TOPTION termékek

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

Its core value lies in providing a visible, controllable, and safe reaction environment or a homogenizing device for experiments or small-batch production through its transparent glass structure.

A device that can cause changes in substances under the irradiation of ultraviolet light/visible light. In short: a photochemical reactor is a core device that uses light energy (ultraviolet or visible light of specific wavelengths) to drive chemical reactions.

A device that can cause changes in substances under the irradiation of ultraviolet light/visible light. In short: a photochemical reactor is a core device that uses light energy (ultraviolet or visible light of specific wavelengths) to drive chemical reactions.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Primarily used in fields with high requirements for product purity, safety, and natural properties: Natural product extraction: plant essential oils (such as Sichuan pepper and chili extracts), spices, pigments, medicinal active ingredients (such as ginkgolide), capsanthin, and fish oil Omega-3. Food industry: caffeine removal, extraction/refining of edible oils, and concentration of flavor substances. High value-added fields: pharmaceuticals (heat-sensitive drug components), cosmetics (natural active ingredients), and emerging fields such as cannabidiol extraction.

Molecular distillation is an advanced liquid-liquid separation technique performed under high vacuum. Its core principle lies in utilizing the difference in molecular free path to separate substances at temperatures far below conventional boiling points. It lowers boiling points under extreme vacuum conditions, achieving liquid-liquid separation and improving the purity of the active ingredient.

Molecular distillation is an advanced liquid-liquid separation technique performed under high vacuum. Its core principle lies in utilizing the difference in molecular free path to separate substances at temperatures far below conventional boiling points. It lowers boiling points under extreme vacuum conditions, achieving liquid-liquid separation and improving the purity of the active ingredient.

Molecular distillation is an advanced liquid-liquid separation technique performed under high vacuum. Its core principle lies in utilizing the difference in molecular free path to separate substances at temperatures far below conventional boiling points. It lowers boiling points under extreme vacuum conditions, achieving liquid-liquid separation and improving the purity of the active ingredient.

Molecular distillation is an advanced liquid-liquid separation technique performed under high vacuum. Its core principle lies in utilizing the difference in molecular free path to separate substances at temperatures far below conventional boiling points. It lowers boiling points under extreme vacuum conditions, achieving liquid-liquid separation and improving the purity of the active ingredient.

Molecular distillation is an advanced liquid-liquid separation technique performed under high vacuum. Its core principle lies in utilizing the difference in molecular free path to separate substances at temperatures far below conventional boiling points. It lowers boiling points under extreme vacuum conditions, achieving liquid-liquid separation and improving the purity of the active ingredient.

Molecular distillation is an advanced liquid-liquid separation technique performed under high vacuum. Its core principle lies in utilizing the difference in molecular free path to separate substances at temperatures far below conventional boiling points. It lowers boiling points under extreme vacuum conditions, achieving liquid-liquid separation and improving the purity of the active ingredient.

Molecular distillation is an advanced liquid-liquid separation technique performed under high vacuum. Its core principle lies in utilizing the difference in molecular free path to separate substances at temperatures far below conventional boiling points. It lowers boiling points under extreme vacuum conditions, achieving liquid-liquid separation and improving the purity of the active ingredient.

A rising film evaporator is a highly efficient separation device for evaporating, concentrating, desolventizing, or degassing materials. It is typically used as a pretreatment unit for "short-path molecular distillation." Whether to use a scraped film or rising film evaporator depends on the customer's specific materials, objectives, and budget.

A rising film evaporator is a highly efficient separation device for evaporating, concentrating, desolventizing, or degassing materials. It is typically used as a pretreatment unit for "short-path molecular distillation." Whether to use a scraped film or rising film evaporator depends on the customer's specific materials, objectives, and budget.

A reactor that provides a mixture for reaction synthesis, concentration synthesis, and distillation reflux.

A reactor that provides a mixture for reaction synthesis, concentration synthesis, and distillation reflux.

A reactor that provides a mixture for reaction synthesis, concentration synthesis, and distillation reflux.

With stirring function, it has reflux function, allowing the solution to slowly turn into crystals and precipitate.

With stirring function, it has reflux function, allowing the solution to slowly turn into crystals and precipitate.

With stirring function, it has reflux function, allowing the solution to slowly turn into crystals and precipitate.

With stirring function, it has reflux function, allowing the solution to slowly turn into crystals and precipitate.

With stirring function, it has reflux function, allowing the solution to slowly turn into crystals and precipitate.

With stirring function, it has reflux function, allowing the solution to slowly turn into crystals and precipitate.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

Typically, customers who use Nutsche Filter primarily utilize its filtration and washing functions, involving multiple filtration and washing processes during operation, thus categorizing it under the filtration stage. The three-in-one filtration, washing, and drying machine is crucial equipment in industries such as chemical and pharmaceutical manufacturing. Its core function is to automatically and continuously complete the three processes of filtration, washing, and drying within a sealed container. It fundamentally changes the traditional process that requires multiple material transfers and separations.

