing the safety container 32 on the ground 20th of the housing 12 and a central opening 150 to accommodate the centrifuge motor 26th having.

Through the surrounding projections 84 , 86 as well as the connecting projection 88 and the connection protrusion 90 are the second connection areas 72 , 74 not directly on the containment 32 on, but a tolerance compensation is effected, whereby the accuracy of fit when connecting security containers 32 and the other pieces 46 of the lower part 42 is improved as the protrusions 84 , 86 , 88 , 90 can be pressed very easily.

In 12 you can finally see that the centrifuge container 30th that in the one piece 44 of the lower part 42 is a floor 151 which is in 12 is only partially shown (with an actually non-existent annular recess to clarify the air flow paths) (cf. 2 ). Below the floor 151 there is a cuff 152 around the centrifuge motor 26th (see. 2 and 4th ) that in the one piece 44 is determined with its outer circumference (cf. 2 ), thereby acting as a seal and together with the floor 151 of the centrifuge container 30th an air duct space 153 forms the one with the four connections 120 communicates.

Here, too, there is again a very good fit and, at the same time, sealing of the passages 60 and the connections 120 through the protrusions 116 , 118 , 126 , 128 that are compressible and compensate for tolerances.

The centrifuge container 30th with the one piece 44 of the lower part 42 is after in the assembled state 2 in the security container 32 to 11 used.

The breakthroughs 144 , 146 of the containment 32 close in cross-section with the respective cross-sections of the depressions 76 , 78 off so that the connecting pieces 56 , 58 fit into the recesses 76 , 78 can intervene to thereby the passages 60 , 62 with the passages 80 , 82 sealed to connect. As a result, there can be no supply or exhaust air in the connection area between other pieces 46 , Security container 32 and one piece 44 emerge, but is completely through the air ducts formed 154 , 156 directed.

By doing that the other piece 46 of the lower part 42 Ledges 102 , 110 , 112 , 114 has, the other piece lies 46 again not all over the floor 20th of the housing, whereby a tolerance compensation is guaranteed.

The supply air connections 108 grip accordingly in the assembled state 2 directly into corresponding openings 158 in the ground 20th of the housing 12 one, resulting in a closed air duct 160 , 162 from supply air 160 and exhaust air 162 results.

More precisely is the supply air 160 by the four in the ground 20th located breakthroughs 158 sucked in and into the supply air connections 108 and the passages 80 convicted. From there the supply air is fed into the connecting pieces 56 transferred and through the passages 60 about the connections 120 to through the cuff 152 and the floor 151 of the centrifuge container 30th formed air duct space 153 and from there through the as an annular gap 163 between centrifuge containers 30th and cuff 152 of the centrifuge motor 26th formed inlet opening 163 near the axis in the centrifuge container 30th transported.

By the rotation of the centrifuge rotor 28 in the direction of rotation there is a centrifugal wheel effect, whereby the exhaust air to the outside of the centrifuge container 30th is thrown and thereby accelerated. This causes the supply air to be sucked in 160 automatically, this effect being further supported by the fact that 4th the passages 60 run spirally inwards in the direction of rotation.

The supply air 160 enters the between centrifuge container 30th and upper part 138 of the housing 12 located annular gap 164 (the annular gap 164 is through the top flange 165 of the centrifuge container 30th and the upper part 138 of the housing 12 limited) and is limited by the upper part 40 with the cantilever 130 in the space 166 between centrifuge containers 30th and containment 32 passed around the centrifuge container 30th extends. This exhaust air 162 is over the two cutouts 50 and the connections 122 to the Passages 62 and from there into the ducts 82 . From the passages 82 becomes the exhaust air 162 further into the exhaust ducts 156 passed until they hit the wedge 100 meets and from there past the centrifuge motor 26th in the direction of the cooling fin element 36 and the electronic components 34 is directed.

The flow directions of supply air 160 and exhaust air 162 are indicated by arrows.

It can be seen that the supply air bypassing warm areas of the centrifuge 10 directly from the cold floor area into the centrifuge container 30th is initiated. This is done without any assistance from fans and the like. Because of the rotation of the centrifuge rotor 28 causes a centrifugal wheel effect, whereby the supply air 160 into the centrifuge container 30th is sucked in. This results in a particularly effective cooling of the centrifuge rotor 28 with the samples contained therein and the centrifuge container 30th .

The supply air then flows in 160 over the annular gap 164 over and becomes in contact with the centrifuge container 26th in the space 166 between centrifuge containers 26th and containment 32 out, causing further cooling of the centrifuge container 26th and thus the centrifuge rotor 28 with the samples contained therein.

Eventually the exhaust air 162 after cooling the centrifuge container 30th nor to cool the centrifuge motor 26th as well as the electronic components 34 and their cooling device 36 used, reducing the heat input of these elements 26th , 34 , 36 into the centrifuge container 30th is reduced from the outset, which ultimately also leads to a cooling of the centrifuge container 30th as well as centrifuge rotor 28 with the samples it contains.

From the above illustration it has also become clear that a centrifuge 10 is provided with a temperature control that works more effectively than previously used temperature-controlled centrifuges. At the same time, this temperature control can also be used to cool heat-emitting centrifuge components such as the centrifuge motor 26th and electronic components 34 , 36 respectively. In addition, this temperature control also works if a safety container 32 around the centrifuge container 30th is arranged.

Unless stated otherwise, all features of the present invention can be combined with one another freely and isolated from other features. Unless otherwise stated, the features described in the description of the figures can also be freely and isolated combined with the other features, in particular the claims features, as features of the invention.

List of reference symbols

10

centrifuge according to the invention, laboratory centrifuge

12

Centrifuge housing

14th

Centrifuge lid

16

side walls

17th

Back wall

18th

front

20th

ground

22nd

Control unit

26th

Centrifuge motor

28

Centrifuge rotor

30th

Centrifuge container

32

Security container

34

electronic components of the centrifuge 10

36

Cooling fin element

38

Air ducting means

40

upper part of the air duct 38

42

lower part of the air duct 38

44

a piece of the lower part 42 the air ducting means 38

46

another piece of the lower part 42 the air ducting means 38

48

raised edge of one piece 44

50

two laterally opposite recesses in the edge 48

54

central opening of one piece 44

56

four first connecting pieces

58

two second connection pieces

60

Passing through of the first four connecting pieces 56

62

Passages of the two second connection pieces 58

64, 66

circumferential projections, ribs

67

first connection area

68

central recess of the other piece 46

70

partially circumferential edge 70 of the other piece 46

72, 74

second connection areas

76

four first wells

78

two second wells

80

Passing through the four first wells 76

82

Passage of the two second wells 78

84, 86

circumferential projections, ribs

88

Connecting protrusion, rib

90

Connection protrusion, rib

92

Exhaust air supply

94

Exhaust air discharge

96

three fillets

98

Fastening elements of the centrifuge motor 26th in the case back 20th

100

curved wedge

102

common projection of the two passages 82 , Rib

104, 106

third connection areas arranged opposite one another

108

Air supply connections, protrusions, ribs

110, 112

circumferential projections, ribs

114

Connecting protrusion, rib

116, 118

Connecting protrusions, ribs

120, 122

connections

124, 126, 128

Connecting protrusions, ribs

130

inside circumferential collar of the upper part 40 the air ducting means 38

132, 134, 136

Formations

138

upper part of the housing 12

140

axial projection, rib

142

Bottom of the containment 32

144, 146

Breakthroughs in the ground 142

148

Holes in the ground 142

150

central opening in the bottom 142

151

Bottom of the centrifuge container 30th

152

Centrifuge motor sleeve 26th

153

Duct space

154, 156

Air ducts

158

Breakthroughs in the ground 20th of the housing 12

160

Supply air

162

Exhaust air

163

Annular gap between centrifuge container 30th and cuff 152 of the centrifuge motor 26th , Inlet opening for supply air 160 into the centrifuge container 30th

164

Annular gap between centrifuge container 30th and upper part 138 of the housing 12

165

top flange of the centrifuge container 30th

166

Space between centrifuge containers 30th and containment 32

D.

Direction of rotation of the centrifuge rotor 28

A.