It can quickly and directly convert liquid materials (solutions, suspensions, emulsions, etc.) into uniformly sized dry powders or granules.(Note: When the solid content)>20%(Some things need to be noted)

It can quickly and directly convert liquid materials (solutions, suspensions, emulsions, etc.) into uniformly sized dry powders or granules.(Note: When the solid content)>20%(Some things need to be noted)

It can quickly and directly convert liquid materials (solutions, suspensions, emulsions, etc.) into uniformly sized dry powders or granules.(Note: When the solid content)>20%(Some things need to be noted)

It can quickly and directly convert liquid materials (solutions, suspensions, emulsions, etc.) into uniformly sized dry powders or granules.(Note: When the solid content)>20%(Some things need to be noted)

It can quickly and directly convert liquid materials (solutions, suspensions, emulsions, etc.) into uniformly sized dry powders or granules.(Note: When the solid content)>20%(Some things need to be noted)

It can quickly and directly convert liquid materials (solutions, suspensions, emulsions, etc.) into uniformly sized dry powders or granules.(Note: When the solid content)>20%(Some things need to be noted)

It can quickly and directly convert liquid materials (solutions, suspensions, emulsions, etc.) into uniformly sized dry powders or granules.(Note: When the solid content)>20%(Some things need to be noted)

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

TOPT-XA/B/C/D/E: TOPT's experimental models are bell-type freeze dryers, meaning they have an organic glass cover and are not for in-situ freeze drying. The differences between ABCDE are: A represents the standard type, B represents the capping type, C represents the manifold type, D represents the manifold capping type, and E represents the T-type support.

The TPV-XF/G/FD/GD series freeze dryers are also known as container-type freeze dryers, featuring in-situ pre-freezing functionality. The difference between F, G, and FD is as follows: F represents standard silicone oil heating; G represents capping silicone oil heating; FD represents standard electric heating; and GD represents capping electric heating.

The TPV-XF/G/FD/GD series freeze dryers are also known as container-type freeze dryers, featuring in-situ pre-freezing functionality. The difference between F, G, and FD is as follows: F represents standard silicone oil heating; G represents capping silicone oil heating; FD represents standard electric heating; and GD represents capping electric heating.

The TPV-XF/G/FD/GD series freeze dryers are also known as container-type freeze dryers, featuring in-situ pre-freezing functionality. The difference between F, G, and FD is as follows: F represents standard silicone oil heating; G represents capping silicone oil heating; FD represents standard electric heating; and GD represents capping electric heating.

The TPV-XF/G/FD/GD series freeze dryers are also known as container-type freeze dryers, featuring in-situ pre-freezing functionality. The difference between F, G, and FD is as follows: F represents standard silicone oil heating; G represents capping silicone oil heating; FD represents standard electric heating; and GD represents capping electric heating.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

The difference between the GZL and GZLY-X models: GZL does not have a capping device, while GZLY does.

food/Fruit /vegetable type freeze dryer

food/Fruit /vegetable type freeze dryer

food/Fruit /vegetable type freeze dryer

food/Fruit /vegetable type freeze dryer

food/Fruit /vegetable type freeze dryer

food/Fruit /vegetable type freeze dryer

food/Fruit /vegetable type freeze dryer

A heating and cooling cycler provides precise and stable external temperature control for core equipment (such as a reactor) by performing heating and cooling cycles alternately or simultaneously through a single device.

1. Multiple temperature options available, such as RT~200℃, RT~300℃; -20~200℃; -40~200℃; -60~250℃; -80~250℃; etc. 2. Can be configured as a combined heating and cooling unit. 3. Custom sizes and temperatures can be provided upon request.

It is widely used in fields such as chemical reactions, material synthesis, biopharmaceuticals and laboratory research that require precise temperature control, providing stable external heating and cooling cycles for equipment such as reaction vessels, bioreactors and distillation devices.

It is widely used in fields such as chemical reactions, material synthesis, biopharmaceuticals and laboratory research that require precise temperature control, providing stable external heating and cooling cycles for equipment such as reaction vessels, bioreactors and distillation devices.

It is widely used in fields such as chemical reactions, material synthesis, biopharmaceuticals and laboratory research that require precise temperature control, providing stable external heating and cooling cycles for equipment such as reaction vessels, bioreactors and distillation devices.

It is widely used in fields such as chemical reactions, material synthesis, biopharmaceuticals and laboratory research that require precise temperature control, providing stable external heating and cooling cycles for equipment such as reaction vessels, bioreactors and distillation devices.

It is widely used in fields such as chemical reactions, material synthesis, biopharmaceuticals and laboratory research that require precise temperature control, providing stable external heating and cooling cycles for equipment such as reaction vessels, bioreactors and distillation devices.

It is widely used in fields such as chemical reactions, material synthesis, biopharmaceuticals and laboratory research that require precise temperature control, providing stable external heating and cooling cycles for equipment such as reaction vessels, bioreactors and distillation devices.

It is widely used in fields such as chemical reactions, material synthesis, biopharmaceuticals and laboratory research that require precise temperature control, providing stable external heating and cooling cycles for equipment such as reaction vessels, bioreactors and distillation devices.

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements

1. Operating temperature range 2. Core equipment characteristics: capacity, material, etc. 3. Temperature control requirements: e.g., how long it takes to heat/cool XXL of material from XX℃ to XX℃ 4. Refrigerant requirements and certification requirements