Axis of rotation

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Non-patent literature cited

• DIN EN 61010-1: 2011-07 [0005]

Claims (10)

Centrifuge (10), in particular laboratory centrifuge, with a centrifuge container (30) in which a centrifuge rotor (28) can be accommodated, a centrifuge motor (26) for driving the centrifuge rotor (28), a housing (12) with a base (20) and lateral side walls (16, 17, 18), the centrifuge container (30), the centrifuge rotor (28) and the centrifuge motor (26) being accommodated in the housing (20), and a temperature control device for controlling the temperature of the centrifuge rotor (28), characterized that the temperature control device has air guide means (38) which are adapted to suck air (160) in a lower region (151, 152) into the centrifuge container (30). Centrifuge (10) Claim 1 , characterized in that the air guide means (38) are set up to suck in supply air (160) through the bottom (20) and / or at least one side wall of the centrifuge housing (12), this supply air (160) preferably directly from the centrifuge housing (12) to the Centrifuge container (30) is conducted without coming into contact with heat-emitting elements of the centrifuge, in particular the centrifuge motor (26) and / or electronic components (34, 36) of the centrifuge (10). Centrifuge (10) Claim 1 or 2 , characterized in that the air guiding means (38) are set up a) to guide exhaust air (162) from the centrifuge container (30) past the centrifuge motor (26) and / or past electronic components (34, 36) of the centrifuge (10) , wherein the exhaust air (162) is preferably first guided past the centrifuge motor (26) and then past the electronic components (34, 36), and / or b) exhaust air (162) from the centrifuge container (30) on the outside of the centrifuge container ( 30, 164). Centrifuge (10) according to one of the preceding claims, characterized in that the centrifuge (10) furthermore has a safety container (32) which at least partially encloses the centrifuge container (30), and the air ducting means (38) are preferably set up, exhaust air (162) out of the centrifuge container (30) between (166) the centrifuge container (30) and the safety container (32), the safety container (32) preferably having one or more openings (144) for the supply air (160) in its bottom area (142). Centrifuge (10) according to one of the preceding claims, characterized in that c) the air ducting means (38) are at least partially thermally insulated and / or that the centrifuge container (10) has thermal insulation on its outside in the area of the air duct (38) (44) is provided and / or d) the air guiding means (38) are formed as a molded part, in particular a foam molded part (40, 44, 46), preferably made of polypropylene or polyurethane, in particular expanded polypropylene and / or at least one soundproof foam element (40 . 44, 46), preferably made of polyurethane. Centrifuge (10) according to one of the preceding claims, characterized in that the air guiding means (38) in several pieces, preferably from a lower part (42) for supplying the supply air (160) to the centrifuge container (30) and for discharging the exhaust air (162) to the Centrifuge motor (26) and / or to the electronic components (34, 36) and an upper part (40) for discharging the exhaust air (162) from the centrifuge container (30) into the space (166) between the centrifuge container (30) and the safety container ( 32) are formed. Centrifuge (10) Claim 6 , characterized in that the lower part (42) is formed from two horizontally separated pieces (44, 46), it is preferably provided that in connection with Claim 4 one piece (46) is arranged between the bottom (20) of the housing (12) and the safety container (32) and the other piece (44) is arranged between the safety container (32) and the centrifuge container (30). Centrifuge (20) according to one of the preceding claims, characterized in that e) the air guide means (38) are adapted to guide the supply air (160) in the direction of rotation (D) of the centrifuge rotor (28) into the centrifuge container (30) and / or to introduce the supply air (160) into the centrifuge container (30) close to the axis of rotation (A) and / or f) the air guiding means (38) are adapted to the air moved in the centrifuge container (30) by the centrifuge rotor (28) at the edge (164 ) of the centrifuge container (30). Centrifuge (10) according to one of the preceding claims, characterized in that g) the air guiding means have a rough surface at least in some areas and / or h) the air guiding means have at least one optionally closable air duct. Centrifuge (10) according to one of the preceding claims, characterized in that the air guiding means (38) at least partially surround the centrifuge motor (26) horizontally, preferably horizontally between the housing base (20) and the safety container (32) or centrifuge container (30) up to at least one exhaust air supply (50) and completely enclose at least one exhaust air discharge (62).

Images